JP7181446B2 - game machine - Google Patents

Description

Regarding gaming machines.

As a recent pachinko game machine, a jackpot lottery with a predetermined probability is triggered when a game ball enters the starting hole on the game board (game area), and if you win the jackpot lottery, you win a big hit (special game ) state, and a large winning opening provided on the game board can be opened to win a large number of prize balls. Among the pachinko gaming machines constructed in this way, there are a probability variable game state for increasing the probability of winning in the big win lottery and a time shortening game state for increasing the efficiency of pattern variation for notifying the lottery result in the big win lottery. There is also a gaming machine that enhances the interest of the game by creating a game progress state that is advantageous to the player by these game states.

JP 2005-312674 A JP 2011-45518 A JP 2008-167875 A

However, since many such gaming machines have existed in the past, there is a problem that the development of a machine capable of realizing even more novel game characteristics is desired.

The pachinko game machine according to this aspect is
a first control board for controlling the progress of a game;
a second control board for controlling the giving of game balls based on information from the first control board;
a power supply board that supplies power;
a plurality of winning holes into which game balls fired toward the game area can enter;
a circulation mechanism that makes it possible to shoot again the game balls that have been shot toward the game area;
Equipped with a front unit having at least a display unit for the number of held balls composed of at least a plurality of 7-segment LEDs , a first display unit, a second display unit, and an operation unit that can be operated by the player,
The first control board has a first storage means capable of storing data used in the first control board,
The second control board has a second storage means capable of storing data used in the second control board,
Power supply to the second control board is configured to be performed directly from the power supply board,
Power is supplied to the first control board from the power supply board via the second control board,
The second control board has a capacitor capable of supplying power to the second storage means,
Even when power is not supplied from the power supply board to the second control board, data in the second storage means can be retained by power supply from the capacitor of the second control board,
Even if power is not supplied to the first control board because the power supply board does not supply power to the second control board, the data in the first storage means is stored by power supply from the capacitor of the second control board. configured to hold,
The first display unit is configured to display first information corresponding to a predetermined error related to the second control board,
The second display unit is configured to display second information different from the first information,
The display area of the first display section is configured to be smaller than the display area of the number-of-balls display section,
The display area of the second display section is configured to be smaller than the display area of the number-of-balls display section,
The first display section, the second display section, and the number-of-balls display section are arranged at predetermined positions on the front unit that are identifiable by the player ,
The first display unit is arranged closer to the player than the number-of-balls display unit,
The second display section is arranged on the right side of the first display section,
The distance between the first display section and the second display section is configured to be longer than the horizontal width of at least one 7-segment LED.
It is a pachinko game machine characterized by
<Appendix>
Other aspects different from this aspect will be listed below, but the present invention can be implemented without being limited to these.
The game machine according to this alternative aspect is
an identification information display portion capable of displaying identification information (for example, a first main game symbol display portion A21g, a second main game symbol display portion B21g, an auxiliary game symbol display portion H21g);
a main control unit (for example, the CPUMC of the main control board M) that controls the progress of the game;
an effect display unit (for example, an effect display device SG) capable of displaying an effect;
A sub control unit (for example, the CPUSC of the sub control board S) that controls the display of the effect,
The main control unit
After the identification information is variably displayed on the identification information display unit, the identification information can be controlled to stop display on the identification information display unit,
The sub control unit
During the period from the start of the variable display of the identification information to the stop display of the identification information, after the performance display unit variably displays the performance symbols, the performance display unit can be controlled to stop display the performance symbols,
A stop display mode of the performance symbols to be stopped and displayed on the performance display unit in response to the initialization of at least a part of the game information stored in the main control unit, and the initialization is performed. It is possible to execute a first control for differentiating the stop display mode of the production pattern to be stopped and displayed on the production display unit in response to the fact that it was not broken,
A stop display mode of the performance symbols to be stopped and displayed on the performance display unit in response to the initialization of at least a part of the game information stored in the main control unit, and the initialization is performed. It is possible to execute a second control that is the same as the stop display mode of the production pattern that is stopped and displayed on the production display unit in response to the failure,
The gaming machine is characterized in that it is possible to switch between execution of the first control and execution of the second control.

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

FIG. 1 is a front view of a pachinko game machine according to this embodiment. FIG. 2 is a front view of the main control display device D53 according to this embodiment. FIG. 3 is a diagram showing the round indicator lamp R10, the display mode of the pending display, and the display mode of the auxiliary game symbols according to the present embodiment. FIG. 4 is a rear view of the pachinko game machine according to this embodiment. FIG. 5 is an overall electrical configuration diagram of the pachinko game machine according to the present embodiment. FIG. 6 is a working diagram of the second big winning hole C20 according to the present embodiment. FIG. 7 is a flowchart of main processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 8 is a flowchart of setting change processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 9 is a flowchart of setting confirmation processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 10 is a main flow chart on the main control board side in the pachinko game machine according to the present embodiment. FIG. 11 is a flow chart of NMI interrupt processing (power failure) on the main control board side in the pachinko machine according to the present embodiment. FIG. 12 is a flowchart of prize ball payout command transmission control processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 13 is a flowchart of the payout control board transmission control process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 14 is an image diagram relating to a 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. 15 is a flow chart of the payout control board reception control process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 16 is a flow chart of ball entry detection processing on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 17 is a flow chart of auxiliary game start entrance ball detection processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 18 is a flowchart of the main game starting entrance ball detection process on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 19 is a flow chart of the first (second) big winning hole entry detection process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 20 is a flowchart of general winning hole entry ball detection processing on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 21 is a flowchart of discharge ball detection processing on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 22 is a flow chart of out-hole entrance ball detection processing on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 23 is a flow chart of the number-of-prizing-balls determination process on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 24 is a flowchart of auxiliary game content determination random number acquisition processing on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 25 is a flowchart of the electric accessary product drive determination process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 26 is a flowchart of main game content determination random number acquisition processing on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 27 is a flowchart of main game symbol display processing on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 28 is a flow chart of the first (second) main game symbol display process on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 29 is a 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. FIG. 30 is a flowchart of a small hit game control process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 31 is a flowchart of upper shielding member drive control processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 32 is a flowchart of the lower shielding member drive control process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 33 is a flowchart of the V winning hole entry ball determination process on the main control board side in the pachinko game machine according to the present embodiment. FIG. 34 is a flowchart of special game control processing on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 35 is a flowchart of the game state determination process after the special game is finished on the main control board side in the pachinko game machine according to the present embodiment. FIG. 36 is a flowchart of special game operation condition determination processing on the main control board side in the pachinko gaming machine according to the present embodiment. FIG. 37 is a flowchart of fraud detection information management processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 38 is a flowchart of error management processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 39 is a flowchart of firing control signal output processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 40 is a flowchart of external signal output processing on the main control board side in the pachinko game machine according to the present embodiment. FIG. 41 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. 42 is a flowchart 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. 43 is a flow chart of error control processing upon detection of payout motor operation abnormality on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 44 is a flow chart of error control processing at the time of payout abnormality detection on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 45 is a flow chart of error control processing when ball path abnormality is detected on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 46 is a flow chart of error control processing at the time of payout motor abnormality detection on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 47 is a flow chart of error control processing when a payout stop abnormality is detected on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 48 is a flow chart of prize ball payout related information transmission/reception processing (to the main control board) on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 49 is a flowchart of prize ball payout control processing (at the start of prize ball payout/motor drive start) on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 50 is a flowchart of prize ball payout control processing (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. 51 is a flow chart of prize ball payout control processing (during motor drive execution) on the payout control board side in the pachinko game machine according to the present embodiment. FIG. 52 is a flowchart of motor error processing on the payout control board side in the pachinko gaming machine according to the present embodiment. FIG. 53 is a main flow chart on the side of the sub-main control section in the pachinko game machine according to this embodiment. FIG. 54 is a flowchart of pending information management processing on the sub-main control unit side in the pachinko gaming machine according to the present embodiment. FIG. 55 is a flow chart of decoration symbol display content determination processing on the sub-main control unit side in the pachinko gaming machine according to the present embodiment. FIG. 56 is a flowchart of decorative symbol display control processing on the sub-main control section side in the pachinko gaming machine according to the present embodiment. FIG. 57 is a flow chart of V winning detection effect display control processing on the sub-main control unit side in the pachinko game machine according to the present embodiment. FIG. 58 is a flowchart of special game-related display control processing on the sub-main control section side in the pachinko gaming machine according to the present embodiment. FIG. 59 is a flow chart of small-hit game-related display control processing on the sub-main control section side in the pachinko gaming machine according to the present embodiment. FIG. 60 is a working diagram relating to winning to the V winning opening in the pachinko game machine according to the present embodiment. FIG. 61 is an example of a memory map in this embodiment. FIG. 62 is an image diagram relating to the setting change method in the pachinko gaming machine according to the present embodiment. FIG. 63 is an image diagram relating to the setting change method in the pachinko gaming machine according to the present embodiment. FIG. 64 is an image diagram relating to the setting confirmation method in the pachinko gaming machine according to the present embodiment. FIG. 65 is a diagram showing an example of a display mode on the effect display device during setting change and setting confirmation in the pachinko game machine according to the present embodiment. FIG. 66 is a front view of a pachinko game machine according to a modification of the present embodiment. FIG. 67 is a diagram showing an operation unit device in a pachinko game machine according to a modification of the present embodiment. FIG. 68 is a functional block diagram applicable to the pachinko game machine according to this example. FIG. 69 is a functional block diagram applicable to the pachinko game machine according to this example. FIG. 70 is a flow chart of the first (second) main game symbol display process on the main control board side in the pachinko gaming machine according to the second embodiment. FIG. 71 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 game machine according to the second embodiment. FIG. 72 is a flow chart of limited frequency variation mode determination processing on the main control board side in the pachinko gaming machine according to the second embodiment. FIG. 73 is a configuration diagram of a limited frequency table used in the first (second) main game symbol display process on the main control board side in the pachinko gaming machine according to the second embodiment. FIG. 74 is a flowchart of special game control processing on the main control board side in the pachinko game machine according to the second embodiment. FIG. 75 is a flow chart of distribution game execution processing on the main control board side in the pachinko game machine according to the second embodiment. FIG. 76 is a flowchart of the game state determination process after the special game is finished on the main control board side in the pachinko game machine according to the second embodiment. FIG. 77 is an effect content determination table on the side of the sub-main control section in the pachinko game machine according to the second embodiment. FIG. 78 is a flowchart of timer interrupt processing on the main control board side in the pachinko game machine according to Modification 1 from the second embodiment. FIG. 79 is a flowchart of main game symbol display processing on the main control board side in the pachinko game machine according to Modification 1 from the second embodiment. FIG. 80 is a flowchart of limited frequency variation mode determination processing on the main control board side in the pachinko game machine according to Modification 1 from the second embodiment. FIG. 81 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 game machine according to Modification 1 from the second embodiment. FIG. 82 is a flowchart of special game control processing on the main control board side in the pachinko game machine according to Modification 1 from the second embodiment. FIG. 83 is a flowchart of end demonstration time control processing on the main control board side in the pachinko game machine according to Modification 1 from the second embodiment. FIG. 84 is a flowchart of special game-related display control processing on the main control board side in the pachinko game machine according to Modification 1 from the second embodiment. FIG. 85 is a flowchart of special game control processing on the main control board side in the pachinko game machine according to Modification 2 from the second embodiment. FIG. 86 is a flowchart of distribution game execution processing on the main control board side in the pachinko game machine according to Modification 2 from the second embodiment. FIG. 87 is a diagram exemplifying the opening pattern of the big winning opening on the main control board side in the pachinko game machine according to Modification 2 from the second embodiment. FIG. 88 is a flowchart of start demonstration time control processing on the side of the sub-main control section in the pachinko game machine according to Modification 2 from the second embodiment. FIG. 89 is a flowchart of special game-related display control processing on the side of the sub-main control section in the pachinko game machine according to Modification 2 from the second embodiment. FIG. 90 is a flowchart of start demonstration effect execution processing on the side of the sub-main control section in the pachinko game machine according to Modification 2 from the second embodiment. FIG. 91 is a flow chart of the first (second) main game symbol display process on the main control board side in the pachinko game machine according to Modification 3 from the second embodiment. FIG. 92 shows a first main game win/fail lottery table (second main game It is a configuration diagram of a winning lottery table). FIG. 93 is a flowchart of main game content determination random number acquisition processing on the main control board side in the pachinko game machine according to Modification 5 from the second embodiment. FIG. 94 is a flow chart of pre-reading determination processing on the main control board side in the pachinko game machine according to Modification 5 from the second embodiment. FIG. 95 is a flow chart of prefetch effect execution determination processing on the side of the sub-main control section in the pachinko game machine according to Modification 5 from the second embodiment. FIG. 96 is a first main game win-fail lottery table (second main game win-fail lottery table) of the main control board in a pachinko game machine according to Modification Example 6 from the second embodiment. FIG. 97 is a diagram showing an example of a configuration for obtaining a winning lottery table for each set value without the main control board grasping the set value in the pachinko game according to Modification 7 from the second embodiment. . FIG. 98 is a flowchart of main processing on the main control board side in the pachinko game machine according to the third embodiment. FIG. 99 is a flowchart of main processing on the main control board side in the pachinko game machine according to Modification 1 from the third embodiment. FIG. 100 is a flowchart of main processing on the main control board side in the pachinko game machine according to Modification 2 from the third embodiment. FIG. 101 is a flowchart of main processing on the main control board side in the pachinko game machine according to Modification 3 from the third embodiment. FIG. 102 is an image diagram of a display mode after restoration from power failure in the pachinko game machine according to 1 of the tenth embodiment.

form for implementation

First, the meaning of each term used in this specification will be explained. "Entering ball" includes not only prize winning in which a prize ball is paid out, but also passing through a "through chucker" in which prize balls are not paid out. "Identification information" may be in any form as long as the type of information can be identified through the five senses (visual, auditory, tactile, etc.), but is preferably visual, such as numbers, letters, and patterns. and the like. In addition, in this specification, "identification information" may be referred to as main game design/special design (special design) or decoration design (design), but "special design (special design)" is the main control board The "decorative design (design)" is identification information as an effect displayed on the sub-control board side. The term “identification information can be displayed” is not limited to any display method, and includes, for example, light emission from light emitting means (for example, liquid crystal, LED, 7-segment) (including not only the presence or absence of light emission but also the difference in color), physical typical display (for example, a pattern drawn on the reel band is stopped and displayed at a predetermined position). “Production” refers to display content that enhances the interest of the game, such as identification information change / stop, notice, etc., moving images such as animation and live action, still images such as pictures, photographs, characters, etc. Combinations can be mentioned. "Open state, open state" and "closed state, closed state" are, for example, in the configuration of a general large winning opening (so-called attacker), open state = easy winning state, closed state = non-winning state. Easy state. Also, for example, a state of protruding from the game board (player side) (hereinafter sometimes referred to as an advanced state) and a state of being retracted into the game board (on the side opposite to the player side) (hereinafter referred to as a retracted state) ) (so-called tongue-type attacker), advance state=easy-win state, retreat state=non-easy-win state. “Random numbers” are random numbers used in lotteries (computer-based lotteries) to determine game content in pachinko machines, and include pseudo-random numbers in addition to strictly-defined random numbers (for example, random numbers are hard soft random numbers as random numbers, pseudo-random numbers). For example, the so-called "basic random number" that affects the result of the game, specifically, the "random number (random number for lottery)" related to the transition to the special game, and the variation mode (or variation time) of the identification pattern are determined. ``variation mode determination random number'' for determining the stop pattern, ``symbol determination random number'' for determining the stop pattern, and ``hit pattern determination random number'' for determining whether to shift to a specific game (for example, probability variation game) after a special game. be able to. It is not necessary to use all these random numbers when determining the content of the variation mode, the content of the definite identification information, etc., but 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 expressed in the form of the number of random numbers or a plurality of random numbers. The random number obtained by entering the ball is called one (that is, in the above example, a bunch of random numbers such as winning random number + variation mode determination random number + symbol determination random number ... is called one random number) . Also, for example, one type of random number (for example, winning random number) may serve as another type of random number (for example, symbol determination random number). "Game state" means, in the case of a pachinko game machine, for example, a special game state in which the large winning opening can be open, and a non-probability variable game state in which the lottery probability of transition to the special game state is a predetermined value. Transition to special game state Probability fluctuation game state with high lottery probability, transition to special game Auxiliary game state with assistance for winning a prize to the starting port that triggers the lottery (so-called normal pattern time saving state, for example, variable to the starting port In the case where the member is attached, any one or a combination of the following: long open period of the variable member, high probability of winning the open variable member, short time to announce the result of the open lottery of the variable member), etc. be. The "game area" is an area in which a game ball can roll, and is not limited to the area in front of the game board D35 (as viewed from the player), but may be, for example, the area behind the game board D35 (as seen from the player). and the front side of the game board D35 (as seen from the player), in which the game ball can roll. “Left-handed hitting” means to hit a game ball by adjusting the shooting intensity of the game ball so that the game ball flows down the left side (left-handed hitting route) of the game area D30, which will be described later. "Right-handed" means to hit a game ball by adjusting the shooting intensity of the game ball so that the game ball flows down the right side (right-handed route) of the game area D30, which will be described later. Also, the "left-handed area" is the area on the left side of the game area D30 when the center of the game area is used as a reference. "Right-handed area" is an area on the right side of the game area D30 when the center of the game area is used as a reference. "Expected average execution time of easy-to-enter game per unit time" is assumed to be a situation where auxiliary game patterns are constantly changing (for example, a situation where there is always a hold related to auxiliary game patterns) In the case, it means the ratio of the open period per unit time (for example, 5 minutes) of the variable member attached to the start port. , If the variable member is attached to the starting port, the length of the opening period of the variable member (so-called open extension function operating state / non-operating state), the normal pattern (auxiliary game pattern) that triggers the opening of the variable member Probability high and low (so-called normal pattern high probability lottery state / low probability lottery state), length of fluctuation time of normal pattern (auxiliary game pattern) that triggers the opening of variable members (so-called normal pattern fluctuation reduction function non-operating state / operating state ), etc., is realized by any one or a plurality of combinations. The "average value of the variable display period of the identification information" is not limited to the fact that the variable display period is actually measured for each variable display of the identification information and the average value based on the measured value is taken. More specifically, when the variable display period is determined for each variable display of the identification information, and there are multiple types of candidates for the variable display period to be determined (selected). , the expected value based on the multiple types of variable display periods (the sum of "selection probability x variable display period"), but if there is only one type of candidate for the variable display period to be selected, that one type (that is, it includes both concepts). Furthermore, a concept limited to only the average value of the variable display period of the identification information at the time of losing, a concept limited to only the average value of the variable display period of the identification information at the time of winning, or only the variable display period with the highest selection probability In other words, it should be added that the purpose of this phrase is to use it as an index that indicates the progress speed of the game that the player can experience (therefore, "the variable display period of the identification information As a method of making the "average value" different, the candidates and/or selection probabilities of the variable display period are made different, or even if the candidates and/or selection probabilities of the variable display period are the same, an additional variable display period is added. There are various methods such as differentiating the period value when performing the calculation, but the method is not limited to any of them). "a first variable period state in which the average value of the variable display period of identification information is the first period, and a second period in which the average value of the variable display period of identification information is a second period different from the first period "has at least a variable period state," may have not only the two states, but also three or more states (or any two states in the case of having three or more states For example, depending on the number of times the identification information is displayed, the state transition from "first fluctuation period state" → "second fluctuation period state" → "third fluctuation period state" Including what you can get. In this case, if the average value of the variable display period of the identification information in each state is configured to be "first variable period state" < "second variable period state" < "third variable period state", A state transition of high-speed game progress→medium-speed game progress→slow game progress can be constructed {of course, the opposite state transition (game progress) may be constructed, In that case, it is suitable when used together with the probability fluctuation game state that continues until the next big hit + the electric chew specific game state (despite the situation where the next big hit is certain, the next big hit As the situation continues, the progress speed of the game improves, so that it may be possible to dispel the feeling of fatigue during the so-called addiction)}. Furthermore, as a feature of each state, in the "first variable period state", the difference between the average value of the variable display period of identification information at the time of losing and the average value of the variable display period of identification information at the time of winning is " In the "third fluctuation period state", which is smaller than the difference in the "second fluctuation period state", the average value of the identification information fluctuation display period at the time of losing and the average value of the identification information fluctuation display period at the time of winning In addition to the fact that the difference is smaller than the difference in the "second fluctuation period state", compared to the "first fluctuation period state", the fluctuation display period of the identification information, especially at the time of losing, tends to be relatively long ( In other words, fluctuations or reach fluctuations that suggest hits and reach are likely to occur), in the "second fluctuation period state", the period of fluctuation display of identification information, especially at the time of winning, is relatively long compared to other states. {That is, the fluctuation display period of the short fluctuation loss that makes the loss deterministic and the fluctuation display period of the medium fluctuation loss that suggests a hit are not selected (or are difficult to select), but the reach fluctuation (per long fluctuation) fluctuation display only the period is selected (or is likely to be selected)}. "Specific period in the high probability lottery state after the execution of the special game" may be a period from immediately after the execution of the special game to a predetermined number of symbol changes, or the special game. It may be a period from after one or more symbol variations are made after the execution of the above to the symbol variations for a predetermined number of times (that is, after the execution of the special game, the high probability lottery state is maintained If it is within the range, it means that it is an arbitrary period within that range. If the state transition can be taken, the specific period can mean the stay period of "first fluctuation period state" and / or "second fluctuation period state"). "When a predetermined condition is satisfied in the information on hold" means, for example, that there is a high possibility that a special game (so-called jackpot game) will occur when the hold is digested, but the possibility that a special game will occur The judgment criteria are not particularly limited. More specifically, "winning random number (random number for success or failure lottery)", "variation mode determination random number" for determining the variation mode (or variation time) of the identification pattern, "symbol determination random number" for determining the stop design, A random number value such as "hit pattern determination random number" that determines whether or not to shift to a specific game (for example, probability variation game) after a special game may be used as a judgment criterion, and event contents derived from these random numbers (whether judgment result , the length of fluctuation time, the type of stop pattern, whether or not to shift to a specific game, etc.) may be used as the judgment criteria. ``Suggesting or notifying the existence of a hold'' means, when suggesting, for example, the production at the time of digestion of the hold until the hold (the pattern variation of the decorative pattern, and the background effect, etc.) can be changed. (In that case, change the display color, change the display shape, etc.), change the sound such as on-hold sound and BGM when the on-hold occurs, light emission for production when the on-hold occurs Change the lighting mode of the body (frame luminous body, etc.), or change other effects that are being executed at the time of the suspension occurrence (decorative pattern pattern variation mode, background effect that is performed in conjunction with it, etc.) changing the execution mode, and the like.

Note that this embodiment is only an example, and regarding the location and function of each means, the order of each step regarding various processes, the timing of turning on and off the flag, the name of the means responsible for the processing of each step, etc. It is not limited to the following aspects. Moreover, the above-described embodiments and modifications should not be construed as being limited to being applied to a specific one, and may be combined in any way. For example, a modification of one embodiment should be understood as a modification of another embodiment, and even if one modification is described independently of another, the It should be understood that combinations of modifications and other such modifications are also described.

The following embodiment is a model (first class first class compound machine) in which two conventional first class pachinko game machines are mixed. However, it is not limited to this in any way, and it is within the scope even if it is applied to other game machines (for example, conventional type 1, type 2, type 3, pachinko game machines such as general electric players) . Note that this embodiment is only an example, and regarding the location and function of each means, the order of each step regarding various processes, the timing of turning on and off the flag, the name of the means responsible for the processing of each step, etc. It is not limited to the following aspects. Moreover, the above-described embodiments and modifications should not be construed as being limited to being applied to a specific one, and may be combined in any way. For example, a modification of one embodiment should be understood as a modification of another embodiment, and even if one modification is described independently of another, the It should be understood that combinations of modifications and other such modifications are also described. Further, in this embodiment, there are a lottery table and a reference table for various tables, but these are also not limiting, and the lottery table may be a reference table or vice versa. In this example, the term "table" is not limited to its format, and one or more selection candidates are selected from among multiple selection candidates based on one or more pieces of information. It should be understood that it is a corresponding aspect. Furthermore, numerical values as specific examples shown in the following embodiments and modified examples {for example, winning probability at the time of lottery execution, maximum number of rounds at the time of special game, symbol fluctuation time, number of continuations in each game state, etc.} This is just an example, and in particular, different conditions (for example, conditions between the first main game side and the second main game side, conditions between probability fluctuation games and non-probability fluctuation games, time reduction games and non- It is understood that the magnitude relationships and combinations of numerical values shown in the section "By conditions with time-shortened games, etc." Should. For example, between the 1st main game side and the 2nd main game side, the probability of winning at the time of lottery execution and the expected value of the maximum number of rounds at the time of the special game have a magnitude relationship between the 1st main game side = 2nd main game side. Even if it is exemplified as such, the magnitude relationship can be changed as appropriate such as 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 numerical values and conditions). Also, for example, when the number of continuations of the probability variable gaming state is configured based on the purpose of continuing until the next big hit occurs, is the number of continuations set to "65535" (configured to continue substantially)? Alternatively, even in the option of the implementation method based on the same purpose, such as maintaining the probability variable game state until the next big win occurs without setting the number of continuations, as long as it does not greatly deviate from the purpose of the following embodiments and modifications. should be understood to be subject to change as appropriate.

(this embodiment)
First, FIG. 1 is a drawing showing the basic structure of the front side of the game machine in this embodiment. The pachinko game machine is mainly composed of a game machine frame and a game board D35. These will be described in order below.

First, the game machine frame of the pachinko game machine includes an outer frame D12, a front frame D14, a transparent plate D16, a door D18, an upper ball tray D20, a lower ball tray D22 and a firing handle D44. First, the outer frame D12 is a frame for fixing the pachinko game machine to a position to be installed. The front frame D14 is a frame that matches the opening of the outer frame D12, and is attached to the outer frame D12 via a hinge mechanism (not shown) so that it can be opened and closed. The front frame D14 includes a mechanism for shooting game balls, a mechanism for detachably housing the game board D35, a mechanism for guiding or collecting game balls, a sub-input button SB, and the like. The transparent plate D16 is made of glass or the like and supported by a door D18 (sometimes referred to as a glass door D18). The door D18 is attached to the front frame D14 via a hinge mechanism (not shown) so that it can be opened and closed. The upper ball tray D20 has a mechanism for storing game balls, delivering game balls to the launch rail, extracting game balls to the lower ball tray D22, and the like. The lower ball tray D22 has a mechanism for storing and extracting game balls. Speakers D24 are provided on the upper right and upper left sides of the game board D35 to output sound effects according to the game state and the like.

The game board D35 and the transparent plate D16 (for example, a glass plate) on the front of the game machine are attached to the game machine frame so as to be parallel to each other while maintaining a distance of more than 13 mm and not more than 25 mm (19 mm in this example). It is Here, the game board D35 is firmly fixed by a fixing mechanism so as not to be easily shaken.

In addition, the transparent plate D16 (for example, a glass plate) is designed so that the entire game area is colorless and transparent and has no unevenness so that the position of the game ball on the game board can be confirmed without obstructing the view of the entire structure of the game board. formed.

The ball tray (for example, the upper ball tray D20, the lower ball tray D22) is such that the game balls on the ball tray are visible to the player (the number of game balls can be generally confirmed), and the player receives the game ball on the tray. It has a shape that does not hinder the taking out of the ball (a shape that allows the game ball to be taken out freely).

Next, the sub-input button SB is an operation member electrically connected to the sub-control board S, which is operated (depressed) to execute an effect based on the operation. The modes of operation of the sub-input button SB include a single press (an operation mode in which the sub-input button SB is pressed only once for a short period of time), a continuous press (an operation mode in which the sub-input button SB is pressed multiple times), and a long press. (an operation mode in which the sub-input button SB is kept pressed for a predetermined period of time). Further, the operation member that is electrically connected to the sub control board S and that is operated (depressed) to execute an effect based on the operation is not limited to the sub input button SB. , left, and right. By operating the operation part, the cross key is configured to be able to select the effect to be executed (notice effect, etc.). , etc.) may be configured to have a lever, etc., on which a physical object is actuated, etc.).

Next, the game board D35 has a game area D30 defined by an outer rail D32 and an inner rail D34. position can be confirmed. The game area D30 is roughly divided into a left-handed area and a right-handed area. In addition, in the game area D30, there are a plurality of mechanisms such as game nails and windmills (not shown), various general winning openings (left general winning opening, right general winning opening), left-handed route, right-handed route, and the first main A game start opening A10, a second main game start opening B10, an auxiliary game start opening H10, a first big winning opening C10, and a second big winning opening C20 are installed, and a main control display device D53 ( Round indicator lamp R10, first main game symbol display device A20, second main game symbol display device B20, auxiliary game symbol display device H20, etc.), production display device SG, center decoration D38, and out port D36 are installed. In this embodiment, the left-handed route may be referred to as the first downstream route, and the right-handed route may be referred to as the second downstream route. Each element will be described in detail below.

Next, the first main game starting port A10 is installed as a starting prize winning port corresponding to the first main game. As a specific configuration, the first main game start opening A10 includes a first main game start opening ball detection device A11s. Here, the first main game start opening detection device A11s is a sensor that detects the entry of a game ball to the first main game start opening A10, and the first main game start that indicates the entry at the time of entry. Generate entry ball information.

Next, the second main game starting port B10 is installed as a starting prize winning port corresponding to the second main game. Specifically, the second main game start opening B10 includes a second main game start opening ball detection device B11s and a second main game start electric accessory B11d. Here, the second main game start opening ball detection device B11s is a sensor that detects the entry of a game ball to the second main game start opening B10, and the second main game start indicating the entry at the time of entry. Generate entry ball information. Next, the second main game starter electric accessory B11d changes between a closed state in which game balls are less likely to enter the second main game starter B10 and an open state in which game balls are easier to enter than in the closed state.

Here, in the present embodiment, a first main game start port A10 and a second main game start port B10 are provided, and a game ball flowing down the left side (left-handed region) of the game region D30 is the first While easily guided to the main game start port A10, game balls flowing down the right side (right-handed region) of the game area D30 are configured to be less likely to be guided to the first main game start port A10. In addition, both the game balls flowing down the left side of the game area D30 and the game balls flowing down the right side of the game area D30 are configured to be guided to the second main game start port B10.

In this embodiment, the electric accessory is provided on the side of the second main game start port B10, but it is not limited to this, and the electric accessory is provided on the side of the first main game start port A10. may Furthermore, in this embodiment, the first main game starter A10 and the second main game starter B10 are arranged so as to overlap, but this is not a limitation, and the first main game starter A10 and the second main game starter A10 are arranged to overlap. It may be arranged apart from the 2 main game start gate B10.

In addition, while the game ball flowing down the left side of the game area D30 (based on the center of the game area) is easily guided to the first main game start port A10, it is difficult to be guided to the second main game start port B10. Even if each starting port is arranged so that a game ball flowing down on the right side (based on the center of the game area) is difficult to be guided to the first main game starting port A10, but easily guided to the second main game starting port B10. good. It should be noted that "easily guided" and "difficult to be guided" are determined, for example, by the number of incoming balls when 10,000 game balls are shot to the right and left respectively.

Next, the auxiliary game starting port H10 is provided with an auxiliary game starting port entering ball detection device H11s. Here, the auxiliary game start entrance ball detection device H11s is a sensor that detects the entrance of the game ball to the auxiliary game start hole H10, and generates auxiliary game start entrance ball information indicating the entrance ball at the time of entrance. do. The entry of the game ball into the auxiliary game starter H10 triggers a lottery for expanding the second main game starter electric accessory B11d of the second main game starter B10.

Here, in the present embodiment, the auxiliary game start opening H10 is such that the game ball flowing down the right side of the game area D30 (based on the center of the game area) is easily guided, and the game ball flowing down the left side of the game area D30 is easily guided. It is configured so as not to be easily guided {However, it is not limited to this, and the game ball flowing down the left side of the game area D30 (based on the center of the game area) is configured to be easily guided to the auxiliary game start opening H10. (For example, auxiliary game starting ports H10 may be provided on the left and right sides of the game area D30, respectively)}.

Next, on the upper right side of the out port D36, the first big prize winning port C10 and the second big winning prize port C20 are arranged, 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 out hole D36, it is configured to easily pass through the area where the first big winning hole C10 and the second big winning hole C20 are arranged.

Next, the first big winning hole C10 is a horizontally rectangular out hole that opens when the first main game pattern (special pattern) or the second main game pattern (special pattern) stops as a jackpot pattern. This is a prize winning opening corresponding to the main game located on the upper right side of D36. As a specific configuration, the first large winning opening C10 includes a first large winning opening winning detection device C11s for detecting the entry of a game ball, a first large winning opening electric accessory C11d {and a first big winning Mouth electric accessory solenoid C13}. Here, the first big winning hole winning detection device C11s is a sensor that detects the entry of a game ball into the first big winning hole C10, and the first big winning hole entering ball information indicating the ball entering the first big winning hole C10. to generate The first big winning opening electric accessory C11d changes the first big winning opening C10 between a normal state in which the game ball cannot or is difficult to win in the first big winning opening C10 and an open state in which the game ball easily wins (the first 1 big prize opening electric accessory solenoid C13 is excited and varied). In the present embodiment, the mode of the big winning opening is changed between a normal state in which a game ball cannot or is difficult to win a horizontal rectangular shape and an open state in which a game ball can easily win a prize. is not limited to In that case, for example, a state in which the rod-shaped member provided in the big prize opening protrudes toward the player side and a retracted state in which the bar member is retracted toward the player side (so-called Tongue type attacker-), and an opening on the passage where the game ball can roll is used as a large winning opening, and the opening can be closed and opened (so-called slide attacker). This is suitable when it is desired to ensure that the number of balls entering the big winning hole is a predetermined number (eg, 10).

Next, the second big winning hole C20 is a horizontal rectangular shape that is opened when the first main game pattern (special pattern) or the second main game pattern (special pattern) stops with a big win pattern, and is out. This is a winning opening corresponding to the main game, which is located above the opening D36 and above the first big winning opening C10. As a specific configuration, the second large winning opening C20 includes a second large winning opening winning detection device C21s for detecting the entry of a game ball, a second large winning opening electric accessory C21d (and a second large winning opening an upper solenoid C26), an upper shielding member C24 that starts to drive when a small winning game starts and can block the flow of the game ball to the lower shielding member C25, and a drive that starts when the game machine is powered on to release the game ball. A lower shielding member C25 that can hinder the flow down to the V winning opening C22, a V winning opening C22 that is a winning opening that triggers a shift to a special game by entering a ball during a small winning game, and a V winning opening C22 A V winning opening ball detection device C22s for detecting the entry of a game ball, a second big winning opening discharge opening C23 for discharging a gaming ball that has entered the second big winning opening C20, and a second big winning opening A second big winning opening discharge detection device C23s for detecting the entry of a game ball into the winning opening discharge opening C23 is provided. Here, the second large winning opening detection device C21s is a sensor that detects the entry of a game ball into the second large winning opening C20, and the second large winning opening entry ball information indicating the entry of the ball at the time of entry. to generate A game ball entered into the second large winning opening C20 is configured to be detected by the second large winning opening winning detection device C21s. Next, the second big winning hole electric accessory C21d changes the second big winning hole C20 into a normal state in which the game ball cannot or is difficult to win in the second big winning hole C20 and an open state in which the game ball easily wins. variable. The form of the big winning opening is changed between a normal state in which a game ball cannot or is difficult to win a horizontal rectangular shape and an open state in which a game ball can easily win a prize, but it is not limited to this. In that case, for example, a state in which the rod-shaped member provided in the big prize opening protrudes toward the player side and a retracted state in which the bar member is retracted toward the player side (so-called It may be a tongue type attacker), which is suitable when it is desired to ensure that the number of balls entering the big winning hole is a predetermined number (for example, 10). The internal structure of the second big winning hole C20 will be described later.

In addition, when executing left-handed hitting in the non-time-reduced gaming state (the game proceeds with left-handed hitting in the non-time-reduced gaming state), the game ball enters the auxiliary game start opening H10 (and the right general winning opening). Since it is difficult to open the second main game starter electric accessory B11d, the game progresses mainly by entering the first main game starter A10 as the starter on the main game side. When executing right hitting in the shortened game state (the game progresses with right hitting in the time shortened game state), the second main because the game ball easily enters the auxiliary game start opening H10 (and the right general winning opening) The game starter electric accessory B11d is easy to open, and the game proceeds mainly by entering the second main game starter B10 as the starter on the main game side. In addition, the ease of entering the first main game start opening A10 in the case of continuing to shoot left-handed game balls in a non-time-reduced gaming state is more pronounced than the ease with which a game ball can be shot right-handed in a time-reduced gaming state. The easiness of entering the ball into the second main game start port B10 is higher in the case of continuing to do so, in other words, the first main game start when the game ball continues to be shot left-handed in the non-shortening game state. 1st main game start A10 or 2nd main game start when game balls continue to be shot by hitting to the right in the time shortening game state rather than the ease of entering the ball into the hole A10 or 2nd main game start B10 The ease of entering the ball into the mouth B10 is higher.

In this specification, the non-probability variable game state is normal state, normal game state, normal time, low probability, low probability state, low probability game state, low probability time, non-probability variation, low probability lottery state, etc. sometimes referred to as Also, the probability variable gaming state may be referred to as high probability, high probability state, high probability gaming state, high probability, variable probability, high probability lottery state, and the like. Also, the time reduction game state may be referred to as a time saving state, a time saving medium, a time saving, or the like. In addition, the non-time-reduction gaming state may be referred to as non-time-saving state, non-time-saving, non-time-saving, and the like. Also, the non-probability variable gaming state and non-time reduction gaming state may be referred to as normal state, normal game state, normal time, and the like.

Here, the main control display device D53 will be described in detail with reference to FIGS. 2 and 3. FIG. The main control display device D53 is a display device controlled by the CPUMC of the main control board M, and is a display device in which a plurality of information display devices (display units) are collectively provided. A game pattern display device B20, an auxiliary game pattern display device H20, a round indicator lamp R10, and other various indicator lamps are provided. The first main game symbol display device A20 (second main game symbol display device B20) provides display etc. 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 As a specific configuration, the first main game symbol display device A20 (second main game symbol display device B20) includes a first main game symbol display portion A21g (second main game symbol display portion B21g) and a first main game symbol display portion A21g (second main game symbol display portion B21g). A symbol reservation display portion A21h (second main game symbol reservation display portion B21h) is provided. Here, the first main game symbol reservation display portion A21h (second main game symbol reservation display portion B21h) is composed of two light emitters, and the number of reservations is indicated by a combination of extinguishing, lighting, and blinking of the light emitters. This number corresponds to the number of reserved random numbers (variation number of main game symbols that have not been executed) related to the first main game (second main game). The first main game symbol display portion A21g (second main game symbol display portion B21g) is composed of, for example, eight red monochromatic LEDs as light emitters, and the first main game symbol (second main game symbol) is Eight LED lighting patterns of "a" to "h" ("k" to "r") are displayed. In addition, the luminous body is not limited to the one composed of a plurality of LEDs, and it is also possible to display by a symbol or the like using a 7-segment LED. In this case, it is desirable to allocate the segment of the stop symbol so that it is difficult for the player to recognize which main game symbol is displayed. In addition, in the present embodiment, during the fluctuation of the first main game symbol (second main game symbol), the right two light emitters ( "g", "h", "q", "r") are flashed (lighting of "g", "h" and lighting of "q", "r" are symbols indicating failure). , but not limited to this, it may be configured to flash a predetermined winning pattern, or to flash a fluctuating pattern indicating that it is fluctuating, or "a" to "h" are turned on in order ("a" → "b" → "c" ... is turned on, but when "b" is turned on, the immediately preceding "a" is turned off) may be configured as follows. Furthermore, the display of the number of reservations is not limited to being composed of two light emitters, and can be configured to display up to four numbers of reservations (for example, it is composed of one light emitter. , hold number 1: lighting, hold number 2: low speed flashing, hold number 3: medium speed flash, hold number 4: high speed flash).

It should be noted that the main game symbols do not necessarily have a role in performance, so in this embodiment, the size of the first main game symbol display device A20 is set to an inconspicuous level. However, in the case of adopting a method in which the main game symbols themselves have an effect role and the decorative symbols are not displayed, it is possible to display the main game symbols on a liquid crystal display such as the effect display device SG, which will be described later. can be configured to

Next, the auxiliary game symbol display device H20 is a device that executes display and the like regarding auxiliary game symbols. Specifically, the auxiliary game symbol display device H20 includes an auxiliary game symbol display portion H21g and an auxiliary game symbol reserve display portion H21h. Here, the auxiliary game symbol reservation display part H21h is composed of two light emitters, and the number of reservations is indicated by a combination of extinguishing, lighting, and blinking of the light emitters, and this number is the number of reservations of the auxiliary game symbol variation. It corresponds to (the number of auxiliary game symbol variations that have not been executed).

Next, the round indicator lamp R10 is composed of four light emitters, and indicates the number of rounds when a win is achieved by the lighting pattern of the light emitters. Referring to FIG. 3, for example, "A" lights up at 8R hits, and "A", "C" and "D" light up at 10R hits. The round indicator lamp R10 is designed to be fully lit for 3 seconds when the RAM is cleared.

There are other light emitters provided in the main control display device D53, and the light emitter "5" is a main control error indicator lamp, which is configured to light up for 30 seconds when the RAM is cleared. Next, the luminous body "6" is a main game pattern probability variation indicator lamp that indicates that the main game pattern is in the probability variation state, and is extinguished if the main game pattern is in the non-probability variation state, and the main game is activated when the power is turned on. It is configured to light up if the pattern is in the probability variation state. In addition, after the power is turned on, when the fluctuation by the main game pattern starts, the probability variation indicator lamp of the main game pattern is extinguished. Next, the light emitting body "7" is an auxiliary game pattern probability variation indicator lamp that indicates that the auxiliary game pattern is in the probability fluctuation state, and if the auxiliary game pattern is in the non-probability fluctuation state, it is turned off, and the auxiliary game pattern is in the probability fluctuation state. It is configured to light up if it is in a fluctuating state. Next, the light emitting body "8" is a right-handed indicator lamp that indicates that the game state is during time saving (game state that should be played to the right). It is configured to light up if it is during time saving (game state that should be hit to the right).

Next, the effect display device SG is a device for executing the display of effect images including decorative symbols that fluctuate and stop interlocking with the main game symbols. Here, as a specific configuration, the effect display device SG includes a display area SG10 in which effects including variable display of decorative symbols are executed. Here, the display area SG10 includes, for example, a decorative symbol display area SG11 that displays moving images of a plurality of rows of decorative symbol variations imitating a slot machine game, a first pending display area SG12 that displays main game pending information, and A second pending display portion SG13, a variation pseudo pending display portion SG14 showing a pseudo pending display as a pending display for effect during fluctuation, and whether or not the variation is performed according to the first main game symbols is based on the second main game symbols. A traffic light SG15 indicating whether or not a change is being made (“○” flashes in the case of a change in the first main game pattern, and “△” flashes in the case of a change in the second main game pattern), and decorations. 4th pattern SG16 indicating that it is fluctuating with the pattern and whether it is a hit or a loss (“☆” blinks if it is fluctuating, “☆” stops with color if it is a hit, and “☆” if it is a loss) ' stops at no color) and has . In this embodiment, the effect display device SG is composed of a liquid crystal display, but may be composed of other display means such as mechanical drums or LEDs. Next, the first suspension display portion SG12 and the second suspension display portion SG13 are each composed of four light emitters, and the light emitters are interlocked with the suspension light emitters of the main game symbols.

Next, the center decoration D38 is installed around the performance display device SG, and has functions such as the passage of game balls, the protection of the performance display device SG, decoration, and the like. In addition, the game effect light emitters D26 are provided in the game area D30 and/or areas other than the game area D30, and play a role of effect by blinking or the like.

Next, the out port D36 is a ball entry port provided below the game area D30. When a game ball enters the out hole D36, various lotteries based on random numbers and prize balls based on the entered ball are not executed, and the game ball is discharged out of the gaming machine. Become. In this embodiment, only the lowest part of the game board is provided with an out hole D36 for receiving game balls that did not win a prize. is also possible. In that case, in order to make it clear that the entrance is not a prize winning opening, it is desirable to use a sticker to display "OUT" or the like so as not to confuse it with a prize winning opening.

Next, the basic structure on the back side of the pachinko game machine will be described with reference to FIG. The pachinko game machine controls the overall operation of the pachinko game machine, and controls the overall game operation (i.e., the game A main control board M that performs control directly related to the interests of players), and a sub-main control unit SM that performs display control etc. related to various effects on the effect display device SG that adds interest to the game content. A sub-sub control unit SS that executes a performance display, an error light emitter SS3 that lights up when a predetermined error occurs to notify the occurrence of an error, a prize ball tank KT, a prize ball rail KR, and a prize according to the winning of each prize opening. A prize ball payout device (set base) KE including a payout unit KE10 for paying out game balls supplied from the ball tank KT to the upper ball tray D20, an error release switch KH3a for canceling a predetermined error, and prize balls. A prize ball payout control board KH for controlling the payout operation by the payout unit KE10, an error indicator KH3 for displaying the status of an error related to payout (for example, 7-segment display), and a prize for controlling the payout operation by the payout unit KE10. A ball payout control board KH, a launcher D42 for launching the game balls (stored balls) in the upper ball tray D20 one by one into the game area D30, a launch control board D40 for controlling the launching operation of the launcher D42, and a pachinko game. A power supply unit E for supplying electric power to each part of the machine and a power switch Ea for turning on/off the power of the pachinko game machine are provided on the rear surface of the front frame D14 (opposite side to the game side).

Also, on the main control board M, there are a first main game start port A10, a second main game start port B10, a left general winning port, a right general winning port, a first big winning port C10, a second big winning port C20, A ball entry state display device J10 capable of displaying the state of entry of a game ball into a prize winning opening is provided, and 4-digit 8-segment displays are arranged in a horizontal row and attached. The ball-entering state display device J10 in FIG. 1 is provided on the surface of the main control board M facing the back side of the game machine. Since it is necessary to open the D18 and check the boards attached to the rear surface of the door unit D18 (game board), the player cannot check it. An example of the ball entry status displayed on the ball entry status display device J10 includes section information based on the total number of outs and a base ratio (a value calculated by "(number of low probability payouts/number of low probability outs) x 100"). etc. Note that the ROM/RAM area for executing the process of step 1550-10 described later and the ROM/RAM area for executing the process of steps 1000-1 to 3500 described later are different areas (addresses do not overlap each other). It may be configured to be

Next, a schematic electrical 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 game machine according to the present embodiment, as described above, has a main control board M that controls the progress of the game, and pays out game balls based on information (signals, commands, etc.) from the main control board M. Based on information (signals, commands, etc.) from the prize ball payout control board KH to control and the main control board M, various effects on the effect display device SG such as fluctuation / stop of the decorative pattern, sound from the speaker D24, A sub-control board S (in this example, a sub-main control section SM and a sub-sub-control section SS are arranged on one board) for controlling the lighting of the game effect light emitters D26 and execution of error notification, etc.; and a power supply unit E that supplies power to the entire game machine including the control board. Here, the sub-control board S is a sub-main control unit that controls various effects on the effect display device SG such as fluctuation and stoppage of decorative patterns, sound from the speaker D24, lighting of the game effect light emitter D26, and error notification. It has two control units, namely, SM and a sub-sub control unit SS for executing display processing such as variable display/stop display of decorative symbols on the effect display device SG, pending display, and advance notice display. In addition, the main control board M, prize ball payout control board KH, sub-main control unit SM and sub-sub control unit SS include a CPU for performing various arithmetic processing, a ROM for pre-storing a program defining the arithmetic processing of the CPU, and a CPU. Equipped with a RAM that temporarily stores data handled by (various data generated during games, computer programs read from ROM, etc.), and a backup area (and backup power supply) to retain information in the event of a power failure. ing.

Schematic configurations of the substrates and electrical connections between the substrates and devices will be described below. First, the main control board M has a winning opening sensor {first main game starting entrance entrance detection device A11s, second main game start entrance entrance detection device B11s, auxiliary game start entrance entrance detection device H11s, first Large winning opening winning detection device C11s, second large winning opening winning detecting device C21s, general winning opening winning ball detecting device}, drive solenoids not shown (first large winning opening solenoid C13, second large winning opening solenoid C23, etc.), information display LEDs (not shown), etc., which are input/output devices essential for the progress of the game (first main game peripheral A, second main game peripheral B, second It is electrically connected to 1 and 2 main game shared peripherals C and auxiliary game peripherals H), and controls the progress of the game based on the input signal from each input device. Further, the main control board M is 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 prize ball payout is performed based on the progress of the game. Information (commands) on prize ball payout control board KH, information on performance/game progress (commands, also referred to as display instruction related information) and information on display of prize ball payouts (commands, (also referred to as payout operation related information) can be transmitted to the sub control board S, respectively.

In addition, in this embodiment, as indicated by the arrows in FIG. The control unit SM is configured to enable one-way communication from the main control board M to the sub-main control unit SM (either serial communication or parallel communication may be used for the communication method). Communication between control boards (between control devices) may be one-way communication or two-way communication. In addition, the main control board M and the prize ball payout control board KH output game-related information and payout-related information to the hall computer HC via the external relay terminal board G as external output information (output to the hall computer HC side). one-way communication).

Next, the prize ball payout control board KH includes a prize ball payout device KE for executing game ball payout, and a device that can be operated by a player and receives a game ball lending request and sends the prize ball payout control board KH. It is connected to a game ball lending device R (sometimes referred to as a card unit R) for transmission. Also, although not shown, in the present embodiment, a control circuit unit (firing control board D40) of the launching device is provided in the prize ball payout control board KH, and the prize ball payout control board KH and the launching device D42 ( It is also connected to the launch handle, launch motor, ball feeder, etc.). In the present embodiment, the game ball lending device R is separated and adjacent to the gaming machine. However, it may be integrated with the gaming machine. Control and management control of recording media for lending electronic money or the like may be performed in an integrated manner.

Here, when it is detected (touch detection) that the player has directly operated the firing handle D44, the firing device D42 determines the firing strength (firing position) based on the operation amount of the firing handle, and It is configured to shoot game balls one by one toward an arbitrary position, and even if game balls are shot continuously, counters and timers are used so that game balls cannot be shot in excess of 100 in one minute. It is configured such that game balls are shot at regular intervals (for example, 599.9 ms/1 ball). In other words, regardless of the game state such as the probability variable game state or the game state such as whether or not the special game is executed, the game balls are always shot at regular intervals (the shooting speed is the same). As a result, the player's shooting skill is appropriately reflected regardless of the game state. More specifically, when the player desires to hit to the right, the player can hit to the right by manipulating the firing handle D44 to a position corresponding to the firing intensity at which the player can hit to the left. is desired, left-hand hitting can be performed by operating the shooting handle D44 to a position corresponding to the firing intensity at which left-hand hitting can be performed. Regardless of the state of (1), the game ball can always be shot with the shooting intensity based on the operation of the shooting handle D44.

The shooting handle D44 is provided with a shooting stop switch (not shown), and is configured so that the player can stop shooting game balls at an arbitrary timing (can shoot one ball at a time). ing. Specifically, even when the player is operating the shooting handle D44 (direct operation of the shooting handle D44 is detected (touch detection)), the game ball can be released by operating the shooting stop switch. It is possible to stop firing. Here, "direct operation" means using a part of the player's body to touch the gaming machine and play a game. In this example, from the viewpoint of gambling, the performance of the launching device D42 is not changed over a predetermined period of time or due to external noise, etc., and the launching motor and launching handle (strength adjustment) are arranged so that durability is ensured. function), the control circuit of the launcher is designed respectively. In addition, it is desirable that the shooting handle D44 does not have a function of vibrating the shooting handle D44 so as not to hinder the adjustment of the shooting position by the player.

In addition, the part that gives kinetic energy to the game ball in the launching device D42, which is the entire device related to shooting the game ball, is composed of one shooting motor. Also, the shooting handle D44 is set so that the shooting intensity returns to 0 when the player does not directly operate it (it is urged by a spring or the like toward the reference position and returns to the reference position when the hand is released from the shooting handle D44). , and the strength adjustment skill of the player can be reflected in the game result.

In this example, the game balls to be used are balls having a diameter of 11 mm and a mass of 5.4 g or more and 5.7 g or less.

Next, the sub-control board S includes, as described above, the effect display device SG for displaying decorative patterns and the like, the speaker D24, the game effect light emitter D26, and other driving devices for effect (not shown, but the so-called It is connected to the motor, solenoid, etc. of the movable body accessory for production. Also, by executing a predetermined operation (long press or press), the sub-input button SB can start or end the measurement of the base value, execute a predetermined effect, or start displaying the maintenance mode. is connected to the sub control board S. Further, it can be determined that the sub-input button SB has been operated based on detection by the sub-input button detection device. In this embodiment, as described above, the sub-control board S has the sub-main control unit SM and the sub-sub-control unit SS. Lighting control of the illumination) light emitter D26 and determination control of display contents to be displayed on the effect display device SG are performed, and display control (substantial display control) on the effect display device SG is performed by the sub-sub control unit SS. configured to take place. In this embodiment, the sub-main control section SM and the sub-sub-control section SS are configured to be integrated on the sub-control board S, but the present invention is not limited to this (configured as separate boards). (Although it may be possible to do so, there are merits such as a space merit and a reduction in the situation where noise is mixed in the wiring etc.). Also, the division of work between the two controllers can be appropriately changed, for example, the sub-sub-controller SS executes voice control (preferable when adopting a VDP integrated with a voice control circuit). Also, instead of giving physical prize balls as prize balls, electronic values may be given.

Next, the flow path of the game ball to be played will be described with reference to the image diagram of the flow path of the game ball shown in the lower part of the figure. In the gaming machine according to the present embodiment, the game balls launched into the game area D30 enter the respective ball entrances {first main game start opening A10, second main game start opening B10, first big winning opening C10, first The ball enters one of the two major winning holes C20, the general winning hole, and the out hole D36}, passes through the ball entering sensor corresponding to each ball entering hole, and is guided into the gaming machine (inside the gaming machine frame D). Here, the game ball entered into the first main game start opening A10 passes through the first main game start opening confirmation sensor provided for fraud detection. After that, all game balls guided into the game machine pass through the total discharge confirmation sensor and are discharged out of the game machine. It should be noted that, although not particularly shown in this example, a switch for confirming the entry of a ball {each entry opening (for example, the first main game start opening A10, the second main game start opening B10, the first big winning opening C10, the second 2 major winning opening C20, general winning opening) passes through a game ball, which is different from the switch for detecting the entry into each ball entry opening or a plurality of switches}. shall be

Next, FIG. 6 is a working diagram relating to the second big prize winning opening C20 in this embodiment, more specifically, an upper shielding member C24 and a lower shielding member provided inside the second big winning opening C20 It is an operation diagram related to whether or not a game ball can enter the V winning opening C22 based on the open mode and the closed mode of C25. In the present embodiment, if the game ball continues to be shot toward the second big winning hole C20 during execution of the small winning game (if it continues to hit to the right), the game will be played to the second big winning hole C20. It is configured so that a plurality of balls enter {for example, the opening mode of the second big prize mouth C20 (second big prize mouth electric accessory C21d) is "open for 0.2 seconds → close for 0.8 seconds → 1 seconds open → closed for 1 second → open for 1 second → closed”}, therefore, whether or not a game ball can enter the V winning opening C22 is determined by whether the game ball in the second big winning opening C20 It is determined by whether or not the opening timing of the shielding member C25 matches well. Hereinafter, the action of the game ball entering the second big winning hole C20 during the small winning game will be described in detail.

First, as shown in FIG. 6(a), the second big winning hole C20 has an inside thereof (as a flow path of the game ball inside the second big winning hole C20) for entering the second big winning hole C20. A second big winning opening winning detection device C21s for detecting a ball, a V winning opening C22, a V winning opening winning detection device C22s for detecting a ball entering the V winning opening C22, and a ball not entering the V winning opening C22. a second big winning hole outlet C23 which is a discharge channel for the game ball, and a second big winning hole discharge detection device C23s for detecting the ball entering the second big winning hole outlet C23; A lower shielding member C25 provided above the V winning opening C22 and an upper shielding member C24 provided above the lower shielding member C25 are provided. A closed state in which the game ball can or easily be prevented from falling by protruding (advanced state), and a closed state in which the game ball is retracted into the game board (back side as viewed from the player). It is configured to be able to take an open state (a so-called tongue type attacker) in which it is impossible or difficult to prevent the game ball from falling (a game ball can fall) by being in a state (retracted state). configuration). More specifically, when the upper shielding member C24 is in the closed state, the game ball cannot or hardly reaches the lower shielding member C25, and when the upper shielding member C24 is in the open state, the game ball is below. When the shielding member C25 is reachable or easily reached, and the lower shielding member C25 is closed, the game ball cannot or is difficult to reach the V winning opening C22, and when the lower shielding member C25 is open. , the game ball is configured to reach or easily reach the V winning opening C22. Next, a specific flow path of a game ball entering the second big winning hole C20 during execution of a small winning game will be described.

As shown in FIG. 6(a), a game ball entered into the second large winning opening C20 during execution of the small winning game passes through the second large winning opening winning detection device C21s, and then the upper shielding which is in the closed state. It is guided to the member C24, and stops (is placed on the upper shielding member C24) in an area (a staying area) formed by the upper shielding member C24 and the inner wall surface of the second big prize winning opening C20. In this embodiment, the parking area is configured so that only one game ball can be placed, so as shown in FIG. In this case, the game ball guided into the second big winning hole C20 after the timing of placing the certain game ball collides with the certain game ball placed on the upper shielding member C24. , the flow path reaching the second large winning opening discharge detection device C23s and the second large winning opening discharging opening C23 without passing through the upper shielding member C24 (V It becomes impossible or difficult flow path) (In addition, the stationary area is configured so that the certain game ball is not extracted from the stationary area by the impact when the other game ball collides. is being used). Here, the right part of FIG. 6(a) is a cross-sectional view schematically showing the XX cross section in FIG. 6(a). As shown in the cross-sectional view, in FIG. 6(a), both the upper shielding member C24 and the lower shielding member C25 are in a closed state {protruding from the game board (toward the player as viewed from the player) (the cross-sectional view )}, and in this case, it is understood that the game ball can be placed on the upper shielding member C24.

In this embodiment, the upper shielding member C24 is set to be opened after a certain period of time from the start of the small winning game (in this example, 5 seconds after the start of the small winning game), and the lower shielding member C25. is configured to repeat the transition between the closed state and the open state at a constant cycle (4-second cycle in this example) from the time the power is turned on (the opening timing of the lower shielding member C25 is periodic). , Whether or not a ball can enter the V winning opening C22 is mainly determined by the timing when the upper shielding member C24 is opened (in other words, the timing when the small winning game is started) (when the lower shielding member C25 is opened). A game ball can enter the V winning opening C22 when a small hit game is started in which the timing of the state and the timing of the opening of the upper shielding member C24 are scheduled to substantially match).

Note that this embodiment is merely an example, and the upper shielding member C24 and the lower shielding member C25 have a state in which it is impossible or difficult to impede the fall of the game ball, a state in which it is possible or easy to impede the fall of the game ball, Any structure may be used as long as it is possible to transition the , and other configurations are not limited at all.

In addition, in the present embodiment, two shielding members, the upper shielding member C24 and the lower shielding member C25, are provided to prevent the game ball from entering the V winning hole C22. A member may be used to prevent the game ball from entering the V winning hole C22. Furthermore, even in a gaming machine that shifts to the probability variable gaming state after the special game is completed by the game ball entering the specific area C22 during the special game, the game ball entering the specific area C22 may be configured to provide a shielding member that obstructs the In such a configuration, the opening mode of the shielding member may be configured to differ depending on the jackpot symbol that triggered the jackpot. As the opening mode of the member, regardless of the jackpot pattern, the shielding member changes from the closed state to the open state after 50 ms from the distribution game execution round start timing or at the distribution game execution round start timing, (2) Distribution game execution round 200 ms after the end timing of the shielding member is changed from the open state to the closed state. Therefore, there is a timing at which the shielding member is opened regardless of the jackpot pattern, and the distribution game execution round is completed before the period from the start of the distribution game execution round to the first opening of the shielding member. It can be configured such that the time period from the time of closing until the final closure of the shielding member is longer.

Next, in the present embodiment, a plurality of set values are provided corresponding to the winning probability of the main game symbol of the gaming machine. Therefore, the configuration of the gaming machine in which a plurality of setting values are provided in this manner will be described in detail.

First, the pachinko gaming machine according to the present embodiment has a plurality of setting values for differentiating the winning probability of the main game pattern. Yes). Hereinafter, as the device for changing settings in this example, setting keys for changing settings will be used for explanation, but the present invention is not limited to this, and a general input device such as a DIP switch may be employed. In addition, from the viewpoint of enabling only a specific administrator to change settings, it is preferable to use a setting key for changing settings, but in addition, password input, biometric authentication, etc. The configuration may be such that the setting can be changed using an authentication system. It should be noted that the setting change includes not only changing the setting value but also setting the same setting value again.

Here, in this example,
(1) When the power is turned on while the setting key is on and the RAM clear button is on, the setting can be changed. (2) The setting key is on and the RAM clear button is on. (3) When the power is turned on with the setting key turned off and the RAM clear button turned on, the RAM is cleared. (4) When power is turned on while the setting key is off and the RAM clear button is off, the power is restored without executing the RAM clear. When changing the set value, the set value may be changed by operating the RAM clear button, or a button (set A change button) or the like may be used, or other input means managed by the main control board M may be used for change.

Below, the processing related to the setting change when the power is turned on will be described with reference to FIG. 7 .

First, FIG. 7 is a main flow chart showing the flow of general processing performed by the main control board M according to this embodiment. After the game machine is powered on, at step 1001, the CPUMC of the main control board M determines whether or not the setting key has been operated. If Yes in step 1001 , the process proceeds to step 1002 . If it is determined in step 1001 that the setting key is on (No in step 1001), then in step 1030 the CPUMC of the main control board M determines whether or not the RAM clear button is on. If Yes in step 1030, the process proceeds to step 1003 to execute setting change processing. On the other hand, if No at step 1030 , at step 3850 , the CPUMC of the main control board M executes setting confirmation processing, which will be described later, and proceeds to step 1007 .

Next, in step 1002, the main control board M confirms the input port of the RAM clear button, and determines whether or not the reset button (RAM clear button) of the power supply unit E has been operated. determines whether or not an operation to intentionally clear the contents of the RAM has been performed. If Yes at step 1002, at step 1004, the CPUMC of the main control board M clears all the contents of the RAM on the main control board M side. Next, in step 1006, the CPUMC 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 unit SM side (transmitted at this timing). (Alternatively, a command may be set at this timing and transmitted in a control command transmission process, which will be described later), and the process proceeds to step 1015 . On the other hand, in the case of No in step 1002, in step 1007, the CPUMC of the main control board M determines whether or not information indicating that the power has been turned off normally is stored in the RAM. In the case of 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 failure and the comparison with the amount of information). Next, at step 1010, the CPUMC of the main control board M determines whether or not the contents of the RAM are normal (whether or not the information at the time of power failure is correctly backed up in the RAM) based on the check result. 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 information indicating that the power has been turned off normally is not stored in the RAM, the process proceeds to step 1004 . If No in step 1010, that is, if the data backed up in the RAM is normal, in step 1012, the CPUMC of the main control board M will store (back up) in the RAM of the main control board M An information command is acquired, and in step 1014, the acquired various information commands are transmitted to the sub-main control unit SM side (they may be transmitted at that timing, or the command may be set at that timing and a control command (to be described later) may be sent). It may be configured to transmit in the transmission process), in step 1014-1, the CPUMC of the main control board M returns the solenoid {Second main game start opening electric accessory of the second main game start opening B10 B11d, the open or closed state of the large winning opening (eg, first large winning opening C10, second large winning opening C20) and movable pieces described later (eg, upper shielding member C24, lower shielding member C25, etc. in FIG. 6) In order to restore the state before the power was cut off, it is determined whether the solenoid operation bit is on in the order of the second main game starter electric accessory B11d, the big winning opening, and the movable piece. 2nd main game starting port/large winning port/movable piece is determined to be open before disconnection, store the solenoid operation flag in the corresponding address) to open again), and the process proceeds to step 1015. do. At step 1015, the CPUMC of the main control board M saves in the RAM information indicating that the power has been turned on normally, and proceeds to step 1016. Next, in step 1016, the CPUMC of the main control board M is triggered by a scheduled execution interrupt (for example, a hardware interrupt every approximately 1.5 ms) related to the main processing on the main control board M side shown in FIG. However, in this example, the interrupt period is set to T) is permitted {as a result, when the scheduled execution interrupt timing is reached, (b) in the figure is executed}, and in step 1018 Transition. After step 1018, the CPUMC of the main control board M repeatedly executes various random number updating processes (for example, random number counter incrementing process) until the next scheduled interrupt timing is reached.

As described above, in this embodiment, when the power is turned on while the setting key is being operated, if the RAM clear button is on, the setting change mode is entered, and if the RAM clear button is off, the setting change mode is entered. is configured to shift to a setting display mode (setting confirmation mode). As an operation of the administrator, if the setting key is operated and the power switch is turned on while the RAM clear button is pressed, the setting change mode is entered. is configured to switch to the setting display mode when is turned on. Further, in the setting change mode, each time the setting change button is pressed, the display of the setting value displayed on the displayed setting value display device is switched like "1→2→3...". Then, when the setting key is returned to a predetermined position (the position where the setting key can be inserted and removed), the setting value is determined so that the setting value displayed on the setting value display device is obtained. Further, the setting confirmation mode may be terminated when the setting key is returned to a predetermined position (position where the setting key can be inserted/extracted) from the setting confirmation mode. In addition, when the power is turned on with the RAM clear button turned on and the setting change mode is entered, a voice saying "The setting change mode has been entered" is output from the speaker, and then the setting key is moved to the specified position. , and the setting change mode ends, the speaker may be configured to output a voice saying "the setting change mode has ended." In addition, when the power is turned on with the RAM clear button turned off and the setting confirmation mode is entered, a voice saying "The setting confirmation mode has been entered" is output from the speaker, and then the setting key is moved to the specified position. , and the setting confirmation mode is terminated, the speaker may be configured to output a voice saying "setting confirmation mode is terminated." In such a configuration, not only the sound but also various light emitters such as frame light emitters and effect display devices can be used to determine whether they are in the setting change mode or the setting confirmation mode. Various luminous bodies such as luminous bodies and various luminous bodies such as frame luminous bodies and production It may be configured so as to be notified by a display device.

As in the present embodiment, when the setting key is on, depending on whether the RAM clear button is turned on or off, when the power is turned on, the transition to the setting change mode or the setting confirmation mode is switched. , Controlled by the sub-control board S side, the setting change mode is changed by the sound output from the speaker D24, the lighting mode of the light emitting body for effect (game effect light emitting body), the display by the effect display device SG, etc. It may also be configured to notify the fact that the mode has been changed to the setting confirmation mode and the like. For example, when shifting to the setting change mode, it outputs the voice "in the setting change mode", and when it shifts to the setting display mode, it outputs the voice "in the setting confirmation mode". , When the setting change mode ends, output the voice "The setting has been changed", and when the setting display mode ends, output the voice "Setting confirmation mode finished" may be configured as follows.

It should be noted that the RAM is cleared in step 1004 so that the probability of operation (probability of big hit) becomes low, and the probability always becomes low after the setting is changed. In addition, the winning probability of the normal design is also similarly low because the RAM is cleared after the setting is changed.

Next, FIG. 8 is a flowchart showing the flow of setting change processing according to this embodiment. When the setting change process is started, a command indicating the start of the setting change process is set and transmitted to the sub control board S in step 1003-1. As a result, the sub-control board S can display "in setting change mode" or the like on the effect display device (FIG. 65). At the same time, it is output to the external terminal board as an outer end signal (security signal). At step 1003-2, it is checked whether the set value (set value data) is within the normal range ("1" to "6"), and if YES, the process proceeds to step 1003-4. If NO in step 1003-2, that is, if the set value (set value data) is determined to be an abnormal value other than "1" to "6", the minimum payout rate is set in step 1003-3. A value (set value data) of "1" is set, and the process proceeds to step 1003-4. In step 1003-4, a special symbol display device (first main game symbol display device A20 or second main game symbol display device B20 may be called in a display mode (for example, full lighting) indicating that the setting is being changed. ) is turned on, and at the same time, the current set value is displayed on the set value display device. Next, in step 1003-5, it is checked whether or not there is an input signal by pressing the RAM clear button, and if NO, the process proceeds to step 1003-11. If YES in step 1003-5, the setting value data switched by the setting key is obtained in step 1003-6, and the process proceeds to step 1003-7. At step 1003-7, it is checked whether the current set value (set value data) is not the maximum value. to add. If NO at step 1003-7, that is, if it is determined that the set value (set value data) is the maximum "6", the lowest ball payout rate "1" is set at 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 set value data is updated, and in step 1003-11, it is checked whether or not there is a fall of the set key signal. At step 1003-11, if there is no fall of the setting key signal, the processing proceeds to step 1003-5, and the processing from step 1003-5 to step 1003-11 continues 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 change, all the LEDs of the special symbol display device are turned off in step 1003-12, and the setting is being changed. After clearing the display mode indicating that the setting change process is completed, a command is set and transmitted to the sub-control board S in step 1003-13. As a result, the sub-control board S hides the message "setting change mode in progress" being displayed on the effect display device, and stops the output to the external terminal board. After the processing of step 1003-13 is completed, the processing shifts to step 1004 of this processing, and RAM clear is executed. In addition, in the processing flow of this embodiment, the setting value switched by the setting key is determined by the fall of the setting key signal (step 1003-11), but this is not the only option. The set value may be determined by performing the main operation (not shown, ball lending button, steering wheel sensor, etc.). Furthermore, the input information of various switches (various gates, starting ports, attackers, etc.) provided on the game board may determine the set values. In this case, the player touches the various switches. Unauthorized change of settings can be prevented by not being able to change settings, and adopting such a complicated procedure for changing settings also serves to prevent unauthorized change of settings. Also, throughout the entire process, the setting value data managed by the RAM has been described using "1" to "6", but the setting value data "0" to "5" may be substituted for the processing. . By doing so, when the RAM is cleared due to a RAM abnormality, the abnormality determination (NO in step 1003-2) due to setting "0" to the value of the RAM that manages the set value data can be avoided. can be done. If the set value data is managed as "0" to "5", "0" is treated as set value data and is not judged to be abnormal. Furthermore, when some kind of lottery is performed using set value data (for example, when different data is selected for each set value in a look-ahead table or the like), there is an advantage that offset processing in table selection is easy to perform. Specifically, when setting value data is managed with "1" to "6", when using it as it is as offset data for table selection, it is necessary to perform processing such as subtracting 1 from the start address. When the value data is managed with "0" to "5", the value can be used as it is as the offset data. When actually displaying the set value data on the set value display device, the set value data is displayed as "1" to "6" by adding 1 to the set value data.

In this embodiment, an error is generated when the set value (set value data) is an abnormal value other than "1" to "6". In this case, the setting is changed again (the power is turned on by turning on the setting key and the RAM clear button), and the set value is set again appropriately. In this way, it is configured such that the game cannot be played if the set value remains an abnormal value other than "1" to "6". In addition, since it is configured so that it is possible to shift to a state in which the setting can be changed only when the set value data is "0", which is out of range, when an error occurs, the set value data By clearing the RAM including the storage area of , "0", which is out of range, is set to the set value data. When setting value data is managed as "0" to "5", if the configuration is such that "0" is set as the setting value data by RAM clearing, etc., the setting value data will remain within the range even if the RAM is cleared. Therefore, the configuration is such that an error does not occur.

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) is confirmed. However, as the execution timing of the confirmation process,
(1) Timing immediately after turning on the power (2) Timing of entering a ball into a predetermined opening (3) Timing of entering a ball into a main game starting opening (4) Timing of entering a ball into an auxiliary game starting opening (5) Big win Timing of entering the ball into the mouth (6) Main game pattern fluctuation start timing (7) Timing immediately after the game state is switched (8) Timing immediately after the start of the big win (9) Timing immediately after the end of the big win Execute at the above timing. good too. Note that the setting value (setting value data) confirmation process may be executed only at one of the above nine timings, or the setting value (setting value data) confirmation process may be executed at a plurality of the above nine timings. A confirmation process may be performed. For example, since it is configured to execute checksum processing when the power is turned on, it is not necessary to provide a process to check only the set values (set value data). The setting value data) may be configured so as not to execute the confirmation process.

Next, FIG. 9 is a flow chart of setting confirmation processing related to the subroutine of step 3850 of FIG. 7 in this embodiment. First, in step 3852, the CPUMC of the main control board M displays the set values corresponding to the current set value information on the set value display device. Next, in step 3854, the CPUMC of the main control board M determines whether or not the setting confirmation has been completed (the setting key switch signal has fallen). Any of the conditions for ending the setting display mode described above may be used as the condition for determining that the setting confirmation has been completed. If No in step 3854, the processes of steps 3852 and 3854 are repeatedly executed. On the other hand, in the case of Yes in step 3854, in step 3856, the CPUMC of the main control board M erases the display of the set values displayed on the set value display device, and proceeds to the next process (process of step 1007). . It should be noted that immediately after starting execution of the setting confirmation process in the same figure (for example, immediately before executing the process of step 3852) and immediately after starting execution of the above-described setting change process (for example, immediately before executing the process of step 1003-14) , the process of permitting timer interrupts may be executed in the same manner as the process of step 1016 .

Next, FIG. 10 is a flow chart showing the flow of timer interrupt processing performed by the main control board M. As shown in FIG. The CPUMC of the main control board M executes the processing shown in FIG. That is, with the arrival of the scheduled interrupt period T (for example, a hardware interrupt at approximately 1.5 ms intervals) as a trigger, first, in step 1000-S, the CPUMC of the main control board M performs the setting key operation determination processing described later. Run. Next, at step 1000-1, the CPUMC of the main control board M executes input processing, which will be described later. Next, at step 1000-2, the CPUMC of the main control board M executes various random number updating processes, which will be described later. Next, at step 1000-3, the CPUMC of the main control board M executes an initial value update type random number update process, which will be described later. Next, at step 1000-4, the CPUMC of the main control board M executes an initial value random number updating process, which will be described later. Next, at step 1000-5, the CPUMC of the main control board M executes timer subtraction processing, which will be described later. Next, at step 1000-6, the CPUMC of the main control board M executes the starting port 2 validity period setting process (processing for setting the validity period of the second main game starting port B10), which will be described later. Next, at step 1000-7, the CPUMC of the main control board M executes winning monitoring processing, which will be described later. Next, at step 3000, the CPUMC of the main control board M executes prize ball payout command transmission control processing, which will be described later. In addition, the number of prize balls paid out when a game ball wins a prize in each prize opening is 4 balls from the first main game start opening A10, 1 ball from the second main game start opening B10, 1 ball from the first main game start opening C10 and the second There are 13 balls in the big winning hole C20, 3 balls in the left general winning hole (also called general winning hole), and 2 balls in the right general winning hole. These prize ball payout numbers are examples, and the number of prize ball payouts when entering the first main game start port A10 and when entering the second main game start port B10 are different. Alternatively, the number of prize balls to be paid out may be different between when the ball enters the first big prize hole C10 and when the ball enters the second big prize hole C20. In addition, when a game ball enters the left general winning hole, a lottery such as a win-or-fail lottery is not executed, and a predetermined number of prize balls (three balls in this example) are awarded to the player. It is In addition, when a game ball enters the right general winning hole, a random number on the auxiliary game side is acquired, and a predetermined number of prize balls paid out (two balls in this example) are provided to the player. It is However, the number of winning balls in all the winning holes provided in the pachinko gaming machine according to this example does not exceed 15 for one winning (winning ball), and is constant regardless of the game state (abnormal (Except when it is invalidated due to circumstances or an error), and is configured so that prize balls are not paid out except for winning prizes, realizing various game states. , the direct result of the game is summarized as "whether or not the shot game ball wins a prize in a predetermined winning hole".

In this example, since the specific prize ball payout control process is performed by the prize ball payout control board KH instead of the main control board M, the main control board M manages the progress of the payout control in real time. However, if there is an accident such as a power failure during payout of one game ball, the correct number of prize balls may not be delivered. For this reason, in this example, a retry function in the event of an abnormality that again pays out game balls for the winning prize (for example, when a game ball enters the first main game start port A10 and one game ball is paid out , and after that, after the power is restored, the remaining 3 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 when such an abnormality occurs. No function is required.

Next, at step 2000, the CPUMC of the main control board M executes a ball entry detection process, which will be described later. Next, at step 1100, the CPUMC of the main control board M executes an auxiliary game content determination random number acquisition process, which will be described later. Next, at step 1200, the CPUMC of the main control board M executes an electric accessary product drive determination process, which will be described later. Next, at step 1300, the CPUMC of the main control board M executes main game content determination random number acquisition processing, which will be described later. Next, at step 1400, the CPUMC of the main control board M executes a main game symbol display process which will be described later. Next, at step 1700, the CPUMC of the main control board M executes a small winning game control process which will be described later. Next, at step 1750, the CPUMC of the main control board M executes upper shielding member drive control processing, which will be described later. Next, at step 3450, the CPUMC of the main control board M executes the below-described lower shielding member drive control process. Next, at step 1950, the CPUMC of the main control board M executes V winning hole entry ball determination processing, which will be described later. Next, at step 1600, the CPUMC of the main control board M executes a special game control process which will be described later. Next, at step 1600-1, the CPUMC of the main control board M executes a big winning opening validity period setting process. Next, at step 1550, the CPUMC of the main control board M executes special game operation condition determination processing, which will be described later. Next, at step 1550-1, the CPUMC of the main control board M executes abnormality detection processing. Next, at step 1550-2, the CPUMC of the main control board M executes the incoming ball passing time abnormality detection process. Next, at step 1550-3, the CPUMC of the main control board M executes a game state display process. Next, at step 1550-4, the CPUMC of the main control board M executes the handle state signal inspection process. Next, at step 1550-5, the CPUMC of the main control board M executes an out port monitoring process. Next, at step 1550-6, the CPUMC of the main control board M executes LED output processing. Next, at step 1900, the CPUMC of the main control board M executes fraud detection information management processing, which will be described later. Next, at step 1950-1, the CPUMC of the main control board M executes error management processing, which will be described later. Next, at step 1550-7, the CPUMC of the main control board M executes firing control signal output processing, which will be described later. Next, at step 1550-8, the CPUMC of the main control board M executes test signal output processing. Next, at step 1550-9, the CPUMC of the main control board M executes solenoid output processing. Next, at 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 section side). Next, at step 3500, the CPUMC of the main control board M executes external signal output processing, which will be described later. Next, at step 1550-10, the CPUMC of the main control board M executes ball entry state control processing. Next, in step 1550-11, the CPUMC of the main control board M sets to permit the generation of timer interrupts, and returns to the processing that was being executed immediately before execution of this interrupt processing.

Next, various processes performed in the timer interrupt process performed by the CPUMC of the main control board M will be described in order.

The setting key operation determination process determines whether or not the setting key switch has been operated (whether the setting key is input to the setting key insertion port, and whether the key switch for changing the setting is in the ON state). or not, etc.). When it is determined that the setting key switch has been operated in the setting key operation determination processing in the timer interrupt processing (i.e., the setting key is inserted into the setting key insertion port and the setting key is rotated in a predetermined direction). If the key switch for changing the setting is ON), it can be determined that it is an illegal operation of the setting key during the game or an operation of the setting key that does not involve opening the door, and can be processed as an error. . It should be noted that input of the setting key may be determined only in the first timer interrupt process after the power is turned on.

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. Switch (for example, first main game start entrance detection device A11s, second main game start entrance detection device B11s, auxiliary game start entrance detection device H11s, first big winning entrance winning detection device C11s, second Large winning entrance winning detection device C21s, general winning detection device, etc.), out ball count switch for detecting the ball entering the out mouth D36, 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, impact detection signal, touch state signal, and magnetic detection signal 2 (detection signal by magnetic detection sensor 2) are monitored. In this example, for a special input such as a RAM clear switch, input determination and the like are performed by a process different from the input process.

Various random number update processing is a process of relatively simply updating (for example, adding a constant) the random number used for lottery that has an extremely low impact on the ball output. , Auxiliary game symbol variation mode random numbers) and variation pattern random numbers (for example, variation mode lottery random numbers) are updated.

The initial value update type random number update process is a process of updating the random numbers used in the lottery that has a certain amount of influence on the ball output (a process different from the various random number update processes described above). Random numbers per symbol (for example, random numbers for winning auxiliary game symbols), random numbers for normal symbols (for example, random numbers for stopping symbols for auxiliary game symbols), random numbers for special symbols (for example, random numbers for lottery symbols), software random numbers for special symbols, etc., to be described later. This is a process for

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 by the initial value update type random number update process used in the lottery that has a certain degree of impact on the ball output. As an example of the random number to be updated in the example, an initial value random number per normal design, a normal design design initial value random number, a special design design initial value random number, and a soft initial value random number per special design can be exemplified. Incidentally, the normal per symbol initial value random number and the normal symbol symbol initial value random number are random numbers that are updated by the initial value random number update process when a plurality of auxiliary game content determination random numbers are provided.

The timer subtraction process is a 1-byte timer or a 2-byte timer (for example, timers for managing first and second main game pattern fluctuations, timers for opening the second main game starter electric accessory, timers for special games, timers for opening time, etc. ) and so on.

The start opening 2 effective period setting process is a winning opening (for example, , second main game starter B10).

The prize-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 requesting transmission of a command to be transmitted to the effect control board.

The large winning opening valid period setting process is a process of saving the result of valid period determination of the large winning opening (eg, the first large winning opening C10, the second large winning opening C20). As will be described later, when the special winning opening has a specific area C22, the result of valid period determination of the specific area C22 may be saved by the special winning opening valid period setting process.

The abnormality detection process is a process of monitoring magnetism, disconnection/short circuit, power source monitoring, radio wave monitoring, opening/closing state of glass frame set/game board D35, impact monitoring, and the like.

The ball passing time abnormality detection process is to detect the ball passing time abnormality when the game ball enters various ball entrances (for example, the first main game start opening A10). This is the process of monitoring the ON time (continuous ON time of the entering ball sensor).

The game state display process includes the number of times the special electric accessory operates continuously (the number of rounds executed in the big hit), the error state, the number of balls that are suspended in operation of the normal symbol display device (currently displayed on the auxiliary game symbol display device H20 Auxiliary game reserved ball number) and operation reserved ball number of special symbol display device (current main game reserved ball number displayed on first main game pattern display device A20 or second main game pattern display device B20) display request This is the process of 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.

The LED output process means display on the special symbol display device (for example, display of the first main game symbol on the first main game symbol display device A20, display of the second main game symbol on the second main game symbol display device B20, display of the second main game symbol on the second main game symbol display device B20, 1. Display of the number of operation pending balls on the first main game side on the main game symbol display device A20, display of the number of operation pending balls on the second main game side on the second main game symbol display device B20), display on the normal symbol display device (Display of auxiliary symbols in the auxiliary game symbol display device H20, display of the number of operation pending balls on the auxiliary game side in the auxiliary game symbol display device H20), display of error state, display of game state, display of hitting (for example, right In order to display the situation where you should hit and the situation where you should hit left) and the number of times the special electric accessory operates continuously (display the number of rounds in the big hit), initialization and display of the display This is the process of sequentially controlling the LED output controlled on the main control board M side, such as data output.

The shooting control signal output process is a process of outputting a signal for prohibiting or permitting shooting of game balls, and the details will be described later.

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

Solenoid output processing refers to the output data of the normal electric accessory (for example, the second main game start opening electric accessory B11d) solenoid and the big winning opening (for example, the first big winning opening C10, the second big winning opening C20) solenoid This is the process of outputting the As will be described later, when shielding members (upper shielding member C24, lower shielding member C25) are provided in the big winning opening, the output data of the movable piece solenoid is output in the solenoid output process.

In the ball-entering state control process, calculation of a base value to be displayed on the ball-entering state display device J10, storage of the calculation result, display control of the calculation result, and the like are executed. At this time, if a setting change means to be described later is provided, the normal prize ball count counter value, normal out count counter value, total out count counter value, final base value of the immediately preceding section, etc. are stored for each set value. It is also possible to configure the display to be displayed on the ball entry state display device. More specifically, when the power is turned on, the performance of the gaming machine corresponding to the current settings (for example, the probability of winning a jackpot or the number of winning balls in each winning hole) is read, and a storage area corresponding to the current settings (for example, , a storage area for storing the normal prize ball count counter value, the normal out count counter value, the total out count counter value, the final base value of the immediately preceding section, etc.). Then, based on the values stored in the respective storage areas, the entry state information is generated and displayed. By configuring in this way, it is possible to appropriately generate and display ball entry state information (for example, base value) for each setting. In addition, regarding the ball entry status information displayed on the ball entry status display device, by operating a dedicated ball entry status display switching button, or by operating a setting change button (a device operated to change the set value) (For example, if the current setting is 1, when the ball entry state display switching button is operated once, the ball entry state information of setting 2 is displayed, and another operation is performed. Then, the ball entry state information of setting 3 is displayed), so that the latest information for each setting can be confirmed. Here, when using the setting change button, in order to prevent the setting from being changed by operating the setting change button, the configuration using the setting key described above (for example, the power is turned on and the setting key switch is turned to the left) A configuration in which the display content is switched by operating the setting change button while the display is on) is preferable. In addition, when the display of the entering state information is switched by the entering state display switching button or the setting change button, the display may be returned to the current setting after a predetermined time elapses.

Next, FIG. 11 is a main flow chart showing the flow of NMI interrupt processing (at the time of power failure) performed by the main control board M. As shown in FIG. First, NMI interrupt processing will be described. As described above, the CPUMC of the main control board M is configured so that the power interruption signal from the reset IC is input to the NMI terminal of the CPU, and when the power supply to the gaming machine is interrupted, the process of FIG. is executed. That is, when the gaming machine is powered off (in this example, when an NMI interrupt occurs), at step 1019-1, the CPUMC of the main control board M determines whether or not a timer interrupt is occurring. If Yes at step 1019-1, at step 1019-2, the CPUMC of the main control board M determines whether or not information indicating that the power has been turned on normally 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 at step 1019-2, at step 1019-3, the CPUMC of the main control board M saves information indicating an abnormal power failure in the RAM, and proceeds to the next step 1022. On the other hand, if No at step 1019-2, at step 1019-4, the CPUMC of the main control board M saves information indicating normal power-off in the RAM, and at step 1020, the main control board M The CPUMC sets power failure information (for example, checksum) based on the information in the RAM area. Next, at 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. Although an example of executing the power interruption process (FIG. 11) by inputting the power interruption signal to the NMI terminal of the CPU has been described, this is not restrictive. It is also possible to determine power interruption and perform power interruption processing by monitoring a specific input port in main control board side main processing (FIG. 7) or timer interrupt processing (FIG. 10).

Next, FIG. 12 is a flow chart of prize ball payout command transmission control processing according to the subroutine of step 3000 in FIG. First, at step 3100, the main control board M executes a payout control board transmission control process, which will be described later. Next, in step 3200, the main control board M executes a payout control board reception control process, which will be described later, and proceeds to the next process (process of step 2000).

Next, FIG. 13 shows a flowchart of the payout control board transmission control process according to the subroutine of step 3100 of FIG. First, at step 3105, the CPUMC of the main control board M determines whether or not the payout signal is OFF, that is, whether or not the payout is currently being executed. In the case of Yes in step 3105, in step 3110, the CPUMC of the main control board M determines whether or not there are undistributed prize balls (prize balls for which the prize ball disbursement command has not yet been transmitted to the prize ball disbursement 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 generates a prize ball payout-related error that is an error inappropriate for the prize ball payout (for example, an error related to a payout motor failure, an , out-of-ball error, etc.) has occurred. In the case of Yes in step 3115, in step 3120, the CPUMC of the main control board M issues a prize ball payout command for the number of prize balls to be paid out corresponding to the unpaid prize ball information in the order in which the current payout process is executed (see FIG. 14). ). Then, in step 3125, the CPUMC of the main control board M erases the undistributed prize ball information corresponding to the prize ball disbursement command set this time, and executes processing for shifting subsequent information. 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 process (the payout control board reception control process of step 3200). do. Note that even if No in steps 3105, 3110, and 3115, the process proceeds to the next process (process of step 3200).

<<Details of commands and information sent and received between the main control board and the payout control board>>
Here, with reference to FIG. 14, the contents of commands and information transmitted and received between the main control board M and the prize ball payout control board KH will be described. Here, the command from the main control board M according to this embodiment to the prize ball payout control board KH consists of specific information indicating that it is a prize ball payout command and information on the number of prize balls. Specifically, bits 7 to 4 are fixed at 1001 (identification information indicating that the command is a prize ball payout command). Next, bits 3 to 0 relate to the number of prize balls. For example, 0 (0000B) means 0 prize balls and 15 (1111A) means 15 prize balls. .

Next, the payout-related information transmitted from the prize ball payout control board KH to the main control board M side will be described. Here, as an example, the payout related information (prize ball payout related information or payout abnormality related information) includes a fixed value (start bit), payout motor operation error information, excessive payout error information, ball path error information, and payout motor error information. , prize ball device error information, tray full error, and prize ball payout completion information. Here, the details of each error will be described later. If the bit corresponding to each error is "0", it means that the error has not occurred. is occurring. Bit 0 relates to completion of prize ball payout, "0" means that prize ball payout is completed, and "1" means that prize ball payout is not completed.

Next, FIG. 15 shows a flow chart of the payout control board reception control process according to the subroutine of step 3200 of FIG. First, at step 3205, the CPUMC of the main control board M determines whether or not the payout-related information has been received. Here, in the case of Yes in step 3205, in step 3210, the CPUMC of the main control board M detects that error information (out-of-ball error, upper tray full error, other payout-related error) exists in the received payout-related information. Determine whether 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 error, and the error information on the prize ball payout control board KH side is transmitted to the main control board M side. But manage (unified management). At this time, the error information on the payout control board KH side may be configured to be transmitted from the main control board M to the sub control board S side. On the other hand, if No at step 3210, at step 3220, the CPUMC of the main control board M turns off the error flag associated with 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 received payout-related information includes prize ball payout completion information. If Yes at step 3225, at step 3230, the CPUMC of the main control board M clears the set prize ball payout command (the prize ball payout command associated with the completion of this payout), and proceeds to the next process (step 2000). process). Note that even if No in steps 3205 and 3225, the process proceeds to the next process (process of step 2000).

Next, FIG. 16 is a flow chart of the entering ball detection process according to the subroutine of step 2000 in FIG. First, at step 2100, the CPUMC of the main control board M executes an auxiliary game start entrance entrance detection process which will be described later. Next, at step 2200, the CPUMC of the main control board M executes a main game start entrance ball detection process which will be described later. Next, at step 2300, the ball entry determination means executes a first (second) big winning hole entry detection process, which will be described later. Next, at step 2400, the CPUMC of the main control board M executes a general winning hole entrance ball detection process, which will be described later. Next, at step 2500, the CPUMC of the main control board M executes a discharged ball detection process, which will be described later. Next, at step 2600, the CPUMC of the main control board M executes an out-hole entrance ball detection process, which will be described later. Next, at step 2700, the CPUMC of the main control board M executes prize ball determination processing, which will be described later, and proceeds to the next processing (processing of step 1100).

Next, FIG. 17 is a flow chart of auxiliary game start entrance ball detection processing according to the subroutine of step 2100 in FIG. First, in step 2102, the CPUMC of the main control board M determines whether or not the auxiliary game start 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 determines that the input from the auxiliary game start entrance detection device H11s is the entrance detection time (this time or more, the auxiliary game start entrance detection device H11s When detects the input, it is determined whether or not it is ON for the time when it is considered that there is a ball entering the auxiliary game start port H10. In the case of Yes in step 2104, in step 2106, the CPUMC of the main control board M turns on the auxiliary game start flag. Next, in step 2108, the CPUMC of the main control board M turns on the auxiliary game start opening detection continuation flag, and proceeds to the next process (process of step 2200).

On the other hand, in the case of No in step 2102, in step 2110, the CPUMC of the main control board M detects that the input from the auxiliary game start entrance detection device H11s is detected over the detection end time (this time or more, the auxiliary game start entrance detection device If H11s does not detect the input, it is determined whether or not the game ball is OFF for the time considered to have passed through the auxiliary game start entrance entrance ball detection device H11s. In the case of Yes in step 2110, in step 2112, the CPUMC of the main control board M turns off the auxiliary game start opening detection continuation flag, and proceeds to the next process (process of step 2200). Note that even if No in step 2104 or step 2110, the process proceeds to the next process (process of step 2200).

Next, FIG. 18 is a flow chart of the main game start entrance ball detection process according to the subroutine of step 2200 in FIG. First, at step 2202, the CPUMC of the main control board M determines whether or not the first main game start opening detection continuation flag is off. In the case of Yes in step 2202, in step 2204, the CPUMC of the main control board M determines that the input from the first main game start entrance detection device A11s is the entrance detection time (this time or more, the first main game start entrance When the ball detection device A11s detects an input, it is determined whether or not it is ON for the time considered to have entered the first main game start port A10. In the case of Yes at step 2204, at step 2206, the CPUMC of the main control board M turns on the first main game start flag. Next, at step 2210, the CPUMC of the main control board M turns on the first main game start opening detection continuation flag.

Next, in step 2211, the CPUMC of the main control board M adds (increments) 1 to the current first main game starting port entry ball count counter value, and proceeds to step 2216. It should be noted that even if No in step 2204 , the process proceeds to step 2216 .

On the other hand, if No in step 2202, in step 2212, the CPUMC of the main control board M detects that the input from the number-of-entered-ball counter MJ10c is longer than the detection time (this time or longer, the first main game start entrance entrance-enter detection device A11s is not detected, it is determined whether or not the game ball is OFF for more than the time considered to have passed through the first main game start entrance ball detection device A11s. Next, at step 2214, the CPUMC of the main control board M turns off the first main game start opening detection continuation flag. Next, at step 2215, the CPUMC of the main control board M turns off the first main game start opening long time detection flag, and proceeds to step 2216. It should be noted that even if No in step 2212 , the process proceeds to step 2216 .

Next, at step 2216, the CPUMC of the main control board M determines whether or not the first main game start opening confirmation sensor has detected a game ball. In the case of Yes in step 2216, in step 2218, the CPUMC of the main control board M adds (increments) 1 to the first main game start opening confirmation counter value, and proceeds to step 2222. In the case of No in step 2216, Also, the process moves to step 2222 .

Next, at step 2222, the CPUMC of the main control board M determines whether or not the second main game start opening detection continuation flag is OFF. In the case of Yes in step 2222, in step 2224, the second main game start entrance ball determination means determines that the input from the second main game start entrance ball detection device B11s When the game start opening detection device B11s detects an input, it is determined whether or not it is ON for the time considered to have entered the second main game start opening B10. In the case of Yes in step 2224, in step 2225, the CPUMC of the main control board M determines whether or not the flag during the second main game start opening valid period is ON. In the case of Yes at step 2225, at step 2226, the CPUMC of the main control board M turns on the second main game start flag. Next, at step 2230, the CPUMC of the main control board M turns on the second main game start opening detection continuation flag.

On the other hand, if No in step 2222, in step 2232, the CPUMC of the main control board M detects that the input from the second main game start entrance detection If the ball detection device B11s does not detect an input, it is determined whether or not the game ball is OFF for the time considered to have passed through the second main game start entrance ball detection device B11s. In the case of Yes at step 2232, at step 2234, the CPUMC of the main control board M turns off the second main game start opening detection continuation flag. Next, at step 2238, the CPUMC of the main control board M turns off the second main game start opening long time detection flag, and proceeds to step 2240. It should be noted that even if No in steps 2224 and 2232 , the process proceeds to step 2240 . Also, if No in step 2225 , in step 2231 , the CPUMC of the main control board M sets the second main game start port illegal ball entry command (command to the sub side), and proceeds to step 2240 .

Next, in step 2240, the CPUMC of the main control board M detects that the first main game start entrance ball detection device A11s (second main game start entrance ball detection device B11s) is detected as a normal ball entry during the fraud detection time. It is determined whether or not it has been ON for the time exceeding the time for which it is determined that fraudulent activity has occurred). In the case of Yes in step 2240, in step 2242, the CPUMC of the main control board M turns on the first (second) main game start opening long time detection flag, and proceeds to the next process (process of step 2300). On the other hand, also in the case of No in step 2240, the process proceeds to the next process (process of step 2300).

Next, FIG. 19 is a flow chart of the first (second) big winning hole entry ball detection process according to the subroutine of step 2300 in FIG. First, at step 2302, the CPUMC of the main control board M determines whether or not the first (second) big winning opening detection continuation flag is OFF. In the case of Yes in step 2302, in step 2304, the CPUMC of the main control board M determines that the input from the first large winning opening winning detection device C11s (second large winning opening winning detection device C21s) is detected for the ball entering detection time (this time As described above, when the ball-entering detection device detects an input, it is determined whether or not it is ON for a period of time during which it is assumed that a ball has entered the relevant ball-entering hole. In the case of Yes in step 2304, in step 2305, the CPUMC of the main control board M determines whether or not the flag during the first (second) big winning opening valid period is ON. In the case of Yes in step 2305, in step 2306, the CPUMC of the main control board M turns on the first (second) big winning hole entry ball flag. Next, at step 2308, the CPUMC of the main control board M adds 1 to the number-of-balls counter value. Next, at step 2310, the CPUMC of the main control board M turns on the first (second) big winning opening detection continuation flag, and proceeds to step 2320.

On the other hand, in the case of No in step 2305 (when the entry of the game ball into the big winning opening is detected during the period when the entering of the game ball is not valid), in step 2311, the CPUMC of the main control board M detects that the big winning opening is illegal. Then, the first (second) big winning hole illegal ball entry command (command to the sub control board S side) is set, and the process proceeds to step 2320 . It should be noted that even if No in step 2304 , the process proceeds to step 2320 .

On the other hand, in the case of No in step 2302, in step 2312, the CPUMC of the main control board M detects the input from the first large winning opening winning detection device C11s (the second large winning opening winning detection device C21s) for the detection time {this time As described above, when the first large winning opening winning detection device C11s (second large winning opening winning detection device C21s) does not detect the input, the game ball detects the first large winning opening winning detection device C11s (second large winning opening winning detection device C11s). It is determined whether or not it has been OFF for the time considered to have completed passing through the detection device C21s). In the case of Yes at step 2312, at step 2314, the CPUMC of the main control board M turns off the first (second) big winning opening detection continuation flag. Next, in step 2318, the CPUMC of the main control board M turns off the first (second) big winning opening long time detection flag, and proceeds to step 2320.

Next, in step 2320, the CPUMC of the main control board M determines that the input from the first large winning opening winning detection device C11s (the second large winning opening winning detection device C21s) When the winning opening detection device C11s (the second big winning opening detection device C21s) detects an input, the time when it is assumed that the illegal entry into the first big winning opening C10 (the second big winning opening C20) is detected. } It is determined whether or not it is ON. In the case of Yes in step 2320, in step 2322, the CPUMC of the main control board M turns on the first (second) big winning opening long time detection flag, and proceeds to the next process (process of step 2400). On the other hand, also in the case of No in step 2320, the process proceeds to the next process (process of step 2400).

Next, FIG. 20 is a flow chart of the general winning hole entrance ball detection process according to the subroutine of step 2400 in FIG. In addition, the general winning opening (the left general winning opening and the right general winning opening may be collectively referred to as the general winning opening) pays out prize balls when the game ball enters, but the game progresses. (does not execute a lottery that affects the progress of the game) and is a sensor that detects the entry of a game ball. There are two types: a general winning hole ball detection device which is a sensor for detecting the entry of a game ball into the mouth, and a general winning hole ball detection device which is a sensor for detecting the entry of a game ball into the right general winning hole. It has a general winning entrance ball detection device).

First, at step 2402, the CPUMC of the main control board M determines whether or not the general winning hole detection continuation flag is off. In the case of Yes in step 2402, in step 2404, the CPUMC of the main control board M detects that the input from the general winning entrance ball detection device is the ball entrance detection time (this time or longer, the general winning entrance ball detection device detects the input). Then, it is determined whether or not the switch is ON for a period of time during which it is assumed that a ball has entered the general winning hole. In the case of Yes at step 2404, at step 2406, the CPUMC of the main control board M turns on the general winning hole entry ball flag. Next, at step 2410, the CPUMC of the main control board M turns on the general winning hole detection continuation flag. On the other hand, in the case of No in step 2402, in step 2412, the CPUMC of the main control board M detects that the input from the general winning entrance detection device is the detection time of the entry (this time or more, the input from the general winning entrance detection device is not detected, it is determined whether or not the game ball is OFF for the time considered to have passed through the general winning entrance ball detection device. If Yes at step 2412, at step 2414, the CPUMC of the main control board M turns off the general winning hole detection continuation flag. Next, at step 2418, the CPUMC of the main control board M turns off the general winning opening long time detection flag, and proceeds to step 2420. It should be noted that even if No in steps 2404 and 2412 , the process proceeds to step 2420 .

Next, in step 2420, the CPUMC of the main control board M determines that the input from the general winning entrance ball detection device is the fraud detection time {if the general winning entrance ball detection device detects the input for this time or more, the general winning A determination is made as to whether or not the switch is ON for a period of time for which it is assumed that an illegal ball into the mouth has been detected. In the case of Yes at step 2420, at step 2422, the CPUMC of the main control board M turns on the general winning opening long time detection flag, and proceeds to the next process (process at step 2500). Note that even if No in step 2420, the process proceeds to the next process (process of step 2500).

Next, FIG. 21 is a flow chart of the discharged ball detection process according to the subroutine of step 2500 in FIG. First, at step 2502, the CPUMC of the main control board M determines whether or not the discharge confirmation detection continuation flag is off. In the case of Yes in step 2502, in step 2504, the CPUMC of the main control board M detects that the input from the total discharge confirmation sensor is the ball entry detection time (when the total discharge confirmation sensor detects the input for this time or more, the total discharge confirmation sensor A determination is made as to whether or not the switch is ON for a period of time during which it is assumed that a ball has been entered. If Yes at step 2504, at step 2506, the CPUMC of the main control board M turns on the ejection 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 2600).

On the other hand, if No in step 2502, in step 2510, the CPUMC of the main control board M detects the input from the total discharge confirmation sensor for the detection end time (if the total discharge confirmation sensor does not detect the input for this time or longer, It is determined whether or not the game ball is OFF for the time considered to have passed the total discharge confirmation sensor. If Yes at step 2510, at step 2512, the CPUMC 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 proceeds to the next process (process of step 2600). It should be noted that even if No in step 2504 or step 2510, the process proceeds to the next process (process of step 2600).

Next, FIG. 22 is a flow chart of the out-going ball detection process according to the subroutine of step 2600 in FIG. First, at step 2602, the CPUMC of the main control board M determines whether or not the outlet detection continuation flag is off. In the case of Yes in step 2602, in step 2604, the CPUMC of the main control board M detects that the input from the out entrance ball detection device is the entrance detection time A determination is made as to whether or not the ball has been ON for a period of time during which it is assumed that the ball has entered the mouth D36. If Yes at step 2604, at step 2606, the CPUMC of the main control board M turns on the outlet detection continuation flag. transition to

On the other hand, in the case of No in step 2602, in step 2610, the CPUMC of the main control board M determines that the input from the out entrance ball detection device has not detected the input for the detection end time (this time or more). If not, it is determined whether or not the game ball has been OFF for a period of time deemed to have passed through the out entrance ball detection device. If Yes at step 2610, at step 2612, the CPUMC of the main control board M turns off the outlet detection continuation flag. Next, at 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 step 2604 or step 2610 is No, the process also proceeds to step 2620 .

Next, in step 2620, the CPUMC of the main control board M determines that the input from the out-door entrance ball detection device is the illegal detection time (if the out-door entrance ball detection device detects It is determined whether or not it is ON for a period of time during which it is considered that an illegal ball is being entered into the mouth D36. In the case of Yes at step 2620, at step 2622, the CPUMC of the main control board M turns on the outlet long time detection flag, and proceeds to the next process (process of step 2700). On the other hand, also in the case of No in step 2620, the process proceeds to the next process (process of step 2700).

Next, FIG. 23 is a flow chart of the number of prize balls determination process according to the subroutine of step 2700 in FIG. First, at step 2702, the CPUMC of the main control board M determines whether or not the first main game start flag is ON. If Yes at step 2702, at step 2704, the CPUMC of the main control board M adds the number of prize balls paid out related to the first main game start port A10 (3 in this example) to the counter value of the number of prize balls counter. do. Next, in step 2708, the CPUMC of the main control board M temporarily stores information (for example, information on the number of prize balls to be paid out) to the effect that the prize balls are to be paid out from the first main game start port A10, and step 2712. transition to On the other hand, if No in step 2702, the process proceeds to step 2712 as well.

Next, at step 2712, the CPUMC of the main control board M determines whether or not the second main game start flag is ON. If Yes at step 2712, at step 2714, the CPUMC of the main control board M adds the number of prize balls paid out related to the second main game start port B10 (3 in this example) to the counter value of the number of prize balls counter. do. Next, in step 2718, the CPUMC of the main control board M temporarily stores information (for example, information on the number of prize balls to be paid out) to the effect that the prize balls are to be paid out from the second main game start port B10, and step 2722. transition to On the other hand, if No in step 2712, the process proceeds to step 2722 as well.

Next, at step 2722, the CPUMC of the main control board M determines whether or not the first (second) big winning hole entry flag is ON. In the case of Yes at step 2722, at step 2723, the CPUMC of the main control board M turns off the first (second) big winning hole entering ball flag. Next, in step 2724, the CPUMC of the main control board M sets the counter value of the prize ball counter to the number of prize balls paid out (13 in this example) associated with the first big prize hole C10 (second big prize hole C20). is added. Next, in step 2728, the CPUMC of the main control board M provides information to the effect that the prize balls related to the first big winning hole C10 (second big winning hole C20) will be paid out (for example, information related to the number of paid out prize balls). is temporarily stored, and the process proceeds to step 2732 . On the other hand, if No in step 2722, the process proceeds to step 2732 as well.

Next, at step 2732, the CPUMC of the main control board M determines whether or not the general winning hole entry flag is ON. In the case of Yes at step 2732, at step 2733, the CPUMC of the main control board M turns off the general winning hole entry ball flag. Next, at step 2734, the CPUMC of the main control board M adds the number of prize balls paid out (10 in this example) to the counter value of the prize ball counter. Next, at step 2738, the CPUMC of the main control board M temporarily stores information (for example, information on the number of prize balls to be paid out) to the effect that prize balls are to be paid out for the general winning hole, and the next process (step 1100) is performed. process). On the other hand, also in the case of No in step 2732, the process proceeds to the next process (process of step 1100).

Next, FIG. 24 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 (flowed in, or passed through in the case of a gate) the auxiliary game starting port H10. In the case of Yes in step 1102, in step 1103, the CPUMC of the main control board M transmits the auxiliary game start opening ball entry command, which is a command related to entering the auxiliary game start opening H10, to the sub-main control unit SM. command transmission buffer (transmitted to the sub-main control unit SM side by the control command transmission processing of step 1999), and the process proceeds to step 1110. FIG. On the other hand, if No at step 1102, at step 1104, the CPUMC of the main control board M determines whether or not the ball has entered the right general winning hole. In the case of Yes at step 1104, at step 1106, the CPUMC of the main control board M determines whether or not the special game execution flag is ON. In the case of Yes at step 1106, at step 1108, the CPUMC of the main control board M sends a right general winning hole entry command, which is a command relating to the fact that the ball has entered the right general winning hole, to the sub-main control unit SM. It is set in the command transmission buffer (transmitted to the sub-main control unit SM side by the control command transmission processing of step 1999), and the process proceeds to step 1110. FIG. It should be noted that even if the result of step 1106 is No, the process proceeds to step 1110 . Next, at step 1110, the CPUMC of the main control board M determines whether or not the number of retained balls is the upper limit (for example, 4). In the case of Yes at step 1110, at step 1112, the CPUMC 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 CPUMC of the main control board M adds 1 to the retained ball by setting it in the RAM area of the main control board M together with the information indicating what number the ball is retained. processing of step 1200). Note that even if No in steps 1104 and 1110, the process proceeds to the next process (process of step 1200). Here, in the present embodiment, it is configured to be able to acquire a random number on the auxiliary game side when the ball enters the auxiliary game starting opening H10 or the right general winning opening. In addition, 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 to flow down the game board surface and the auxiliary game starts. While the ball can enter the ball entrance (right general winning opening, etc.) downstream from the opening H10, the game ball entering the right general winning opening flows down to the back of the game board surface, and after that, other balls enter. It is configured so that the ball does not enter the mouth. In addition, although the details will be described later, even if a game ball enters the auxiliary game start opening H10 (a game ball passes through the auxiliary game start opening H10), there is no prize ball payout, but the right general winning opening It is configured such that prize balls are paid out when a game ball enters.

Next, FIG. 25 is a flowchart of the electric accessary product drive determination process according to the subroutine of step 1200 in FIG. First, at step 1202, the CPUMC of the main control board M determines whether or not the electric accessory open flag is off. In the case of Yes in step 1202, in step 1204, the CPUMC of the main control board M determines whether or not the auxiliary game symbol fluctuating flag is off. In the case of Yes at step 1204, at step 1206, the CPUMC of the main control board M determines whether or not there is a reserved ball related to the auxiliary game symbol. In the case of Yes in step 1206, in step 1216, the CPUMC of the main control board M acquires the auxiliary game side game state (flag state of the auxiliary game time saving flag), and refers to the auxiliary game symbol determination lottery table, Determine the stop symbol based on the obtained auxiliary game side game state and the auxiliary game symbol winning random number based on the reserved ball (for example, when the auxiliary game time saving flag is on, it is higher than when it is off) Winning symbols are selected with probability) and 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 lottery table for determining the auxiliary game stop symbol. As shown in the table, in this example, there are "D0, D1, D2" as the stopped symbols, and "D1, D2" as the winning symbols. The opening mode of the electric accessary to be opened at the time of the non-time reduction game is (open for 0.2 seconds→closed) when the stopped symbol is "D1". When the pattern is "D2", the opening mode is (open for 0.2 seconds→close for 0.8 seconds→open, close for 2.0 seconds) (maximum open). Further, in the time shortening game, when the stopped symbol is "D1", the opening mode is (open for 1 second→close for 1 second→open for 1 second→close for 1 second→open for 1 second→close), and stop. When the drawn pattern is "D2", the opening mode is configured to be (open for 0.2 seconds→close for 0.8 seconds→open for 4.0 seconds→close). Incidentally, the stop pattern is likely to be a losing symbol "D0" during the non-time shortening game, and the stop symbol is likely to be a winning symbol "D1" during the time shortening game.

Next, in step 1218, the CPUMC of the main control board M sets the timer for auxiliary game design variation management based on the game state of the auxiliary game side (the flag state of the auxiliary game time reduction flag) to the predetermined time related to the auxiliary game design fluctuation time. Time (for example, 1 second when the auxiliary game time saving flag is on, 10 seconds when the auxiliary game time saving flag is off) is set. Then, at step 1220, the CPUMC of the main control board M turns on the auxiliary game symbol fluctuating 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 pattern, After starting the game symbol variation management timer, the auxiliary game symbol variation display is started on the auxiliary game symbol display section H21g.

Next, in step 1224, the CPUMC of the main control board M refers to the auxiliary game symbol variation management timer to determine whether or not the predetermined time related to the auxiliary game symbol variation time has been reached. In the case of Yes in step 1224, in step 1226, the CPUMC of the main control board M acquires the stop symbols of the auxiliary game symbols and confirms and displays the acquired stop symbols of the auxiliary game symbols on the auxiliary game symbol display section H21g. do. Then, at step 1228, the CPUMC of the main control board M turns off the auxiliary game symbol fluctuating flag. Next, at step 1230, the CPUMC of the main control board M determines whether or not the stop symbol of the auxiliary game symbol is "hit" (D1 and D2 in this example). In the case of Yes in step 1230, in step 1232, the CPUMC of the main control board M is based on the winning pattern on the auxiliary game side. → Open for 1 second → Close for 1 second → Open for 1 second → Closed. is set, and a predetermined time related to the opening time (opening/closing time) of the electric accessory is set in the second main game start opening electric accessory opening timer. Next, at step 1234, the CPUMC of the main control board M turns on the electric accessory open flag. Then, in step 1236, the CPUMC of the main control board M opens the second main game starter electric accessory B11d of the second main game starter B10, and proceeds to step 1242. It should be noted that even if No in step 1202 , the process proceeds to step 1242 . In this embodiment, when the main game time saving flag is off and the auxiliary game stop symbol is a predetermined winning symbol (D2), the second main game start opening electric accessory B11d is kept open for the longest time. It is

Next, in step 1242, the CPUMC of the main control board M refers to the second main game start opening electric accessory opening timer, and determines whether or not the predetermined time related to the opening time of the electric accessory has reached. . In the case of Yes in step 1242, in steps 1244 and 1246, the CPUMC of the main control board M closes the second main game starter electric accessory B11d, turns off the electric accessory open flag, and proceeds to the next process. (Processing of step 1300).

If No at step 1204, the process proceeds to step 1224. If No at steps 1206, 1224, 1230, and 1242, the process proceeds to the next process (process of step 1300).

Further, in this flowchart, for the sake of convenience, the process proceeds to the next step immediately after displaying the stop symbol in step 1226, 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 fixing time of about 500 ms (for example, this process may be performed by branching using the stop display fixing flag and 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 pattern, auxiliary game symbol Auxiliary game symbol variation mode random numbers or the like for determining the variation time may be provided.

In addition, although not shown, in one opening operation of the second main game start opening electric accessory B11d (opening operation based on the stop of the symbol per auxiliary game once), the game is opened at the second main game start opening B10. Even when a predetermined number of balls (for example, 10 balls) are entered, the opening operation of the second main game starter electric accessory B11d is ended, that is, the time reduction game state (auxiliary game time reduction flag ON ), when the opening (longest opening) of the second main game starter electric accessory B11d based on the auxiliary game stop symbol “D2” is executed, “open for 0.2 seconds → close for 0.8 seconds → When the opening time of "open for 4 seconds → closed" ends, or the predetermined number of game balls (for example, 10 balls) are released from the second main game start opening B10 during the opening period of the second main game start opening electric accessory B11d. The opening (opening period) of the second main game starter electric accessory B11d is completed by the achievement of whichever is earlier when the ball is entered. Also, in the case of the non-time reduction game state (auxiliary game time reduction flag off), when the opening (longest opening) of the second main game start opening electric accessory B11d based on the auxiliary game stop symbol "D2" is executed, " Open for 0.2 seconds → Close for 0.8 seconds → Open for 2.0 seconds → Closed", or the predetermined number (for example, 10) game balls enter the second main game starter B10, whichever comes first, the opening (opening period) of the second main game starter electric accessory B11d ends. ing. In addition, the total time during which the normal electric accessories are open at the maximum opening time (when the auxiliary game stop symbol is "D2") in the time shortening game state (auxiliary game time reduction flag on) is 4.2 seconds, non- The total time that the normal electric accessories are open at the maximum open time (when the auxiliary game stop pattern is "D2") in the time shortening game state (auxiliary game time reduction flag off) is 2.2 seconds, any game Even in the state, it is configured not to exceed 6 seconds throughout the maximum opening time of one time, and in each game state (time shortening game state) so that the maximum number of winnings during operation does not exceed about 10 or non-time reduction game state).

In addition, in this example, when the normal symbol (auxiliary game symbol) which is the trigger for the operation of the normal electric accessory (second main game starter electric accessory B11d) is confirmed and displayed in the winning mode, immediately (for example, (within 500 ms, which is shorter than the shortest pattern variation time in the game machine), and it is clearly associated with which trigger the normal electric accessory is operating. In addition, in order to prevent a large number of game balls from winning during the closing operation (during the operation of opening → closing) of the normal electric role (second main game start opening electric role B11d), the normal electric role The drive source (solenoid) is selected so that the object (second main game starter electric accessory B11d) returns to the non-operating state in a short time, and more game balls than necessary are won and the ball is released. It is designed so that it does not differ greatly from the design.

Next, FIG. 26 is a flow chart of main game content determination random number acquisition processing according to the subroutine of step 1300 in FIG. First, in step 1302, the CPUMC of the main control board M determines whether or not the first main game start entrance ball information has been received from the first main game start entrance ball detection device A11s of the first main game start entrance A10. judge. In the case of Yes in step 1302, in step 1303, the CPUMC of the main control board M sends the first main game starting port entry command, which is a command related to entering the first main game starting port A10, to the sub-main control unit SM. (transmitted to the sub-main control unit SM side by the control command transmission processing in step 1999), and the process proceeds to step 1304. Next, in step 1304, the CPUMC of the main control board M determines whether or not the number of reserved balls related to the main game (especially the first main game side) is within the upper limit (for example, 4). In the case of Yes at step 1304, at step 1306, the CPUMC of the main control board M acquires the first main game content determination random number. In this embodiment, as the first main game content determination random number, the winning lottery random number for determining winning or losing, the symbol lottery random number for determining the symbol at the time of winning, and the variation pattern (variation time) of the special symbol are determined. Three random numbers of the variation mode lottery random number for doing are acquired. Incidentally, these three random numbers are generated by random number generation means with different update cycles and random number ranges, and are obtained in succession at this timing. Next, at step 1308, the CPUMC of the main control board M temporarily stores (holds) the acquired random number in the RAM area of the main control board M. FIG. Next, at step 1310, the CPUMC of the main control board M sets the information indicating that the first main game random number has been acquired (hold generation command) 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 in step 1999).

The lottery random number may be composed of one random number, or may be a random number generated from two or more random numbers. As random numbers generated from two or more random numbers, a CPU built-in random number updated based on a CPU clock or an external clock and a soft random number per special symbol (main game symbol) updated by timer interrupt processing are provided. may be used.

Next, in step 1312, the CPUMC of the main control board M has received the second main game start entrance ball information from the second main game start entrance ball detection device B11s of the second main game start entrance B10. judge. In the case of Yes in step 1312, in step 1314, the CPUMC of the main control board M determines whether or not the number of reserved balls related to the main game (especially the second main game side) is within the upper limit (eg 4). In the case of Yes at step 1314, at step 1316, the CPUMC of the main control board M acquires the second main game content determination random number. In this embodiment, three random numbers are acquired as the second main game content determination random numbers, the win/fail lottery random number, the symbol lottery random number, and the variation mode lottery random number, as in the case of the first main game side. Incidentally, the acquisition range of each random number on the first main game side and the acquisition range of each random number on the second main game side (for example, the acquisition range of the winning lottery random number for the first main game and the winning lottery random number for the second main game) are set to the same. Next, at step 1318, the CPUMC of the main control board M temporarily stores (holds) the acquired random number in the RAM area. Next, at step 1320, the CPUMC of the main control board M sets the information indicating that the second main game random number has been obtained (hold generation command) in the command transmission buffer for transmitting to the sub-main control unit SM. (Sent 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). If No in steps 1302 and 1304, the process proceeds to step 1312. If No in steps 1312 and 1314, the next process (process of step 1400) is performed.

Next, FIG. 27 is a flow chart of the main game symbol display process according to the subroutine of step 1400 in FIG. First, in step 1401, the CPUMC of the main control board M refers to the RAM area of the main control board M, and confirms whether or not there is a hold of the second main game symbol. In the case of Yes in step 1401, in step 1400 (1), the CPUMC of the main control board M executes the first main game symbol display processing described later, and the next processing {processing of steps 1400 (1) and (2) }. On the other hand, in the case of No at step 1401, at step 1400 (2), the CPUMC of the main control board M executes the second main game symbol display process described later, and the next process {steps 1400 (1), (2) processing}.

Thus, in this embodiment, when there is a reserved ball of the second main game pattern, regardless of the presence of a reserved ball of the first main game pattern (even if the winning order is the reserved ball of the first main game pattern) Although it is configured to preferentially execute the pending digestion of the second main game symbol, it is not limited to this (pending digestion based on the winning order, and simultaneous parallel execution of both main game symbols It may be configured to execute a parallel lottery that randomly draws lots).

Next, FIG. 28 is a flow chart of the first main game symbol display process (second main game symbol display process) relating to the subroutine of step 1400 (1) {step 1400 (2)} in FIG. Since this process is substantially the same for 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. Use parentheses. First, at 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 that the special game is not in progress (or the condition device is in operation), the main game symbols are not fluctuating, the main game symbols are on hold, and the small winning game is not in progress. is a condition. Although not shown in this example, if a variable fixed time (time to stop and display the finalized display pattern after the main game pattern is confirmed) is provided, during the variable fixed time, the next fluctuation start condition may be configured so as not to satisfy

If Yes at step 1403, at steps 1405 and 1406, the CPUMC of the main control board M temporarily stores the first main game content determination random number ( Second main game content determination random number) is read out, deleted from the RAM area of the main control board M, and the remaining temporarily stored hold information is shifted (hold digest processing). Next, in step 1410-1, the CPUMC of the main control board M refers to the main game table 1 corresponding to each game state, and determines the first main game content determination random number (second main game content determination random number) (particularly, A winning lottery random number) is used to execute a lottery for the main game symbols.

Here, FIG. 29 (main game table 1) is an example of the first main game winning/failure lottery table (second main game winning/failure lottery table).

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 Based on the main game content determination random number (second main game content determination random number) (particularly, the symbol lottery random number), the stop symbols relating to the main game symbols are determined and temporarily stored in the RAM area.

Here, FIG. 29 (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 this embodiment, when a big hit is won, a plurality of main game symbol candidates (in this example, "4A (for example, abcd is lit), 5A (for example, abcde is lit), 7A (for example, abcdefg is lit)” and “4B (for example, klmn is lit), 5B (for example, klmno is lit), 7B (for example, klmnopq is lit)”). is configured to be determined as The number of rounds of the special game determined with reference to the main game symbols is 8R for 4A, 4B, 5A and 5B, and 10R for 7A and 7B. In addition, the types of random numbers and stop symbols are only examples and are not limited to these {for example, the lost symbols are not limited to one type of symbol, and may be configured to provide multiple types of symbols. may}.

Next, in step 1410-2, after determining the stop symbols related to the main game symbols, in step 1410-3, the CPUMC of the main control board M determines the main game symbols based on the main game side random number, the result of the lottery, and the game state. is determined (or variation time), and the process proceeds to step 1414 .

Here, the main game table 3 shown in FIG. 29 is an example of a lottery table for determining the first main game variation mode (lottery table for determining the second main game variation mode). As shown in this figure, in the present embodiment, it is configured such that the variation mode (variation time) of the main game symbols with respect to a certain random number value can be determined based on the win/loss lottery result of the main game symbols and the state of the main game time saving flag. It is For example, with respect to a certain random number, if the result of the lottery of the main game pattern is a hit, it is easy to determine a variation mode in which the variation time is relatively long, and if the main game time reduction flag is on (time reduction In the case of a game state), it is configured such that a variation mode in which the variation time is relatively short is easily determined. This example is merely an example, and the type of variation mode (variation time), selectivity, and the like are not limited in any way. Also, it may be configured so that the symbol variation time on the first main game side in the time shortening game state (when the main game time shortening flag is ON) is relatively long {symbol variation on the second main game side is configured to be advantageous to the player, the pattern fluctuation efficiency of the first main game side is reduced, and the second main game side is likely to be suspended (which is advantageous to the player). (because it is intended to construct a situation, it is particularly effective when the first main game side start opening and the second main game side start opening cannot be separated).

Next, in step 1414, the CPUMC of the main control board M issues a command (stop symbol information, attribute information of the stop symbol, variation mode information, etc.) related to the main game symbol temporarily stored in the RAM area of the main control board M, and A command related to the current gaming state (symbol variation display start instruction command) is set in the command transmission buffer for transmission to the sub-main control unit SM side (by the control command transmission processing in step 1999, sent). Next, at step 1415, the CPUMC of the main control board M sets the first and second main game symbol variation management timers to a predetermined time period related to the variation time of the main game symbols. Next, at step 1416, the CPUMC of the main control board M displays 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), according to the variation mode stored in the RAM area of the main control board M, the variation display of the main game symbols is started. Next, at step 1418 , the CPUMC of the main control board M turns on the fluctuating flag, and proceeds to step 1420 .

On the other hand, if No at step 1403, at step 1419, the CPUMC of the main control board M determines whether or not the fluctuating flag is on. If Yes in step 1419, the process proceeds to step 1420. If No in step 1419, the process proceeds to the next process (process of step 1700).

Next, at step 1420, the CPUMC of the main control board M determines whether or not the predetermined time relating to the variation time of the main game symbols has been reached. In the case of Yes at step 1420, at step 1422, the CPUMC of the main control board M sends information to the effect that the pattern variation will end (symbol confirmation display instruction command) for command transmission to the sub-main control unit SM side. It is set in the buffer (transmitted to the sub-main control unit SM side by the control command transmission processing in step 1999). Next, at step 1423, the CPUMC of the main control board M displays 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) The variable display of the main game symbols on the screen is stopped, and the stop symbols stored in the RAM area of the main control board M are controlled to be displayed as fixed stop symbols. Next, at step 1424, the CPUMC of the main control board M turns off the fluctuating flag.

Next, at step 1430, the CPUMC of the main control board M refers to the RAM area of the main control board M, and determines whether or not the stop symbol of the main game symbol is a jackpot symbol. If Yes at step 1430 , at step 1432 , the CPUMC of the main control board M turns on the condition device operation flag, and proceeds to step 1500 . On the other hand, if the stopped symbol is not a big hit symbol at step 1430, at step 1434, the CPUMC of the main control board M determines whether or not the stopped symbol is a small winning symbol. In the case of Yes at step 1434 , at step 1436 , the CPUMC of the main control board M turns on the small hit flag and proceeds to step 1500 . On the other hand, if step 1434 is No, the process proceeds to step 1500 as well.

Next, at step 1500, the CPUMC of the main control board M executes specific game end determination processing, which will be described later, and proceeds to the next processing (processing of step 1700). Note that even if No in step 1420, the process proceeds to the next process (process of step 1700).

Next, FIG. 29 (main game table 1 and main game table 2) is an example of the first main game win/loss lottery table (second main game win/loss lottery table) in this embodiment. In this embodiment, regardless of the game state, the contents of the table to be referred to differ only depending on whether the symbol variation is related to the first main game side or the symbol variation related to the second main game side. . In addition, it is configured so that a small win can be won on both the first main game side and the second main game side, and the win/loss lottery result on the second main game side is almost a small win. It should be noted that the winning probability is merely an example, and is not limited to this at all. Further, when a small win is won, one main game symbol is determined as a small winning symbol from among one type of main game symbol candidates for the first main game side and two types of main game symbol candidates for the second main game side. ing. In addition, the types of random numbers and stop symbols are only examples and are not limited to these {for example, the lost symbols are not limited to one type of symbol, and may be configured to provide multiple types of symbols. Alternatively, when a specific symbol is stopped and displayed, the type of variation and/or selection rate of the main game pattern is different from before the specific symbol is stopped and displayed (limited frequency state). may be configured to migrate}.

Next, FIG. 30 is a flow chart of small-hit game control processing according to the subroutine of step 1700 in FIG. 10 in this embodiment. First, in step 1701, the CPUMC of the main control board M is a discharge standby flag {a flag that is turned on in step 1722 to be described later, that is, a scheduled small winning game (especially, a scheduled second After the execution of the opening pattern of the winning opening C20) is completed, the flag that is turned on during the discharge waiting period (discharge waiting time) of the game balls remaining in the second big winning opening C20 is turned off. judge. In the case of Yes in step 1701, in step 1702, the CPUMC of the main control board M determines whether or not the small hit flag is ON. In the case of Yes in step 1702, in step 1704, the CPUMC of the main control board M turns off the small hit flag. Next, at step 1705, the CPUMC of the main control board M determines the opening pattern of the second big winning opening C20 of the round (in this example, for example, in all small winning symbols, "0.2 seconds open→0. Closed for 8 seconds → Open for 1 second → Closed for 1 second → Open for 1 second → Closed", and if the game ball continues to be shot toward the second big winning hole C20, the game ball enters the second big winning hole C20. configured to enter multiple balls). The opening mode of the big winning hole (second big winning hole C20) during execution of the small win can be arbitrarily set. may be configured to be a predetermined time or less (for example, 1.8 seconds or less) (for example, "open for 0.2 seconds → close for 0.8 seconds → open for 1 second → close" (total open time = 1 .2 seconds)). Next, at 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 winning execution start command (a command to the effect that a small winning game has started), and directs the player to shoot a game ball toward the second big winning opening C20. ) is set in the command transmission buffer for transmission to the sub-main control unit SM (transmitted to the sub-main control unit SM by the control command transmission processing in step 1999). Next, in step 1708, the CPUMC of the main control board M opens the second big winning hole C20 and starts a small-hit game timer (the timer value is counted down). Next, at step 1709, the CPUMC of the main control board M starts a discharge standby timer (increment timer), and proceeds to step 1712. In addition, here, the discharge standby timer measures the elapsed time from the start of the small winning game, so that the discharge standby time ends after a predetermined time (10 seconds in this example) has elapsed from the start of the small winning. {Of course, the method of measuring the discharge waiting time is not limited to this. Measurement may be started from }.

On the other hand, in the case of No in step 1702, in step 1710, the CPUMC of the main control board M determines whether or not the small hit execution flag is ON. If Yes in step 1710 , go to step 1712 .

Next, at step 1712, the CPUMC of the main control board M determines whether or not a game ball has won a prize (entered a ball) in the second big prize winning opening C20. In the case of Yes at step 1712, at step 1714, the CPUMC of the main control board M determines whether or not there are a predetermined number (for example, 10) of winning balls in the second big winning hole C20. If Yes in step 1714 , go to step 1718 . On the other hand, in the case of No in step 1712 or step 1714, in step 1716, the CPUMC of the main control board M refers to the timer for the small winning game, and a predetermined time (for example, 4 seconds) relating to the opening of the big winning opening has passed. Determine whether or not If Yes at step 1716 , go to step 1718 .

Next, at step 1718, the CPUMC of the main control board M stops the driving of the second big winning opening electric accessory C21d to close the second big winning opening C20. Next, at step 1722, the CPUMC of the main control board M turns on the discharge standby flag (the discharge standby time starts from the execution timing of this process), and the process proceeds to step 1724. It should be noted that even if No in step 1701 , the process proceeds to step 1724 .

Next, at step 1724, the CPUMC of the main control board M determines whether or not the timer value has reached the discharge waiting time end value (10 seconds in this example). If Yes at step 1724, at step 1725, the CPUMC of the main control board M clears the discharge standby timer to zero. Next, at step 1726, the CPUMC of the main control board M turns off the discharge standby flag. Next, at step 1728, the CPUMC of the main control board M stops and resets the timer for the small hit game. Next, at step 1730, the CPUMC of the main control board M turns off the small hit execution flag, and proceeds to the next process {process of step 1750}. Incidentally, even if No in step 1710, step 1716 or step 1724, the process proceeds to the next process {process of step 1750}.

Here, in this example, the maximum number of winning prizes set as a program for one small win is 10, and the maximum opening time of the big winning hole for one small win is 1.8 seconds or less. .2 seconds (more specifically, a series of opening and closing of "0.2 seconds open → 0.8 seconds closed → 1 second open → closed" as the opening mode of the big winning opening when executing one small win operation), and is controlled to close the big winning opening when any of the closing conditions is achieved. Here, in order to suppress excessive prize winning and minimize the divergence from the design value of paid balls, it is desirable to perform control so as to close immediately after the closing conditions are met. On the other hand, even if such processing is performed, the ball enters the big prize hole immediately after the closing condition is met, or the winning ball stays in front of the count sensor (the winning ball is detected by the count sensor after the closing condition is met). to do) is also considered. Therefore, in either case after the maximum opening time has passed or after the maximum number of winnings has been exceeded, the winning is processed as a valid winning only under predetermined conditions (within a predetermined period after closing). It is desirable to

Next, FIG. 31 is a flow chart of the upper shielding member drive control process related to the subroutine of step 1750 in FIG. 10 in this embodiment. First, at step 1752, the CPUMC of the main control board M determines whether or not the small hit execution flag is ON. In the case of Yes in step 1752, in step 1754, the CPUMC of the main control board M controls the upper shielding member in a predetermined driving pattern (in this example, a pattern that repeats "closed for 5 seconds→opened for 1 second→closed for 24 seconds"). C24 is started to be driven, and the next process (process of step 1800) is performed. There is no problem even if the driving pattern of the upper shielding member C24 is changed. Since it is configured so that a ball can be entered into the opening C22, it is not possible to enter the V winning opening C22 by setting the opening time to a long time such as 3 seconds or not opening for more than 10 seconds from the start of driving. Not recommended. On the other hand, if No at step 1752, at step 1756, the CPUMC of the main control board M closes the upper shielding member C24 (initial position) to end the driving, and proceeds to the next process {process of step 3450}. Transition. Thus, in the second embodiment, the upper shielding member C24 starts driving with the start of the small winning game (the opening of the second big winning opening C20 related to the small winning) as a trigger, and ends the small winning game. It is configured to end the driving as a trigger, and the small winning game is completed before the upper shielding member C24 is driven once in the open pattern, and the driving of the upper shielding member C24 is completed. there is In addition, since the small winning game is provided with a discharge waiting time, the small winning game does not end until the discharge waiting time ends even after the opening of the second big winning opening C20 related to the small winning game is completed. It will happen.

Next, FIG. 32 is a flow chart of the lower shielding member drive control process according to the subroutine of step 3450 in FIG. 10 in this embodiment. First, in step 3452, the CPUMC of the main control board M drives the lower shielding member C25 in a constant driving pattern (in this example, a pattern that repeats "closed for 3 seconds → open for 1 second") after the power is turned on. , the process proceeds to the next process {process of step 1950}. Thus, the upper shielding member C24 is configured to start driving when the small winning game is started, while the lower shielding member C25 is configured to start driving when the gaming machine is turned on.

Next, FIG. 33 is a flow chart of the V winning hole entry ball determination process according to the subroutine of step 1950 in FIG. 10 in this embodiment. First, at step 1952, the CPUMC of the main control board M sets a conditional device operation reservation flag (a flag that is turned on at step 1960, which will be described later). flag) is turned off. In the case of Yes at step 1952, at step 1954, the CPUMC of the main control board M determines whether or not a game ball has entered the V winning hole C22. In the case of Yes in step 1954, in step 1956, the CPUMC of the main control board M is within the V winning opening effective period (period from the start timing of the small winning game to the end timing of the discharge standby time related to the small winning game) Determine whether or not there is In the case of Yes at step 1956, at step 1958, the CPUMC of the main control board M transmits a V winning detection command (a command for executing a V winning detection effect, which will be described later) to the sub-main control unit SM side. command transmission buffer (transmitted to the sub-main control unit SM side by the control command transmission processing in step 1999). Next, at step 1960, the CPUMC of the main control board M turns on the condition device operation reservation flag, and proceeds to the next process (process of step 1700).

On the other hand, in the case of No in step 1952, in step 1962, the CPUMC of the main control board M determines the V winning opening effective period (from the start timing of the small winning game to the end timing of the discharge waiting time related to the small winning game) is finished. In the case of Yes at step 1962, at step 1964, the CPUMC of the main control board M turns on the condition device operation flag, and proceeds to the next process (process of step 1700). Note that even if No in step 1954, step 1956, or step 1962, the process proceeds to the next process (process of step 1700). In addition, in the case of No in step 1956, in other words, when the risk of illegal ball entry such as game ball entering the V winning opening C22 increases even though the small winning game is not being executed, It is preferable to be configured to execute error processing as appropriate. In addition, the number of rounds of the special game related to the entry of the ball into the V winning opening C22 is "9R", and the series flow of "small winning game → special game related to the entry of the ball into the V winning opening C22" is totaled. Then, the number of rounds "1R" related to the small winning game and the number of rounds "9R" related to the special game are "10R". In this example, the round for entering the ball into the V winning slot C22 (specific area) was set as 1R (that is, the number of rounds in which balls can be obtained is 9 rounds from 2 to 10 rounds), It may be designed as 1R after entering the V winning hole C22 (that is, 10 rounds worth of balls from 1 to 10 can be obtained).

Next, FIG. 34 is a flow chart of special game control processing according to the subroutine of step 1600 in FIG. First, at step 1602, the CPUMC of the main control board M determines whether or not the special game shift permission flag is ON. If Yes at step 1602, at steps 1604 and 1606, the CPUMC of the main control board M turns off the special game transition permission flag and turns on the special game execution flag. Next, at step 1607, the CPUMC of the main control board M sets an initial value (1 in this example) to a round number counter (not shown). Next, at step 1608, the CPUMC of the main control board M sets the information (special game start display instruction command) to the effect that the special game is to be started in the command transmission buffer for transmitting to the sub-main control section side ( (transmitted to the sub-main control unit SM side in the control command transmission process of step 1999), and the process proceeds to step 1612. FIG.

On the other hand, if No at step 1602, at step 1610, the CPUMC 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 proceeds to step 1612 . If No in step 1610, the CPUMC of the main control board M determines that the special game is not permitted, and proceeds to the next process (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, whether or not it is immediately before the start of each round. If Yes in step 1612, that is, if it is just before the start of each round, first, in step 1614, the set opening pattern (for example, an opening pattern that keeps opening, a pattern that opens and closes multiple times) is set. Next, at step 1616, the CPUMC of the main control board M clears the counter value of the winning ball counter to zero. Next, at step 1618, the CPUMC of the main control board M turns on the round continuation flag. Next, in step 1620, the CPUMC of the main control board M drives the first big prize winning opening electric accessory C11d (or the second big winning prize opening electric accessory C21d) of the first big winning prize opening C10 to drive the first big winning prize opening electric accessory C11d. The winning opening C10 (or the second big winning opening C20) is opened, the special game timer (especially the opening time timer) is set to a predetermined time (for example, 30 seconds) and started. On the other hand, if No in step 1612, that is, if the big winning opening is open, the process proceeds to step 1622 without performing the processing of steps 1614-1620.

Next, at step 1622, the CPUMC of the main control board M transmits a game state command related to the current special game (for example, the current number of rounds, the number of winning game balls, etc.) to the side of the sub-main control unit SM. (transmitted to the sub-main control unit SM side in the control command transmission process of step 1999). Next, at step 1624, the CPUMC of the main control board M refers to the counter value of the winning ball counter, and a predetermined number (for example, 10 It is determined whether or not there is a winning ball (ball). If Yes in step 1624 , go to step 1628 . On the other hand, in the case of No in step 1624, in step 1626, the CPUMC of the main control board M refers to the special game timer (especially the opening time timer) and sets a predetermined time (for example, 30 seconds) related to opening the big winning opening. determines whether or not has elapsed. If Yes at step 1626 , the process also proceeds to step 1628 . If No in step 1626, the process proceeds to the next process (step 1601).

Next, in step 1628, the CPUMC of the main control board M displays the first big winning opening electric accessory C11d of the first big winning opening C10 (or the second big winning opening electric accessory C21d of the second big winning opening C20). is stopped to close the first big winning hole C10 (or the second big winning hole C20). Next, at step 1630, the CPUMC of the main control board M resets the special game timer (especially the opening time timer). Next, at step 1632, the CPUMC of the main control board M turns off the round continuation flag. Next, at step 1633, the CPUMC of the main control board M adds 1 to the counter value of the round number counter (not shown). Next, at step 1634, it is determined whether or not the final round has ended (for example, whether or not the counter value of a round number counter (not shown) has exceeded the maximum number of rounds). In the case of Yes at step 1634, at step 1636, the CPUMC of the main control board M turns off the special game execution flag. Next, at step 1638, the CPUMC of the main control board M sets the information (special game end display instruction command) to the effect that the special game is to end in the command transmission buffer for transmitting to the sub-main control section SM side. (Sent to the sub-main control unit SM side in the control command transmission process of step 1999). Then, in step 1650, a game state determination process after the end of a special game, which will be described later, is executed, and the process proceeds to the next process (process of step 1601). Note that even if No in step 1634, the process proceeds to the next process (process of step 1601).

In this example, the maximum winning number of game balls set as a program in one unit game (execution of one round) is set as 10, and when the maximum winning number is reached, controls to immediately close the big winning openings (for example, the first big winning opening C10, the second big winning opening C20), and prevents the winning of game balls exceeding the maximum winning number. Even if the maximum number of prizes is exceeded due to unforeseen circumstances such as game balls temporarily stopping between the door and the game board during the closing operation of the prize opening, the maximum number of prizes may be exceeded under predetermined conditions (within a predetermined period after closing). Only in this case, winnings exceeding the maximum number of winnings are treated as valid winnings.

More specifically, when the first big winning hole C10 is opened in the first round of the jackpot, when a predetermined number (for example, 10 balls) of prizes are won in the first big winning hole C10 in the first round, the One round will end, but in the first round, in the situation where 9 game balls enter the first big prize hole C10, the tenth ball enters the first big prize hole C10 and the 11th ball enters the first big prize hole C10. Even if a predetermined number of game balls (for example, 10 balls) that will end the first round enter the first big prize hole C10 by entering the ball at the same time, It is configured to pay out prize balls with winning as effective. On the other hand, the drive mechanism (solenoid and drive transmission mechanism) and the opening/closing part (door, etc.) of the big prize opening execute closing processing and real-time is closed, and structural design and electrical design are made so that a plurality of game balls do not stay in the opening and closing member or its vicinity immediately before the closing operation. As a result, the game performance is prevented from deviating from the ball output design value, and the player is not disadvantaged.

In addition, the maximum open time set as a program in one unit game (execution of one round) is set to be 30 seconds or less throughout one unit game, When the number of winning game balls into the winning opening reaches the maximum winning number, control is performed so that the big winning opening is immediately closed, and after the maximum opening time elapses, the winning of game balls is prevented, while the balls are (The game ball temporarily stays between the door and the game board during the closing operation of the big winning opening.) Even if you win after the maximum opening time has passed, Only within a predetermined period), the winning is processed as a valid winning.

More specifically, as the opening mode of the big winning opening when executing one round in the big winning, depending on the type of big winning and the number of unit games (number of rounds executed), "open for 15 seconds → close for 2 seconds → 14.5 seconds open→closed", "29.5 seconds open→closed", etc., one of a plurality of operation patterns is set. The total opening time is set to 30 seconds or less, and the maximum opening time (29.5 seconds) of the large winning opening has passed in one round, and the game balls are being closed during the closing process of the large winning opening. Even if a ball enters the game, the prize ball is paid out as long as it is within the effective period (about 1000 ms after the closing process of the big prize opening). On the other hand, the driving mechanism (solenoid and drive transmission mechanism) and the opening/closing part (door, etc.) of the big prize gate will close the big prize gate in real time with the execution of the closing process so as to prevent winning after the maximum opening time has passed. However, structural design and electrical design are made so that a plurality of game balls do not stay in the opening and closing member or its vicinity immediately before the closing operation. As a result, it is possible to prevent the game performance from deviating from the ball output design value, and to prevent the player from being disadvantaged.

Next, FIG. 35 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 1681-1, the CPUMC of the main control board M determines whether or not the special game triggered by the ball entering the V winning hole C22 has ended (in this embodiment, the small winning game Triggered by the entry of a game ball into the V winning opening C22, a special game is executed). In the case of Yes in step 1681-1, in step 1681-2, the CPUMC of the main control board M determines that the stop symbol is a time-saving jackpot symbol (a jackpot symbol that transitions to a time-reducing game state after the execution of the special game is finished, and in this example 4B, 5A, 5B, 7A, 7B) is determined. If Yes in step 1681-2, go to step 1681-5. On the other hand, in the case of No in step 1681-1, in step 1681-4, the CPUMC of the main control board M displays the time reduction small winning symbol (the special game that will shift to the time reduction game state after execution of the special game In this example, it is determined whether or not a special game has ended triggered by 7AK (for example, fgh lights up) and 7BK (for example, pqr lights up)). . If Yes in step 1681-4, the process proceeds to step 1681-5.

Next, in step 1681-5, the CPUMC of the main control board M sets a predetermined number of times (100 times in this example) to the counter value of the time saving number counter. Next, in steps 1681-6 and 1681-7, the CPUMC of the main control board M turns on the main game time saving flag and the auxiliary game time saving flag, and proceeds to the next process (step 1601 process). In the case of No in step 1681-2, in other words, if the stop pattern is 4A, which is a time-saving jackpot pattern, or in the case of No in step 1681-4, in other words, 2BK, which is a time-saving small hit pattern (for example, oqr lights up), the process proceeds to the next process (step 1601) even if the special game has ended.

In addition, in this example, only based on the end of the big hit, the electric sapo game state (time for opening the winning opening related to normal electric accessories, time until opening, etc., number of openings, etc., and operation of normal electric accessories) It is a state in which the probability of displaying the combination of symbols to be played is changed so as to facilitate winning, and may be referred to as a time shortened game state or an auxiliary game time shortened game state). The state is limited until the main game symbols are changed a predetermined number of times (for example, 100 times) (until the main game symbols are changed for a predetermined number of times). Furthermore, the electric support game is set so that the number of game balls acquired together with the winning of other winning holes is substantially the same as the number of game balls fired (the ball output rate does not exceed 1) or less. The ball is designed during the state (the placement of each winning port, the operation of normal electric accessories, the probability of hitting the auxiliary game pattern, etc.), and the ball output performance in the electric sapo game state is the same as the jackpot game. It is designed not to be higher than performance. By configuring in this way, the game related to the main game pattern and the game related to the auxiliary game pattern become master-slave relationship in the game, and the game does not become unnecessarily complicated.

Next, FIG. 36 is a flow chart of the special game operation condition determination process according to the subroutine of step 1550 in FIG. First, at step 1552, the CPUMC of the main control board M determines whether or not the condition device operation flag is ON. In the case of Yes in step 1552, in step 1554, the CPUMC of the main control board M turns off the specific game flag (main game time reduction flag/auxiliary game time reduction flag). Next, at step 1558, the CPUMC of the main control board M clears the value of the time saving counter. Next, at step 1560, the CPUMC of the main control board M turns on the special game transition permission flag. Next, at step 1562, the CPUMC of the main control board M turns off the condition device operation flag, and proceeds to the next process (process of step 1550-1). Incidentally, even if No in step 1552, the process proceeds to the next process (process of step 1550-1).

Next, FIG. 37 is a flow chart of fraud detection information management processing related to the subroutine of step 1900 in FIG. First, in step 1902, the CPUMC of the main control board M refers to the unauthorized radio wave sensor and determines whether or not the input from the unauthorized radio wave sensor is ON for a predetermined number of times in a row (for example, this processing is timer interrupt processing). This is the process executed in , and it is intended to eliminate the influence of noise by determining whether or not it is continuously ON in a predetermined number of interrupts. In the case of "predetermined number of consecutive times", it has the same meaning). If Yes at step 1902 , at step 1904 , the CPUMC of the main control board M determines that unauthorized radio waves have been detected, turns on the unauthorized radio wave detection flag, and proceeds to step 1912 . On the other hand, if No at step 1902, at step 1906, the CPUMC of the main control board M refers to the unauthorized radio wave sensor and determines whether or not the input from the unauthorized radio wave sensor is OFF for a predetermined number of times in a row. If Yes at step 1906 , at step 1908 , the CPUMC of the main control board M determines that the detection of unauthorized radio waves has ended, turns off the unauthorized radio wave detection flag, and proceeds to step 1912 . It should be noted that even if No in step 1906 , the process proceeds to step 1912 .

Next, in step 1912, the CPUMC of the main control board M refers to the fraudulent magnetic sensor and determines whether or not the input from the fraudulent magnetic sensor is ON for a predetermined number of times in succession. If Yes at step 1912 , at step 1914 , the CPUMC of the main control board M determines that fraudulent magnetism has been detected, turns on the fraudulent magnetism detection flag, and proceeds to step 1922 . On the other hand, if No at step 1912, at step 1916, the CPUMC of the main control board M refers to the fraudulent magnetic sensor and determines whether or not the input from the fraudulent magnetic sensor is OFF for a predetermined number of times in succession. If Yes at step 1916 , at step 1918 , the CPUMC of the main control board M determines that detection of fraudulent magnetism has ended, turns off the fraudulent magnetism detection flag, and proceeds to step 1922 . It should be noted that even if No in step 1916 , the process proceeds to step 1922 .

Next, at step 1922, the CPUMC of the main control board M refers to the door open sensor and determines whether or not the input from the door open sensor is ON for a predetermined number of times in succession. If Yes at step 1922 , at step 1924 , the CPUMC of the main control board M determines that the door unit D 18 has been opened, turns on the door open flag, and proceeds to step 1932 . On the other hand, if No at step 1922, at step 1926, the CPUMC of the main control board M refers to the door open sensor and determines whether or not the input from the door open sensor is OFF for a predetermined number of times in succession. If Yes at step 1926 , at step 1928 , the CPUMC of the main control board M determines that the door unit D 18 has been opened, turns off the door open flag, and proceeds to step 1932 . It should be noted that even if No in step 1926 , the process proceeds to step 1932 .

Next, at step 1932, the CPUMC of the main control board M refers to the frame open sensor and determines whether or not the input from the frame open sensor is ON for a predetermined number of times in a row. In the case of Yes in step 1932, in step 1934, the CPUMC of the main control board M determines that the game machine frame D has been opened, turns on the frame open flag, and proceeds to the next process (step 1950-1). Transition. On the other hand, if No at step 1932, at step 1936, the CPUMC of the main control board M refers to the frame open sensor and determines whether or not the input from the frame open sensor is OFF for a predetermined number of times in succession. In the case of Yes in step 1936, in step 1938, the CPUMC of the main control board M determines that the game machine frame D has been opened, turns off the frame open flag, and proceeds to the next process (step 1950-1). Transition. Note that even if No in step 1936, the process proceeds to the next process (step 1950-1).

Next, FIG. 38 is a flow chart of error management processing related to the subroutine of step 1950-1 in FIG. First, at step 1952-1, the CPUMC of the main control board M determines whether or not the error occurrence condition is satisfied. If Yes in step 1952-1, in step 1954-1, the CPUMC of the main control board M transmits a command indicating that an error has occurred and the error type information (command to the sub control board S side) (step transmitted to the sub-main control unit SM by the control command transmission process of 1999). Next, at step 1956-1, the CPUMC of the main control board M determines whether or not the error cancellation condition is satisfied. In the case of Yes in step 1956-1, in step 1958-1, the CPUMC of the main control board M transmits a command (command to the sub control board S side) related to information indicating that the error has been canceled (in step 1999 is sent to the sub-main control unit SM by the control command sending process), and the process proceeds to the next process (step 1550-7). Note that even if No in step 1952-1 or step 1956-1, the process proceeds to the next process (process of step 1550-7).

Next, FIG. 39 is a flow chart of firing control signal output processing 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 the payout control board (sometimes referred to as the prize ball payout control board KH) and the communication state (BIT0) and disconnection short circuit power supply abnormality (BIT1). Get the error flag. BIT0, which indicates the communication state, indicates normal if "00000000B" and indicates abnormal if "00000001B". In BIT1 indicating disconnection and short-circuit power source abnormality, "00000000B" indicates normality, and "00000010B" indicates abnormality. Next, at step 1550-7-2, the CPUMC of the main control board M calculates the AND of the error flag acquired at step 1550-7-1 and the determination data ("00000011B"). Next, at step 1550-7-3, the CPUMC of the main control board M sets the firing enable signal bit data. For example, BIT5 of the output port indicates the emission enable signal, and "00000000B" indicates an error (abnormality), and "00100000B" indicates normality. Next, at step 1550-7-4, the CPUMC of the main control board M outputs to the output port and proceeds to the next process (process of step 1550-8). 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 effect strobe bit data, and BIT7 is a security bit.

Next, FIG. 40 is a flow chart of external signal output processing according to the subroutine of step 3500 in FIG. First, at step 3502, the CPUMC of the main control board M refers to the game state temporary storage means MB to confirm the state of the gaming machine. Next, in step 3504, the CPUMC of the main control board M refers to the external terminal transmission content determination table 1, and based on the confirmed state of the gaming machine, transmits the signal to the hall computer HC via the external relay terminal board G. A signal indicating the state of the gaming machine is output, and the process proceeds to the next process (step 1550-10).

(External relay terminal board)
Here, the signal output via the external relay terminal strip G according to this embodiment will be described with reference to the lower part of the figure (image diagram of signal output). The external relay terminal plate G has a plurality of external connection terminals as output terminals to which various cable connectors are connected {for example, information on prize ball payout, information on winning and symbol stop, current game state (normal game state, game state information output terminal for outputting information related to specific game state, special game state, etc.), error information for outputting various error information detected by an open detection sensor etc. when the door is open terminals for output, etc.} are provided. As will be described later, the plurality of output terminals are connected to the hall computer HC by cable harnesses so that information can be output from the plurality of output terminals to the hall computer HC. Here, in the present embodiment, one output terminal is assigned as a terminal for outputting 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 output terminals for signals output from the main control board M. For example, a jackpot output terminal for outputting a signal during a jackpot (there are a plurality of terminals depending on the type of jackpot). ), a door opening output terminal that outputs a signal while the glass door D18 is open, a start opening winning output terminal that outputs a signal when the start opening wins, and a ball shortage in the prize ball tank KT. Game-related information that is important for the game hall operator, such as output terminal for out-of-ball output that outputs a signal while it is in use, output terminal for the number of times of special design confirmation that outputs a signal when the special design is fixed, etc. This is an output terminal. That is, by using the output terminal for the payout-related information as one output terminal, it is possible to avoid exhaustion of the terminals for output of these important game-related information.

Further, in this embodiment, the main control board M and the prize ball payout control board KH are configured to transmit game-related information and 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, an outline of the information transmission system of the pachinko game machine according to the present embodiment will be described. A cable harness connects between G and the hall computer HC. On the other hand, as shown in this example, since the external relay terminal board G is composed of 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 connected. It doesn't mean that That is, an electrical signal (a signal of binary logic 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 After being replaced by a physical signal (a signal of binary logic whose switch state is ON/OFF) by the unit, it 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 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 closes the contact portion G2, thereby connecting the output terminal and the hall computer HC. Further, when the relay coil G1 is demagnetized, the contact portion G2 returns to the open state, thereby disconnecting the output terminal from the hall computer HC. Therefore, on the hall computer HC side, a pulse signal substantially identical to the pulse signal input to the input terminal of the external relay terminal board G can be obtained by detecting the conduction period. With such a configuration, one-way communication from the main control board M and the prize ball payout control board KH to the hall computer HC can be physically secured, and the main control board M and This prevents illegal manipulation of the prize ball payout control board KH (so-called remote control goto). In this example, the mechanism using the relay coil is configured to prevent slanderous behavior and enable one-way communication to the hall computer HC. A photosensor having a light-receiving part is also configured to enable one-way communication (for example, light from a light-emitting part connected to the main control board M and prize ball payout control board KH is received by a light-receiving part connected to the hall computer HC). It should be supplemented that the signal can be received by reading it with the unit.

However, since it is configured to be temporarily replaced with a physical signal (switch state is on/off), the main control board M and the prize ball payout control board KH to the hall computer HC, one signal on the external relay terminal board 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 number of special symbol determination, It is customary to configure so that only information indicating that "one variation of special symbols has ended" can be transmitted).

Next, the processing on the prize ball payout control board KH will be described in detail with reference to the flowcharts of FIGS. 41 to 52. FIG.

First, FIG. 41 is a flowchart of a main routine 4000 executed on the prize ball payout control board KH side. First, at step 4100, the payout control board (payout control means) KH executes an error control process at the time of abnormality detection, which will be described later. Next, at step 4200, the payout control board (payout control means) KH executes prize ball payout related information transmission/reception processing with the main control board M, which will be described later. Next, at step 4300, the payout control board (payout control means) KH executes a prize ball payout control process (at the start of prize ball payout/motor drive start), which will be described later. Next, at step 4400, the payout control board (payout control means) KH executes prize ball payout control processing (at the end of motor driving/at the end of prize ball payout), which will be described later. Next, at step 4500, the payout control board (payout control means) KH executes prize ball payout control processing (during execution of motor drive), which will be described later. Then, at step 4600, the payout control board (payout control means) KH executes a motor error processing, which will be described later, and proceeds to step 4100.

Here, referring to the block diagram on the right side of FIG. , an error control means 3200 for controlling errors related to payout on the prize ball payout control board KH side, and a predetermined number of game balls in response to a prize ball payout command or a ball rental command. and a payout control means 3300 for executing payout processing. Each means will be described in detail below.

First, the transmission/reception control means 3100 includes reception control means 3110 for controlling reception of information (for example, commands and signals) from the main control board M and the card unit R, and transmission of information to the main control board M and the card unit R. and transmission control means 3120 for controlling.

Here, the reception control means 3110 further has main side reception control means 3111 for controlling reception of information (for example, commands) from the main control board M. FIG. The main side reception control means 3111 further has main side reception information temporary storage means 3111a for temporarily storing information transmitted from the main control board M side. Further, the transmission control means 3120 further has a payout-related error information temporary storage means 3121 for temporarily storing error information relating to the payout operation for transmission to the main control board M side.

Next, the error control means 3200 includes 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, An error control means 3230 for error control when detecting an abnormality in the operation of the ball, an error control means 3240 for error control when an abnormality is detected when an abnormality is detected, and an error control means 3240 when an error is detected when an abnormality in the path of the ball is detected. Ball path abnormality detection error control means 3250 that governs control, payout motor abnormality detection error control means 3260 that governs error control when a payout motor abnormality is detected, and a fatal abnormality related to the prize ball payout operation is detected. a ball bite error occurrence timer 3200t that manages the error notification period when a ball bite error occurs in the prize ball payout unit KE10; It further has a non-passage error occurrence timer 3200t2 that manages the period of error notification when a non-passage error of the payout count sensor KE10s occurs. Here, the payout motor operation abnormality detection error control means 3230 further has an illegal payout accumulation counter 3231 for accumulating and counting the number of times the payout motor operation abnormality is detected. In addition, 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. In addition, the ball path abnormality detection error control means 3250 further has a payout interval extension control means 3251 for executing time extension processing of payout intervals relating to prize ball payout. Further, the payout motor abnormality detection error control means 3260 further has 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 means 3300 has a payout process related information temporary storage means 3310 for temporarily storing information necessary for the payout process. Here, the payout process related information temporary storage means 3310 is payout status flag temporary storage means 3311 for temporarily storing the status related to payout (for example, whether or not payout is in progress, whether or not payout abnormality has occurred). During the payout process, a payout counter for setting the number of game balls to be paid out, step counter temporary storage means for temporarily storing the number of steps to be driven by the payout motor KE10m, and the payout motor KE10m are driven. a temporary storage means 3314 for temporarily storing the position information of the excited stator, and a predetermined time after one continuous payout operation (unit payout operation). It further has a ball passage waiting timer 3315 for timing the 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 reaches 0, but is not limited to this, and is an increment type timer. A configuration using a timer is also possible. Each subroutine will be described in detail below.

Next, FIG. 42 is a flow chart of error control processing at the time of abnormality detection according to the subroutine of step 4100 of FIG. First, at step 4110, the error control means 3200 executes an error control process at the time of abnormal operation of the payout motor, which will be described later. Next, at step 4120, the error control means 3200 executes an error control process at the time of abnormal payout detection, which will be described later. Next, at step 4140, the error control means 3200 executes an error control process at the time of ball path abnormality detection, which will be described later. Next, at step 4170, the error control means 3200 executes an error control process at the time of abnormal payout motor detection, which will be described later. Next, in step 4190, the error control means 3200 executes an error control process when a payout stop abnormality is detected, which will be described later, and proceeds to the next process (prize ball payout related information transmission/reception process in step 4200).

Next, FIG. 43 is a flow chart of the error control process at the time of detection of malfunction of the payout motor according to the subroutine of step 4110 of FIG. First, the purpose of this process is to count the number of occurrences of the abnormality when a payout motor operation abnormality described later is detected, and to set a flag indicating the occurrence of an error when the number of occurrences of the abnormality exceeds a threshold value. is to turn on. First, in step 4111, the payout motor operation abnormality detection error control means 3230 refers to the payout state flag temporary storage means 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 passing of the game ball by the payout count sensor KE10s under the condition that the prize ball payout process is not executed on the prize ball payout control board KH side. It is a flag that is turned on when (withdrawal motor operation abnormality). In the case of 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 adds 1 to the counter value of the fraudulent payout cumulative counter 3231 (increments). Next, in step 4114, the payout motor operation abnormality detection error control means 3230 refers to the counter value of the fraudulent payout cumulative counter 3231, and determines whether or not the count value is equal to or greater than a predetermined number (for example, 25). do. In the case of Yes in step 4114 , in step 4115 , the payout motor operation error 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 . It should be noted that even if No in step 4111 or step 4114 , the process proceeds to step 4116 .

Next, in step 4116, the payout motor operation error 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. In the case of Yes in step 4116, in step 4119, the payout motor operation error detection error control means 3230 sets the payout motor operation error as payout related error information in the payout related error information temporary storage means 3121, and the next process ( It shifts to step 4120 (error control processing when abnormal payout is detected). Also in the case of No in step 4116, the process proceeds to the next process (error control process at step 4120 when abnormal payout is detected).

Next, FIG. 44 is a flow chart of error control processing at the time of payout abnormality detection, relating to the subroutine of step 4120 of FIG. First, the purpose of this process is to count the number of excessive game ball payouts caused by the abnormality when a payout abnormality, which will be described later, is detected, and when the count number exceeds the threshold, It is to turn on a flag indicating the occurrence of an error. 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, the payout abnormality detection flag is set when a predetermined number of prize ball payouts based on a command transmitted from the main control board M side is exceeded and an excessive payout of game balls is detected (payout This is a flag that is turned on when there is an abnormality. In the case of Yes in step 4121, in step 4122, the payout abnormality detection 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 excess payout number temporarily stored in the payout process related information temporary storage means 3310, and sets the excess payout number to the excess payout accumulation 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 greater than a predetermined number (for example, 25). In the case of Yes at step 4124 , at step 4125 , the payout abnormality detection error control means 3240 turns on the overpayment error flag in the error flag temporary storage means 3221 , and proceeds to step 4126 . It should be noted that even if No in step 4121 or step 4124 , the process proceeds to step 4126 . In addition, the overpayment error (state in which the overpayment error flag is on) is configured to be resolved only by turning on the power again, but this example is only an example and is not limited to this. For example, the error may be canceled by pressing an error canceling switch or by elapse of a predetermined period of time.

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. In the case of Yes in step 4126, in step 4129, the payout abnormality detection error control means 3240 sets an excessive payout error as payout related error information in the payout related error information temporary storage means 3121, and the next process (step 4140 error control processing when ball path abnormality is detected). If No in step 4126, the process proceeds to the next process (error control process at step 4140 when ball path abnormality is detected).

Next, FIG. 45 is a flow chart of error control processing at the time of ball path abnormality detection according to the subroutine of step 4140 of FIG. First, the purpose of this process is to detect an abnormality in the ball path, which will be described later. Or, when an abnormality corresponding to the ball running out abnormality or the ball shortage abnormality is detected, along with investigating whether there is a small amount of game balls (ball shortage) abnormality in the prize ball payout unit KE10 , to turn on a flag indicating that an error has occurred. In addition, (2) when an abnormality equivalent to a ball running out abnormality or a ball shortage abnormality is detected, by extending the payout interval of the prize ball payout, the waiting time until the ball running out abnormality or ball shortage abnormality is resolved. is to create 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 is set at the end of execution of a predetermined number of payout operations (unit payout operations) scheduled on the prize ball payout control board KH side, and the motor drive operates normally. This flag is turned on when it is detected that the predetermined number of coins to be paid out is not reached under the condition that it is determined that the number of coins to be paid out is not enough. In the case of Yes in step 4141, in step 4142, the ball path abnormality detection 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 the ball running out abnormality or the ball shortage abnormality are satisfied. Here, the conditions for occurrence of the ball-out abnormality or the ball-insufficient abnormality are not particularly limited. An example where it is assumed that a ball running out abnormality has occurred when the presence of a game ball cannot be detected, and a ball flow path directly above the sprocket in the prize ball payout unit KE10 (in this example, there are two ball flow paths ) is provided with a game ball detection sensor, and when the presence of game balls cannot be detected by any of the detection sensors, it is assumed that the ball shortage abnormality occurs. In the case of Yes in step 4143 , in step 4144 , ball path abnormality detection error control means 3250 turns on the ball path error flag in 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 . It should be noted that 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. In the case of Yes in step 4151, in step 4152, the ball path abnormality detection error control means 3250 determines whether or not the conditions for resolving the ball run-out abnormality or ball shortage abnormality are satisfied. Here, there is no particular limitation on the conditions for resolving the out-of-balls abnormality or insufficient balls-abnormality, and in the case where the above-mentioned conditions for occurrence of out-of-balls abnormality or insufficient balls-abnormality are unsatisfied, an example in which the abnormality is resolved can be mentioned. In the case of Yes in step 4152 , in step 4153 , ball path abnormality detection error control means 3250 turns off the ball path error flag in error flag temporary storage means 3221 . Then, in step 4155, the payout interval extension control means 3251 determines the excitation timing (for example, 3ms×8 steps=continuous excitation to perform a predetermined number of payout operations at a speed of 1 at 24ms) during normal operation, and the ball A passage waiting time (for example, 500 ms) is set, and the process proceeds to the next process (error control process at step 4170 when an abnormality in the payout motor is detected). On the other hand, if No at step 4152, at step 4156, the payout interval extension control means 3251 adjusts the excitation timing and the ball passage waiting time so that the payout speed of one ball is relatively lower than that during normal operation. Then, the process proceeds to the next process (error control process at step 4170 when abnormality of payout motor is detected). Incidentally, even in the case of No in step 4151, the process proceeds to the next process (error control process at step 4170 when abnormality of payout motor is detected). Here, the excitation timing to be changed is not particularly limited, but for example, after performing a payout operation for one ball at a speed of 3 ms×8 steps=24 ms, wait for a predetermined time (for example, 5 seconds). An example can be given of changing the excitation timing so that a time is provided, and after the waiting time has elapsed, the payout operation is performed again at a speed of 1 payout every 3 ms×8 steps=24 ms. Also, the changed ball passage waiting time is not particularly limited (for example, changed from 500 ms to 30 seconds).

Next, FIG. 46 is a flow chart of the error control process at the time of abnormal payout motor detection according to the subroutine of step 4170 of FIG. First, the purpose of this process is to turn on a flag indicating the occurrence of an error when an abnormality in the payout motor, which will be described later, is detected, and to retry the payout motor (the stepping motor KE10m in the prize ball payout unit KE10). It is to execute a switching control process. First, in step 4171, the payout motor abnormality detection 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 operating normally due to external factors such as ball jam. In the case of Yes in step 4171 , in step 4172 , the payout motor abnormality detection 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 the payout motor error in the payout related error information temporary storage means 3121 as payout related error information. Then, at 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 . It should be noted that 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 to a standby state for a predetermined time after the occurrence of a motor error, which will be described later, and providing a wait time for the motor error to be eliminated 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. In the case of Yes at step 4177, at step 4178, the retry operation control means 3261 refers to the payout state flag temporary storage means 3311 and determines whether or not the retry operation execution permission flag is ON. In the case of Yes at step 4178 , at step 4179 , the retry operation control means 3261 turns off the retry operation execution permission flag in the payout state flag temporary storage means 3311 . Next, at 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. Here, the predetermined number of steps during the retry operation is not particularly limited, but an example of setting it to the same number as the confirmation timing of the rotor position confirmation sensor KE10ms during the retry operation, which will be 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 means 3261 selects a retry operation excitation method (for example, a well-known 1-2 phase excitation method) related to stepping motor operation and a one-step switching speed for retry operation (for example, 6 ms). Next, in step 4183, the retry operation control means 3261 sets a predetermined value (for example, 500 ms) in the ball passage waiting timer 3315 as the ball passage waiting time/motor pause time related to the stepping motor operation. Next, at step 4184 , the retry operation control means 3261 turns on the retry operation in-execution 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 process (error control process at step 4190 when the payout stop abnormality is detected). do. Also in the case of No in step 4177 or step 4178, the process proceeds to the next process (error control process at step 4190 when an abnormality requiring stoppage of payout is detected).

Next, FIG. 47 is a flow chart of the error control process at the time of the payout stop abnormality detection, according to the subroutine of step 4190 of FIG. First, the purpose of this process is to turn on a 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 detect a fatal error related to the continuation of the prize ball payout process. To disable the continuation of prize ball payout processing until the abnormality is eliminated. Here, the fatal anomaly related to the continuation of the prize ball payout process includes a communication error between the main control board M and the prize ball payout control board KH, a communication error between the card unit R and the prize ball payout control board KH, and payout. The sensor abnormality of the count sensor KE10s, the tray (upper tray) full tank abnormality, and the like can be mentioned. 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 has been switched from off to on. In the case of Yes in step 4191-1, in step 4191-2, the payout stop abnormality detection error control means 3270 sets and starts the error duration (for example, 120 seconds) in the ball biting error generation timer 3200t, Go 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 error control means 3270 refers to the ball engagement error generation timer 3200t, and determines whether the timer value is 0. judge. If Yes at step 4191-3, at 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, also in the case of No in step 4191-3, the process proceeds to step 4192-1.

Next, in step 4192-1, the payout stop abnormality detection error control means 3270 refers to the error flag temporary storage means 3221 and determines whether or not the switch non-passage error detection flag has been switched from off to on. In the case of Yes in step 4192-1, in step 4192-2, the payout stop abnormality detection time error control means 3270 sets the error duration (for example, 120 seconds) to the non-passage error occurrence timer 3200t2 and starts it, Go 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-passage error generation timer 3200t2, and determines whether the timer value is 0. judge. In the case of Yes in step 4192-3, in step 4192-4, the payout stop abnormality detection error control means 3270 turns off the switch non-passage error flag in the error flag temporary storage means 3221, and step 4193-1. transition to On the other hand, if No in step 4192-3, the process also proceeds 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 has been pressed. If Yes in step 4193-1, in steps 4193-2 to 4193-5, the payout stop abnormality detection error control means 3270 generates a flag ( For example, the payout motor operation error flag, payout operation incomplete game ball detection flag, payout motor error flag, switch non-passing error detection flag) are turned off, and the process proceeds to step 4194-1. On the other hand, also in the case of No in step 4193-1, the process proceeds to step 4194-1.

Next, in step 4194-1, the error control means 3270 upon detecting an abnormality requiring stoppage of payout determines whether or not an abnormality in communication between the main control board M and the ball payout control board KH is detected. In the case of 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 means 3270 turns off the communication error flag in the error flag temporary storage means 3221, and proceeds to step 4195-1. Transition.

Next, in step 4195-1, the error control means 3270 when the payout stop abnormality is detected detects a sensor abnormality of the payout count sensor KE10s (for example, there is no input from the count sensor, or the input value is constant for a predetermined time or longer). , etc.) is detected. In the case of Yes in step 4195-1, in step 4195-2, the payout stop abnormality detection time 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, in the case of No in step 4195-1, in step 4195-3, the payout stop abnormality detection time error control means 3270 turns off the prize ball device error flag in the error flag temporary storage means 3221, and step 4196- Go to 1.

Next, in step 4196-1, the error control means 3270 upon detection of an abnormality requiring stoppage of dispensing determines whether or not the tray (upper tray) full tank abnormality has been detected. In the case of Yes in step 4196-1, the payout stop abnormality detection error control means 3270 turns on the tray full error flag in the error flag temporary storage means 3221 in step 4196-2. Next, in step 4196-3, the payout stop abnormality detection error control means 3270 transmits a saucer full tank command to the sub-control board S side, and proceeds to step 4197-1. On the other hand, if No in step 4196-1, the payout stop required abnormality detection error control means 3270 turns off the tray full error flag in the error flag temporary storage means 3221 in step 4196-4. Next, in step 4196-5, the payout stop required error detection error control means 3270 transmits a saucer full tank release command to the sub-control board S side, and proceeds to step 4197-1.

Next, in step 4197-1, the payout stop required error detection error control means 3270 determines whether or not a connection error of the card unit R is detected. In the case of Yes in step 4197-1, in step 4197-2, the payout stop abnormality detection error control means 3270 turns on the CR unit disconnection error flag in the error flag temporary storage means 3221, and step 4198-1. to On the other hand, if No in step 4197-1, the payout stop abnormality detection error control means 3270 turns off the CR unit disconnection error flag in the error flag temporary storage means 3221 in step 4197-3, and -1.

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

In the case of Yes in step 4198-1, in step 4198-2, the payout stop abnormality detection time error control means 3270 refers to the error flag temporary storage means 3221, the communication error flag, the prize ball device error flag, the tray full It is determined whether or not all the error flags of the error flag and the CR unit disconnection error flag are off. In the case of Yes in step 4198-2, in step 4198-3, the payout stop required 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). is paused, the payout operation is resumed), and the process proceeds to the next process (process of step 4200). On the other hand, if No in step 4198-1 or step 4198-2, in step 4198-4, the payout stop required error detection error control means 3270 forcibly suspends the payout operation in the payout control means 3300, and then (process of step 4200).

Next, FIG. 48 is a flowchart of prize ball payout related information reception processing (for the main control board) relating to the subroutine of step 4200 of FIG. Here, the first half of the flow is information reception processing from the main control board M (and accompanying processing of setting the number of prize balls to be paid out), and the second half of the flow is information transmission processing to the main control board M. Therefore, the first half of the process of receiving information from the main control board M (and the associated process of setting the number of prize balls to be paid out) will be described. With reference to 3311, it is determined whether or not the prize ball payout flag is off. Here, the "prize ball payout flag" is when the prize ball payout process is being executed on the payout control side (when the payout motor of the payout device is in driving operation, when the ball passage waiting time/motor pause time It is a flag that is turned on when the If Yes at step 4205, at step 4210, the main reception control means 3111 refers to the main reception information temporary storage means 3111a and determines whether or not a prize ball payout command has been received. If Yes at step 4210, at 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 number of prize balls to be paid out based on the prize ball payout command information temporarily stored in the main-side reception information temporary storage means 3111a, and determines the prize ball payout. The number information is set in the payout counter, and the process proceeds to the next process (step 4225). This completes the set processing of the number of prize balls to be paid out when the normal prize ball payout processing is executed. It should be noted that even if No in steps 4205 and 4210, the process proceeds to the next process (step 4225).

Next, the information transmission processing to the main control board M will be described. First, in step 4225, the transmission control means 3120 refers to the error flag temporary storage means 3221 and determines whether or not the payout-related error transmission flag is on. judge. Here, the "payout-related error transmission flag" is when the 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 immediately after the error is notified to the main control board M side and then turned off. If Yes at step 4225 , at step 4230 the error control means 3200 turns off the payout-related error transmission flag in the error flag temporary storage means 3221 . Then, at 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). Also in the case of No in step 4225, the process proceeds to the next process (step 4240).

Next, at 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. If Yes at step 4240, at step 4245, the transmission control means 3120 accesses the flag area of the payout status 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 {prize ball payout control process in step 4300 (prize ball payout start・Motor drive start)}. Incidentally, even in the case of No at step 4240, the next process {prize ball payout control process at step 4300 (at the start of prize ball payout/motor drive start)} is shifted to. With this, the prize ball payout completion information transmission process is terminated.

Next, FIG. 49 is a flow chart of prize ball payout control processing (at the start of prize ball payout/motor drive start) relating to the subroutine of step 4300 of FIG. Here, this process is the process before executing the motor drive process of the next step 4400, and in response to receiving the prize ball payout command from the main control board M side, the number of motor drive steps, etc. This is the process of setting. First, at 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 in FIG. 48) 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. do.

Next, at step 4320, the payout control means 3300 determines whether or not the number of prize balls to be paid out set in the payout counter is equal to or greater than a predetermined number (for example, 3). If Yes at step 4320 , at step 4325 , the payout control means 3300 temporarily stores the counter value (n) in the step counter temporary storage means so that the predetermined number of coins are paid out, and proceeds to step 4332 . The counter value (n) temporarily stored here is the number of steps of the stepping motor. On the other hand, if No in step 4320, the payout control means 3300 temporarily stores the counter value (n) in the step counter temporary storage means so that the number of prize balls to be paid out set in the payout counter is paid out, and proceeds to step 4332. Transition.

Next, at step 4332 , the payout control means 3300 sets the planned payout number in the current unit payout operation (that is, the payout number scheduled at step 4325 or step 4330 ) to the unit payout counter 3317 . Next, at step 4335, the payout control means 3300 sets 0 as the excitation stator position identification counter value (j). Here, the excitation stator position specific counter indicates the relative position of the rotor with respect to the stator, and "0" corresponds to the default position during payout standby (stop). Next, in step 4337, the payout control means 3300 switches between the normal operation excitation method (for example, the well-known 2-2 phase excitation method) and the normal operation switching speed (for example, 3 ms ). Next, at step 4338, the payout control means 3300 sets a predetermined value (for example, 500 ms) in the ball passage waiting timer 3315 as the ball passage waiting time/motor pause time related to the stepping motor operation. Next, at step 4339, the payout control means 3300 accesses the payout state flag temporary storage means 3311 and turns off the retry operation executing flag. Here, the retry operation in-execution flag is a flag that is turned on while the retry operation related to the operation of the stepping motor is being executed as described above. Then, at 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 processing {prize ball payout control process at step 4400 (at the end of motor drive, prize At the end of ball delivery)}.

On the other hand, if No at step 4305, at 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. If Yes in step 4345, the motor has already been driven, so the next process {prize ball payout control process of step 4400 (at the end of motor driving/at the end of prize ball payout)} is shifted to.

On the other hand, if 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 prize ball payout continuation flag refers to the case where the prize ball payout operation should be continued after the stepping motor has been operated for a predetermined number of steps in the unit payout operation and the ball passage waiting time/motor pause time has elapsed ( A detailed condition will be described later). In the case of Yes at step 4350, the next process {prize ball payout control process at step 4400 (at the end of motor driving/at the end of prize ball payout)} is shifted to.

On the other hand, if No at step 4350, at 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 to determine whether or not the counter value exceeds 0 (that is, whether or not all of the planned payout quantity by the current unit payout operation has been paid out). or not). If Yes at step 4354 , at step 4356 , the payout control means 3300 accesses the payout state flag temporary storage means 3311 , turns on the ball path abnormality detection flag, and proceeds to step 4320 . On the other hand, if step 4354 is No, 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 being triggered by the reception of the prize ball payout command from the main control board M side. If it is determined that the number of balls scheduled to be paid out by the unit payout operation this time has not been paid out, an abnormality that causes a ball-out error or a ball-shortage error is detected.

Next, FIG. 50 is a flow chart of prize ball payout control processing (at the end of motor driving/at the end of prize ball payout) relating to the subroutine of step 4400 in FIG. Here, this process is the termination process when all the motors scheduled in the previous process (step 4300) are finished to be driven, or when all the scheduled prize balls are paid out. . Here, step 4402 to step 4419 executes motor drive end processing, step 4420 to step 4425 execute game ball detection processing, and step 4430 to step 4462 execute prize ball payout end processing.

First, the motor drive end processing will be described. First, in step 4402, 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 prize ball payout flag is on. do. In the case of Yes at step 4402, at step 4405, 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 at step 4405, at step 4410, the payout control means 3300 refers to the counter value (n) in the step counter temporary storage means to determine whether the counter value is 0, that is, step 4325 in FIG. Alternatively, it is determined whether or not all steps in the current unit payout operation set in step 4330 have been executed. If Yes at step 4410, at 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, at 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. In the case of Yes at step 4416 , at 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 executing flag, and proceeds to step 4418 . On the other hand, if No in step 4416 , the process proceeds 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 the current excitation stator position identification counter value (j) is continuously excited). Next, at step 4419, the payout control means 3300 starts the ball passage waiting timer 3315, and proceeds to step 4420. It should be noted that the process proceeds to step 4420 also in the case of No in step 4405 or step 4410 . With this, the motor driving end processing is ended.

Next, the game ball detection process will be described. First, at 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. In the case of Yes at step 4420 , at step 4422 , the payout control means 3300 subtracts 1 from the counter value temporarily stored in the unit payout counter 3317 . Next, at step 4425 , the payout control means 3300 subtracts 1 from the counter value temporarily stored in the payout counter, and proceeds to step 4430 . It should be noted that the process proceeds to step 4430 also in the case of No in step 4420 . Here, in this example, the value of the payout counter is decremented by 1 each time an entering ball is detected. If so, it may be configured so that the value corresponding to the number of hits can be subtracted. With this, the game ball detection processing is terminated.

Next, the prize ball payout end process will be described. First, at step 4430, the payout control means 3300 refers to the payout counter and determines whether or not the count value is 0 or less. In the case of Yes at step 4430, at 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 related to the payout is detected by the sensor even though the driving of the motor related to the payout has not ended), in step 4432, The payout control means 3300 turns on the game ball detection flag when payout is not completed in the error flag temporary storage means 3221 , and proceeds to step 4435 . On the other hand, if step 4431 is No, the process proceeds to step 4435 as well.

Next, in steps 4435 and 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, at step 4441, the payout control means 3300 refers to the payout counter and determines whether or not the count value is less than zero. In the case of Yes at step 4441 , at step 4442 , the payout control means 3300 turns on the payout abnormality detection flag in the payout state flag temporary storage means 3311 . Next, at step 4443, the payout control means 3300 refers to the payout counter, and based on the count value, the number of excess payouts (for example, if the counter value is "-3", the number of excess payouts is "3"). The information 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 at step 4500 (during execution of motor drive)}. In addition, if No in step 4441 (that is, if the count value of the payout counter is 0 and the predetermined number of payouts are normally paid out), the following processing {prize ball payout control processing in step 4500 ( (during execution of motor drive)}. In this example, an overpayment is detected when the value of the payout counter becomes 0 or less, but the present invention is not limited to this. When the time (for example, sufficient detection waiting time until the game ball paid out by the drive is detected by the payout count sensor KE10s) has passed, detection of excessive payout (payout counter value is less than 0 determination of whether or not) can be executed (that is, excessive payout is an unexpected situation in which game balls exceeding the number of game balls scheduled to be paid out have been paid out) This means that the occurrence of this contingency, which is extremely difficult to occur due to design, means that there is a problem with one of the dispensing mechanisms, or that a fraudulent act has occurred during the dispensing operation. (meaning that it is likely that

On the other hand, if No at step 4430, at 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 zero. In the case of Yes in step 4445, in step 4446, the payout control means 3300 turns on the switch non-passing error detection flag in the error flag temporary storage means 3221 (in this example, after the payout operation ends, a predetermined When the game balls for the number of game balls related to the payout operation are not detected even after the ball passing waiting time of time has passed, it is immediately determined that the switch non-passing error has occurred. It is not limited, and it may be configured to determine that a switch non-passage error has occurred when the event occurs multiple times.)

Next, at step 4447, the payout control means 3300 accesses the payout state flag temporary storage means 3311 and determines whether or not the retry action execution waiting 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 at step 4447, at 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 following processing {prize ball payout control process at step 4500 ( (during execution of motor drive)}. On the other hand, in the case of No in step 4447, in steps 4460 and 4462, the payout control means 3300 accesses the payout state flag temporary storage means 3311, turns off the retry action execution standby flag, and sets the retry action execution permission flag. It is turned on, and the process proceeds to the next process {prize ball payout control process at step 4500 (during execution of motor drive)}. Incidentally, also in the case of No in step 4445, the next process {prize ball payout control process of step 4500 (during execution of motor drive)} is shifted to.

Here, if No in step 4402 (that is, if the prize ball payout process is not being executed), in step 4470, the payout control means 3300 determines whether or not a game ball detection signal has been received from the payout count sensor KE10s. judge. If Yes at step 4470, at step 4472, the payout control means 3300 turns on the payout motor operation abnormality detection flag in the payout state flag temporary storage means 3311, and performs the following processing {prize ball payout control process at step 4500 ( (during execution of motor drive)}. Incidentally, even in the case of No at step 4470, the next process {prize ball payout control process at step 4500 (during execution of motor drive)} is shifted to.

Next, FIG. 51 is a flow chart of prize ball payout control processing (during execution of motor driving) relating to the subroutine of step 4500 of FIG. Here, this process is a process of actually driving the motor based on the number of steps set in the previous process (step 4400). First, at 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 (see step 4340 in FIG. 49). is a flag that is turned off when all are executed. Here, if Yes at step 4505, at step 4510, the payout control means 3300 subtracts 1 from the step counter value (n) of the step counter temporary storage means. Next, at step 4520 , the payout control means 3300 updates (increments by one) the exciting stator position identification counter value (j) in the excitation stator position identification counter value temporary storage means 3314 . Next, at step 4525, the payout control means 3300 excites the stator corresponding to the excitation stator position identification counter value (j) in the excitation stator position identification counter value temporary storage means 3314 based on the predetermined excitation method and switching speed. .

Next, at 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 KE10 ms is performed for the purpose of confirming whether or not an abnormal operation related to the motor operation (out-of-step phenomenon due to ball jamming, etc.) has occurred. In the case of Yes at step 4530, at step 4550, the payout control means 3300 refers to the presence or absence of the detection signal from the rotor position confirmation sensor KE10ms. Then, at step 4555, error control means 3200 determines whether or not the rotor is rotating correctly, that is, whether or not a motor error has occurred, based on the presence or absence of the detection signal at step 4550. If Yes at step 4555, at step 4560, the error control means 3200 turns on the motor position abnormality flag in the payout status flag temporary storage means 3311, and proceeds to the next process (motor error processing at step 4600). If No at step 4530, the process proceeds to the next process (motor error processing at step 4600). The motor error flag in means 3221 is turned off, and the process proceeds to the next process (step 4600 for motor error processing).

Next, FIG. 52 is a flowchart of the motor error processing 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, at step 4605, the payout control means 3300 refers to the payout state flag temporary storage means 3311 and determines whether or not the motor position abnormality flag is on. Here, as shown in step 4560 in FIG. 51, it is detected at a predetermined detection timing whether or not the motor is at a predetermined rotational position. and the motor position abnormality flag is turned on. In the case of Yes at step 4605, at 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 . At step 4620, the error control means 3200 clears the step counter value (n) in the step counter temporary storage means, and proceeds to the next process (error control process at the time of abnormality detection at step 4100). This is because the number of steps set this time was not executed due to the occurrence of a motor error. 4415). Note that even if No in step 4605, the process proceeds to the next process (error control process at the time of abnormality detection in step 4100).

Next, with reference to FIG. 53, control processing executed on the side of the sub-main control unit SM according to this embodiment will be described. First, FIG. 53 is a main flowchart on the sub-control board S side (especially on the sub-main control section SM side). Here, the process of FIG. 1(a) is the process on the side of the sub-main control unit SM that is executed after reset such as when power is turned on to the gaming machine. That is, when the game machine is powered on, in step 2001, the CPUSC of the sub-control board S resets and starts the power-on timer. The power-on timer is provided for grasping the opening timing of the lower shielding member C25. Next, in step 2002, the CPUSC of the sub-control board S executes initial processing based on the information received from the main side (main control board M side) (for example, when RAM clear information is received → sub-side When the RAM is initialized and various information commands are received → the performance-related information at the time of power failure is reset in the sub-side RAM). Next, in step 2003, the CPUSC of the sub-control board S restores the number of reservations (for example, the value of the binding reservation counter) based on the information received from the main side (main control board M side). In addition, the performance being executed, the information related to the special pattern, etc. are not restored, and the "preparing" screen is displayed until the start of the next variation. After that, the CPUSC of the sub-control board S shifts to loop processing for repeatedly executing (b), which is a repetitive processing routine. Here, when (b) is executed, first, in step 2400-1, the CPUSC of the sub control board S executes a hold information management process, which will be described later, as shown in the process of FIG. . Next, at step 2700-1, the CPUSC of the sub-control board S executes a decorative pattern display content determination process, which will be described later. Next, at step 2800, the CPUSC of the sub-control board S executes decorative symbol display control processing, which will be described later. Next, at step 2500-1, the CPUSC of the sub-control board S executes V winning detection effect display control processing, which will be described later. Next, at step 2900, the CPUSC of the sub-control board S executes a special game-related display control process, which will be described later. Next, at step 2550, the CPUSC of the sub-control board S executes a small-hit game-related display control process, which will be described later. Next, at step 2999, the CPUSC of the sub-control board S executes the display command transmission control process (transmits the commands set by these series of subroutines to the sub-sub control unit SS side), and ends this repeat processing routine. do.

As described above, the CPUSC of the sub-main control unit SM adopts a mode of loop processing the sub-main side routine (S2400-1 to S2999) after resetting. Further, the process of FIG. 4(c) is the process when the sub-main control unit SM is interrupted, and the signal from the STB signal line in the main control board M is transmitted to one terminal of the CPU of the sub-main control unit SM. In the example, it is the processing flow (c) in the case of being connected to the NMI terminal). That is, when an NMI interrupt occurs in the sub-main control unit SM (when the STB signal line is turned on), at step 2004, the CPUSC of the sub-control board S receives the command input port from the main control board M side (described above). Check the input port of the data signal line that has been connected). In step 2006, the CPUSC of the sub-control board S temporarily stores the command sent from the main control board M in the RAM area of the sub-main control unit SM based on the confirmation result, and immediately before this interrupt processing. return to the process that was being executed.

In this example, it is configured as a loop process that repeatedly executes the repetitive process routine (b) of the CPUSC of the sub control board S, but the process is not limited to this, and the process (b) is executed at predetermined time intervals. It is also possible to configure with timer interrupt processing.

Next, FIG. 54 is a flowchart of the pending information management process related to the subroutine of step 2400-1 in FIG. First, in step 2402-1, the CPUSC of the sub control board S has received a command (holding information relating to the first main game symbol or the second main game symbol) related to the occurrence of a new hold from the main control board M side. determine whether or not In the case of Yes in step 2402-1, in step 2404-1, the CPUSC of the sub-control board S sets the binding hold counter value (in this example, a maximum of 4 for the first main game and a maximum for the second main game 4) is added to "1". Next, in step 2406-1, the CPUSC of the sub-control board S temporarily stores the pending information (random value, etc.) transmitted from the main control board M side in the RAM area of the sub-control board S, and step 2418- 1.

On the other hand, if No in step 2402-1, the CPUSC of the sub-control board S determines whether or not it has received a symbol variation display start instruction command from the main control board M side in step 2410-1. If Yes at step 2410-1, at step 2412-1, the CPUSC of the sub control board S subtracts "1" from the drawing suspension counter value. Next, in step 2414-1, the CPUSC of the sub-control board S deletes the pending information (random number, etc.) related to the pattern variation from the RAM area of the sub-control board S, and shifts the remaining pending information. . Next, at step 2416-1, the CPUSC of the sub-control board S turns on the design content determination permission flag, and proceeds to step 2418-1. It should be noted that even if No in step 2410-1, the process proceeds to step 2418-1.

Next, at step 2418-1, the CPUMC of the main control board M lights and displays the same number of pending display images as the setting pending counter value on the effect display device SG, and the next process (step 2700-1 process).

Next, FIG. 55 is a flow chart of the decorative pattern display content determination process according to the subroutine of step 2700-1 in FIG. First, at step 2702-1, the CPUSC of the sub control board S determines whether or not the design content determination permission flag is ON. In the case of Yes at step 2702-1, at step 2704-1, the CPUSC of the sub control board S turns off the design content determination permission flag. Next, at step 2706-1, the CPUSC of the sub-control board S refers to the temporarily stored symbol information (stop symbol/variation mode related to the main game symbol) and the lottery table for determining the details of the variation of the design. , Stop symbols of decorative symbols {For example, when the stop symbols related to the main game symbols are jackpot symbols, doubles such as "7, 7, 7", and when they are losing symbols, "1, 3, 5" and the like} and the mode of variation are determined and temporarily stored in the RAM area of the sub-control board S.

Next, at step 2712-1, the CPUSC of the sub control board S turns on the design content determination flag, and proceeds to the next process (process of step 2800). Note that even if No in step 2702-1, the process proceeds to the next process (process of step 2800).

Next, FIG. 56 is a flow chart of the decorative design display control process related to the subroutine of step 2800 in FIG. First, at step 2802, the CPUSC of the sub control board S determines whether or not the design content determination flag is ON. In the case of Yes in step 2802, in step 2804, the CPUSC of the sub control board S turns off the design content determination flag. Next, at step 2806, the CPUSC of the sub-control board S turns on the symbol-fluctuation flag. Next, at step 2809, the CPUSC of the sub-control board S starts the design variation time management timer, and proceeds to step 2810. It should be noted that even if No in step 2802 , the process proceeds to step 2810 .

Next, at step 2810, the CPUSC of the sub-control board S determines whether or not the symbol-fluctuation flag is ON. In the case of Yes in step 2810, in step 2811, the CPUSC of the sub control board S confirms the timer value of the design variation time management timer. Next, in step 2812, the CPUSC of the sub-control board S determines whether or not the decorative pattern variation start timing has been reached based on the design variation time management timer and the variation mode temporarily stored in the RAM area of the sub-control board S. determine whether or not In the case of Yes in step 2812, in step 2814, the CPUSC of the sub control board S sets a command to display the variation of the decorative pattern on the effect display device SG (in the display command transmission control process of step 2999, sub-sub control (transmitted to the SS side), and the process proceeds to step 2832.

On the other hand, in the case of No in step 2812, in step 2816, the CPUSC of the sub control board S stops the decorative design based on the design variation time management timer and the variation mode temporarily stored in the RAM area of the sub control board S. It is determined whether or not the display timing (temporary stop display timing) has been reached. In the case of Yes in step 2816, in step 2818, the CPUSC of the sub control board S sets a command to display the stop display (temporary stop display) of the decorative pattern on the effect display device SG (display command transmission control in step 2999). in processing, it is transmitted to the sub-sub control unit SS side), and the process proceeds to step 2832 .

On the other hand, in the case of No in step 2816, in step 2824, the CPUSC of the sub-control board S displays the preview image and reach based on the design variation time management timer and the variation mode temporarily stored in the RAM area of the sub-control board S. It is determined whether or not the image display timing has been reached. In the case of Yes in step 2824, in step 2826, the CPUSC of the sub control board S sets a command to display the image display related to the preview image and reach image on the effect display device SG (in the display command transmission control process of step 2999). and transmitted to the sub-sub-controller SS side), and the process proceeds to step 2832 . It should be noted that even if No in step 2824 , the process proceeds to step 2832 .

Next, in step 2832, the CPUSC of the sub-control board S determines whether or not the main game symbols are stopped and displayed (for example, information indicating that the main game symbols are stopped and displayed is received from the main control board M side). (determine whether or not the In the case of Yes in step 2832, in step 2834, the CPUSC of the sub control board S sets a decorative pattern stop display command (fixed display command) in the effect display device SG (sub-sub in the display command transmission control process of step 2999). transmitted to the control unit SS side). Next, at step 2836, the CPUSC of the sub-control board S stops and resets (clears to zero) the design variation time management timer. Next, at step 2838, the CPUSC of the sub-control board S turns off the symbol-changing flag, and proceeds to the next process (step 2500-1). Note that even if No in step 2810 or step 2832, the process proceeds to the next process (step 2500-1).

Next, FIG. 57 is a flow chart of the V prize detection effect display control process according to the subroutine of step 2500-1 in FIG. First, in step 2502-1, the CPUSC of the sub-control board S determines whether or not it has received a small hit execution start command (a command indicating that a small prize game has started) from the main side. In the case of Yes in step 2502-1, in step 2504-1, the CPUSC of the sub control board S issues a right-handed instruction effect {shooting a game ball toward the second big winning hole C20 during a small winning game (right-handed execution)} is set (transmitted to the sub-sub control unit SS side in the display command transmission control process of step 2999), and the process proceeds to step 2506-1. On the other hand, if the answer to step 2502-1 is No, the process also proceeds to step 2506-1. Next, in step 2506-1, the CPUSC of the sub control board S issues a V winning detection command from the main side (informs the player that a game ball has entered the V winning hole C22). It is determined whether or not a command for executing a V prize detection effect, which is an effect for making a game, has been received. In the case of Yes in step 2506-1, in step 2508-1, the CPUSC of the sub-control board S sets a command related to the V prize detection effect (transmitted to the sub-sub control unit SS side in the display command transmission control process of step 2999). be executed) and move to the next process. On the other hand, also in the case of No in step 2506-1, the process proceeds to the next process. In addition, since the V winning detection effect is an effect for notifying the player that a game ball enters the V winning hole C22 and then a special game is executed, the content of the effect is to congratulate the player. It is desirable that the content or the content of the effect notifying the player that the game is highly profitable.

Next, FIG. 58 is a flowchart of special game-related display control processing according to the subroutine of step 2900 in FIG. First, at step 2902, the CPUSC of the sub control board S determines whether or not the special game flag is off. In the case of Yes in step 2902, in step 2904, the CPUSC of the sub control board S determines whether or not a special game start display instruction command has been received from the main control board M side. In the case of Yes at step 2904, at step 2912, the CPUSC of the sub control board S turns on the special game flag. Next, at step 2914, the CPUSC of the sub-control board S displays the big win start display on the effect display device SG (appropriately displays according to the type of the big win), and proceeds to step 2920. It should be noted that even if No in step 2902 , the process proceeds to step 2920 .

Next, at step 2920, the CPUSC of the sub control board S sequentially displays the number of rounds, the number of prizes won, and the number of prize balls on the effect display device SG based on the game information sequentially transmitted from the main control board M side. Set a command to execute (which may be appropriately executed as necessary based on game characteristics, types of jackpots, etc.). Next, at step 2926, the CPUSC of the sub control board S determines whether or not a special game end display instruction command has been received from the main control board M side. In the case of Yes at step 2926, at step 2928, the CPUSC of the sub control board S sets a command to display the end of the big win on the performance display device SG (performs appropriate display based on the type of big win). Next, at step 2929, the CPUSC of the sub-control board S zeroes the number-of-balls-entering counter (counter for measuring the number of balls entering the right general winning hole during the special game). Next, at step 2930, the CPUSC of the sub control board S turns off the special game flag, and proceeds to the next process (step 2550 process). Note that even if No in step 2904 or step 2926, the process proceeds to the next process (process of step 2550).

Next, FIG. 59 is a flowchart of a small-hit-game-related display control process according to the subroutine of step 2550 in FIG. First, in step 2552, the CPUSC of the sub-control board S determines whether or not the flag during the small hit is off. In the case of Yes in step 2552, in step 2554, the CPUSC of the sub control board S determines whether or not it has received a small hit start command from the main side. In the case of Yes in step 2554, in step 2558, the CPUSC of the sub-control board S sets a command related to the small hit start display (transmitted to the sub-sub control unit SS side in the display command transmission control process of step 2999). .

Next, at step 2562, the CPUSC of the sub-control board S turns on the small hit medium flag, and proceeds to step 2564. It should be noted that even if No in step 2552 , the process proceeds to step 2564 . Next, at step 2564, the CPUSC of the sub-control board S determines whether or not it has received a small hit end command from the main side. In the case of Yes in step 2564, in step 2566, the CPUSC of the sub-control board S sets a command related to the small hit end display (transmitted to the sub-sub control unit SS side in the display command transmission control process of step 2999). . Next, in step 2568, the CPUSC of the sub-control board S turns off the flag during a small hit, and proceeds to the next process (process of step 2999). Note that even if No in step 2554 or step 2564, the process proceeds to the next process (process of step 2999).

(action)
Next, with reference to FIG. 60, the action of winning to the V winning opening C22 in this embodiment will be described. First, in the figure, when a hold related to a small hit occurs, the opening of the upper shielding member C24 is calculated based on the number of holds at the time of determining the fluctuation time, and the opening of the upper shielding member C24 after the hold related to the small win occurs. FIG. 10 is a working diagram illustrating the relationship between the time until the game starts (hereinafter sometimes simply referred to as "upper shielding member opening arrival time") and the ease with which a ball can enter the V winning opening C22. . Incidentally, in this example, a case is exemplified in which a hold related to a small hit occurs during a certain symbol variation in which there are two holds related to a loss. In this example, the order of consuming the reserves is "first reserve->second reserve->third reserve" (the third reserve is a reserve related to a small prize). In the following, the time from the occurrence of the third suspension (=reservation related to the small hit) to the end of the pattern variation during variation is the same (2 seconds), and the start of the pattern variation of the first suspension It is assumed that the timing and the random values of the variation mode determination random numbers for the first to third suspensions are the same.

First, when a hold related to a small hit occurs during a pattern variation in which there are two holds related to a loss, the third hold (= hold related to a small win) occurs in the upper shielding member opening arrival time. The time from to the end of the pattern fluctuation during fluctuation; the fluctuation time of the first reservation; the fluctuation time of the second reservation; the fluctuation time of the third reservation (=holding related to the small hit); to the time when the upper shielding member C24 starts to open, and ;

Next, while referring to the table in the upper part of the same figure, during the pattern variation in which there are two retentions related to losing (first retention and second retention), the third retention (=retention related to the small hit) is Under the situation that occurred, as pattern A, when the shooting of the game ball is stopped after the occurrence of the third suspension (= suspension related to the small hit) {especially after the third suspension (= suspension related to the small hit) is when a new hold does not occur} and the shielding member opening arrival time, and as pattern B, when the game ball is continued to be launched after the occurrence of the third hold (= hold related to the small hit) {especially, the third When a new hold occurs after a hold (=hold related to a small hit) occurs} and the upper shielding member opening arrival time are exemplified.

In pattern A, no new suspension occurs after the third suspension (= suspension related to the small hit) occurs, and when the fluctuation time related to the first suspension is determined, the number of suspensions is 2 {second suspension and second 3 hold (= hold for small hit)}, and when the variable time for the second hold is determined, the number of holds is 1 {3rd hold (= hold for small hit)}, and the third hold (= The number of reservations becomes 0 at the time of determination of the variable time related to the reservation related to the small hit. In this case, referring to the lottery table for determining the first main game variation mode in FIG. 29, the time from the occurrence of the third suspension (=retention related to the small win) to the end of the symbol variation during variation is 2 seconds. The variation time of the first suspension is 5 seconds; The variation time of the second suspension is 10 seconds; The variation time of the third suspension (= suspension related to the small hit) is 60 seconds; The time from the start to the opening of the upper shielding member C24 is 5 seconds; therefore, the time to reach the opening of the upper shielding member is 82 seconds.

Next, in pattern B, after the occurrence of the third suspension (=reservation related to the small win), two new suspensions occur after the start of the symbol variation of the first suspension and before the start of the symbol variation of the second suspension. In the case, when the variable time related to the first hold is determined, the number of holds is 2 {second hold and third hold (= hold related to the small hit)}, and the number of holds when the variable time is determined for the second hold There are 3 {third hold (= hold related to small hit) and two new holds}, and when the variable time related to the 3rd hold (= hold related to small win) is determined, the number of holds is 2 (the newly occurring two pending). In this case, referring to the lottery table for determining the first main game variation mode in FIG. 29, in pattern B, from the occurrence of the third suspension (=retention related to the small win) to the end of the symbol variation during variation. The time of the first suspension is 2 seconds; The variation time of the first suspension is 5 seconds; The variation time of the second suspension is 5 seconds; The variation time of the third suspension (= suspension related to the small hit) is 60 seconds Yes; the time from the start of the small winning game to the start of opening the upper shielding member C24 is 5 seconds;

Here, as described above, the ease with which a ball can enter the V winning opening C22 (whether or not a game ball can enter the V winning opening C22) depends on the opening timing of the upper shielding member C24 and the opening timing of the lower shielding member C25. is a good match or not. That is, by referring to the opening arrival time of the upper shielding member and the opening timing of the lower shielding member C25, it is possible to determine whether or not it is easy to enter the ball into the V winning opening C22 during the small winning game according to the patterns A and B. It is possible to determine in advance whether

Next, the lower part of the figure shows the open mode (closed mode) of the upper shielding member C24 and the open mode (closed mode) of the lower shielding member C25 in each of the pattern A and the pattern B (the lower shielding member C25 is a power source). It repeats opening and closing periodically from the time of turning on.) is a timing chart showing . In this timing chart, the elapsed time from the third suspension (=retention associated with the small hit) occurrence timing is illustrated with reference to the third suspension (=retention associated with the small hit) occurrence timing. In addition, as the opening mode (closing mode) of the lower shielding member C25, the elapsed time from the timing of occurrence of the third suspension (= suspension related to the small hit) is "4n+1 (seconds)" to "4n+2 (seconds)" (n is an integer).

As shown in this timing chart, in pattern A, the timing at which the opening of the upper shielding member C24 is started is the timing when 82 seconds have elapsed from the timing of the occurrence of the third suspension (= suspension related to the small hit), Taking into account the time (0.2 seconds in this example) required for the game ball to reach the lower shielding member C25 from the position of the upper shielding member C24, the result is 82.2 seconds. " to "4n+2 (seconds)" (n is an integer). Therefore, the opening timing of the upper shielding member C24 and the opening timing of the lower shielding member C25 do not match, and the game ball placed on the upper shielding member C24 falls due to the opening of the upper shielding member C24. , When reaching the lower shielding member C25, the lower shielding member C25 is not opened, so it becomes difficult for the ball to enter the V winning opening C22 located downstream of the lower shielding member C25 (V Entry of the ball into the prize winning opening C22 is likely to be hindered). On the other hand, in pattern B, the timing at which the opening of the upper shielding member C24 is started is the timing when 77 seconds have passed since the timing of occurrence of the third hold (=holding related to the small hit), and the game ball is placed on the upper shielding member C24. When the time (0.2 seconds in this example) to reach the lower shielding member C25 from the position of is added, it becomes 77.2 seconds. " (n is an integer) (n=19). Therefore, the opening timing of the upper shielding member C24 and the opening timing of the lower shielding member C25 match, and the game balls placed on the upper shielding member C24 fall down when the upper shielding member C24 is opened. Since the lower shielding member C25 is opened when the lower shielding member C25 is reached, it becomes easier for the ball to enter the V winning opening C22 located downstream of the lower shielding member C25 (the game ball may Entry of the ball into the V winning opening C22 is difficult to be inhibited). Incidentally, in the case of the pattern A and the pattern B, the above-described shooting continuation instruction effect is executed.

As described above, in the present embodiment, as pattern A, a new hold does not occur from the occurrence of the hold related to the small hit to the start of the symbol variation related to the small hit (the number of holds is 2 or more Pattern variation is difficult to start in this state (the time from the occurrence of a hold related to a small hit to the start of opening of the upper shielding member C24 tends to be long); A new suspension occurs from the occurrence of the suspension to the start of the symbol variation related to the small hit (the number of suspensions is always maintained at 2 or more, and the symbol variation is easy to start = small hit The opening timing of the upper shielding member C24 may change in the case where the time from the occurrence of the suspension to the start of the opening of the upper shielding member C24 tends to be shortened. Furthermore, it is possible to change whether or not the opening timing of the upper shielding member C24 matches the opening timing of the lower shielding member C25 according to such a change in the opening timing of the upper shielding member C24. It is possible to provide a game machine with high interest such that attention is paid to whether or not the ball enters the V winning hole C22 when winning a small prize.

In addition, in this embodiment, based on the holding variation mode determination random number that exists at the time when the holding related to the small hit occurs, all the variable times that can be executed corresponding to the holding number at the time of holding consumption are confirmed. , based on the result, the time from the occurrence of the hold related to the small win to the start of opening the upper shielding member C24 is calculated in advance, and the calculated result, the opening timing of the lower shielding member C25, (Furthermore, the time required for the game ball to reach the lower shielding member C25 from the position of the upper shielding member C24 is taken into consideration), in the small hit game, the ball can be easily entered into the V winning opening C22. (The opening timing of the upper shielding member C24 and the opening timing of the lower shielding member C25 are matched). It becomes possible. In this way, when a ball can be entered into the V winning opening C22 during execution of the small winning game related to the reservation when the reservation to be a small win occurs, the combination of the variable time that allows the ball to enter. It may be configured so that the player can be notified of the shooting mode of the game ball that is likely to become (or a change in the desired number of reservations) as an effect, and by configuring in this way, the game to the V winning opening C22 in the small winning game It is possible to create novel playability that whether or not the ball will enter the ball can be determined by the player's technical intervention.

In addition, in this embodiment, depending on the number of reservations when determining the fluctuation time of the main game pattern, by configuring so that the determined fluctuation time can be different, after the reservation that becomes a small hit occurs. The time until the shielding member C25 is opened can be changed to allow the player to technically intervene, but the time from when a small hit is held to when the lower shielding member C25 is opened cannot be changed. The configuration that can be changed by the player's technical intervention is not limited to this. For example, (1) when the player presses down, the main game symbols are forcibly stopped and the stop symbols are displayed. A different variation shortening button is provided, and the time is varied according to the timing of pressing the button. (2) Both the first main game symbols and the second main game symbols are simultaneously executed A parallel lottery that can be drawn (and can be changed) can be executed, and when the stop pattern related to the second main game pattern becomes a small winning pattern, the small winning game related to the small winning pattern The period during execution may be configured such that the variation time (elapse of variation time) of the first main game symbols is temporarily stopped, and the time is varied.

In this embodiment, when a predetermined condition (for example, a specific small winning symbol is stopped, etc.) is satisfied, a game ball can enter the V winning opening C22 during execution of the small winning game. Effect that notifies the player of the timing of launching a game ball (for example, on the effect display device SG, a message such as "If you enter a specific ball hole now, you have a great chance to enter the V winning hole!" display) can be executed.

In addition, as a specific game state, there is a probability variable game state in which the winning/failure lottery result is advantageous to the player compared to the non-probability variable game state, and a round in which the second big winning opening C20 is opened during the special game. It may be configured to have a distribution game execution round, and by entering a ball in the V winning opening C22 during the distribution game execution round, it may be configured to shift to the probability variation game state after the special game ends. . In addition, in the case of such a configuration, in the round before the distribution game execution round, the game ball launch timing is set so that the game ball can enter the V winning opening C22 in the distribution game execution round. It is desirable to be configured so as to be able to execute an effect to notify the player (for example, display on the effect display device SG, "If you enter the second big prize hole now, you will have a big chance to change the probability!" etc.). .

(Configuration of memory map)
Next, with reference to FIG. 61, the configuration of part of the memory map in the RAM of the main control board M applicable to the pachinko game machine according to this example will be described in detail. In the area shown in the figure, from the upper address,
(1) "Set value data": Area for storing information related to set values (number data for managing set values, etc.) (2) "External signal system data": Information related to external signal output Area for storage (3) "RAM checksum data": data used in the checksum calculation process executed when the power is turned on, which is calculated from the data stored in the RAM when the power is turned off. and an area (4) "control command buffer" for storing information for calculating a specific value (for example, "0") in the checksum calculation process executed when the power is turned on: transmitted to the sub control board side (5) "stack pointer temporary storage buffer": Information used when power is restored. Area for storing information to be stored in the stack pointer when returning from interruption (6) "Unused area": Area for storing areas not used for games (7) "Save data 1 to save data 8": CALL instruction , PUSH instruction, etc., the maximum amount of data to be saved may be written to RAM
area is used in the order of In this configuration, the highest address indicated by the stack pointer is designed to be "7FF8H". There is a possibility that the stack pointer points to the address of In that case, there is a possibility that the saved data will be stored beyond the area of "saved data 1 to saved data 8" that has been secured as an area for data to be saved in advance. In consideration of such a situation, the address (address close to "7FF8H") that may be indicated by the stack pointer in the event of the unexpected failure is data that does not affect the progress of the game (there is little impact). data). Specifically, by providing an address for storing "set value data" at an address that is at least one address away from "saved data 1 to saved data 8" secured as an area for data to be saved in advance, the game It is possible to provide a game machine that does not disadvantage not only players but also game parlors. In the figure, (5) "stack pointer temporary storage buffer" is data that is not used while the game is in progress after the power has been restored, and (4) "control command buffer" (3) "RAM checksum data" can be used while the game is progressing after the power has been restored. (2) "external signal system data" is data to be transmitted to the hall computer, and therefore has little effect on the progress of the game. On the other hand, (1) "set value data" is information related to set values that affect the outcome of the game. occurs. As described above, (1) "set value data" is important data for the normal progress of the game. For this reason, in (1) to (7) in the same figure, (1) "set value data" is the highest order data (data stored at the upper address). In other words, (2) "external signal system data", (3) "RAM checksum data , (4) 'control command buffer', (5) 'stack pointer temporary storage buffer', and (6) 'unused area'. (2) "external signal system data", (3) "RAM checksum data", (4) "control command buffer", (5) "stack pointer temporary storage buffer", (6) "unused area" There is no problem even if the order of the addresses where the five data are stored is changed. Alternatively, the data may be stored in the order of "(6)→(5)→(3)→(2)→(4)" from the upper address. In addition, (6) "unused area" may not be provided.

In addition, in the area for storing the above-mentioned "set value data" (area (1) shown in FIG. 61), the set value data is held by supplying power from the backup power supply even when the power is cut off. . A backup power supply for holding this "set value data" can be provided in the power supply unit E or a relay board provided between the power supply unit E and the main control board M. The backup power source for holding the "set value data" is a board having a CPU such as the main control board M, sub-control board S (sub-main control part SM and sub-sub control part SS), prize ball payout control board KH, etc. is not installed. With this configuration, the set value data is always cleared when the control board in which the set value data is stored is replaced, and unauthorized replacement of the control board can be suppressed. Of course, only the area storing the setting data can be backed up by the backup power supply.

Here, it is also preferable to back up the area storing the set value data and another area, or the RAM storing the set value data and the other RAM, respectively, with separate backup power supplies. With this configuration, it is possible to improve the storage reliability of important set value data.

(Description of how to change settings)
Next, a setting change method will be described. First, each device will be described, then the functions to be changed in settings will be described, and finally, a specific procedure for changing settings will be described.

≪Set value display device≫
First, the setting value display device will be described. The gaming machine according to this example includes a set value display device on the main control board M for displaying set values to be set when changing settings. The setting value display device is a 7-segment display device, and the display of "1" to "6" makes it possible to determine six levels of setting 1 to 6. In this example, an example in which the set value display device is provided separately from the ball entry state display device J10, the RAM clear button, etc. has been described, but the present invention is not limited to this, and the setting value display device is set using the ball entry state display device J10. A value may be displayed. In this case, both the setting value and the base value are displayed on the ball entry state display device J10. may be configured to display the base value. It is also possible to keep the base value displayed during the setting change mode. can be considered. Furthermore, by changing the display mode of the entering state display device J10, both the set value and the base value may be displayed simultaneously in 4-digit 7-segment. For example, of the 4-digit 7-seg, the most significant digit may display the current set value, and the remaining 3 digits may display the base value.

≪Change target≫
In this example, the winning probability of the lottery for the main game symbols in one game state can be changed. Although different from the present embodiment, for example, 6 stages of setting 1 to 6 are provided, and in the order of setting 1 to setting 6, the probability of winning the jackpot in each of the probability fluctuation gaming state and the non-probability fluctuation gaming state gradually increases. In addition, the winning probability of the probability variable gaming state for each setting is configured to be twice the winning probability of the non-probability variable gaming state. there is Specifically, the winning probability of the non-probability variation gaming state is set 1: 1/320 (205/65536), set 2: 1/318 (206/65536), set 3: 1/317 (207/65536) , Setting 4: 1/315 (208/65536), Setting 5: 1/314 (209/65536), Setting 6: 13312 (210/65536). 1: 1/160 (410/65536), setting 2: 1/159 (412/65536), setting 3: 1/158 (414/65536), setting 4: 1/158 (416/65536), setting 5: 1/157 (418/65536), setting 6:1/156 (420/65536). In addition, the winning probability of the winning lottery of the main game pattern includes the winning probability of the small win, and the winning probability of the small win is regardless of the set value and the game state (variable probability game state, non-variable probability game state). It is constant (for example, 1/99). It should be noted that the winning probability of the probability variable gaming state is within 10 times the non-probability variable gaming state, that is, setting 1: 1/30.7, setting 2: 1/30.3, setting 3: 1/ 29.9, setting 4: 1/29.5, setting 5: 1/28.0, and setting 6: 1/27.0.

The RAM area in this embodiment has a setting value storage area (specific area) and other game data storage areas (for example, main game side random numbers, round numbers, etc.), and the setting value storage area is , are configured to be stored in upper addresses of the RAM area. If a setting is changed by the setting key switch and there is an error in the RAM area, the entire RAM area, including the setting value storage area, is cleared (initialized). When the RAM is cleared by operation, the memory area for setting values is not cleared, and only the data in other game data memory areas are cleared (initialized). Also, an example has been described in which the set value is stored at the start address of the RAM area for the purpose of facilitating designation of the clear range when clearing the RAM, but there is no problem in storing the setting value at any address in the RAM area. Also, a storage area may be provided that is not cleared even when a setting change is executed and there is an abnormality in the RAM area. The information related to the display on the entering state display device J10 may be configured not to be cleared.

≪Timing of confirmation of set value data≫
Next, confirmation processing of set values at the time of lottery will be described. Confirmation processing of the set value at the time of the lottery is performed before step 1410-1 during the main game symbol display processing of step 1400 in the processing at the time of timer interruption, confirms the currently set set value, and is set. This is the process of setting the main game table 1 corresponding to the set value (that is, the winning probability of the big hit corresponding to the setting described above). After confirming the setting value at the time of the winning lottery, at step 1410-1, the CPUMC of the main control board M refers to the main game table 1 corresponding to each game state, and determines the first main game content determination random number ( Based on the second main game content determination random number) (particularly, the winning lottery random number), the main game pattern winning lottery is executed. In addition, when checking the currently set setting value, the setting value is out of range (1) Unrecoverable error that cannot be recovered without executing RAM clear processing when changing settings (unrecoverable to the situation immediately before the error occurred) (2) The set value may be determined as setting 1, which is most disadvantageous to the player.

In addition, although the structure which confirms a setting value for every special symbol lottery process was demonstrated, it is also possible to perform only at a predetermined timing. Specifically, the information may be checked only once when the settings are changed and when the power is turned on, or may be checked at each change timing of the game state such as a big win. Also, in the case of a game machine equipped with the ball entry state display device J10, confirmation may be made in accordance with the display timing or calculation timing. As a result, the timing of checking the setting value can be reduced, and the load on other processes can be reduced.

<<Processing while changing settings>>
Next, processing during setting change will be described.

<Processing on the main control side>
First, the CPUMC of the main control board M is configured to be able to display that the setting is being changed on the special symbol display device (first main game symbol display device A20, second main game symbol display device B20). Specifically, during the setting change, all the LEDs of the special symbol display device are turned on. It should be noted that it is desirable that all the LEDs of the special symbol display device are lit up in such a manner that they are not displayed during the game of the player. Also, if it is possible to indicate that the setting is being changed, it is not always necessary to use a special symbol display device, and for example, various LEDs provided on the game board surface may be used. However, at this time, if the same lighting pattern as the notification related to various functions normally performed at the time of power failure recovery (power failure recovery notification, RAM clear notification, etc.) is performed, the notification mode will be confused and the setting will be changed. Since there is a concern that it may not be possible to clearly determine that the setting is being changed, it is desirable to notify the user with a lighting pattern that is executed only during the setting change. In this case, by switching to the notification regarding various functions after the setting change is completed, it is possible to make it visually easy to understand that the setting change has been changed to the normal power failure recovery state. Also, by providing a dedicated LED and processing it to display only during setting change, various LEDs {special symbol display device and normal symbol display device (auxiliary game symbol display device H20)} that display other game information It is possible to reduce the processing load compared to using .

<Processing on the sub-control side>
Next, the CPUSC of the sub-control board S is configured to be able to suggest that the settings are being changed by means of the effect display device SG, the speaker D24, and the like. Specifically, the effect display device SG is configured to display an image of "Settings are being changed", and the speaker D24 is configured to output a voice of "Settings are being changed". Also, during the setting change, the game data unrelated to the main game (not controlled by the CPUMC of the main control board M) can be changed. For example, setting of volume change (possible or impossible), setting of RTC (real time clock), setting of energy saving mode {playing standby (playing standby when it is determined that the game has not been executed for a predetermined period of time, for example, When the shooting handle is not operated for 5 minutes, it is in game standby, and during game standby, the standby demonstration screen is displayed on the effect display device). is lowered}, and these changes can be made by operating the sub-input button SB or the cross key. Moreover, you may substitute input devices, such as not only this but a touch panel. In this case, in addition to the liquid crystal display used for the main game as the effect display device, it is desirable to provide another liquid crystal display for performing only sub-inputs and use it as a touch panel. The RTC (real time clock) is a mechanism for measuring time provided on the board of the sub-main control section. The RTC (real-time clock) has a built-in power source (battery) that is independent of the board, and keeps time even when power is not supplied to the game machine. - Based on the time, it is possible to supply the current date and time.

<Input restrictions>
Next, input restrictions during setting change will be described. Specifically, in the process of step 1003 (setting change process), it is configured not to detect the entry of a ball into the starting port (first main game starting port A10, second main game starting port B10). For example, even if the input signal is input to the input port by detecting the input by the first main game start entrance detection device (A11s) or the second main game start entrance detection device (B11s), Since the CPUMC of the main control board M does not permit timer interrupt processing, it does not check the input port. However, it is configured to enable error detection such as door open detection and magnet detection. Therefore, by making it possible to detect errors such as door open detection and magnet detection in the main processing (setting change processing) on the main control board side, it is possible to prevent fraudulent behavior during the setting change process. is.

<External output>
Next, the information that the CPUMC of the main control board M outputs to the outside will be described. As the information that the CPUMC of the main control board M outputs to the outside, 1. setting value;2. It is possible to output a signal indicating that the setting is being changed. In this embodiment, 1. external output of set values;2. Information indicating that the setting is being changed is configured to be output from the main control board M to the hall computer. The signal indicating that the setting is being changed is continuously output during the setting change, and is configured to continue to be output until a predetermined time (for example, 1000 ms) elapses after the setting change is completed. Further, the CPUMC of the main control board M is configured to transmit a setting value command, a setting change start command, and a setting change end command to the CPUSC of the sub control board S and the CPU of the prize ball payout control board.

<Payment processing>
Next, a description will be given of the processing when the power is turned off during the payout process and then the settings are changed. Specifically, when power is cut off while prize balls are being paid out in the prize ball payout unit KE10, the power is turned off while the number of remaining prize balls is backed up in the RAM area. . When the power is restored, the number of remaining prize balls is still stored in normal power restoration (that is, RAM is not cleared). If the power is restored when the power is turned on, the entire RAM area, including the storage area for the set values, will be cleared, so the number of remaining prize balls that was backed up will also be cleared. Even if the power is cut off during the putting out, the number of remaining prize balls will not be put out when the power is restored. Although not shown, when the setting change mode is entered, the CPUMC of the main game board M notifies the prize ball payout control board KH (the CPU of the prize ball payout control board) that the setting change mode has been entered. A command (sometimes referred to as a setting change start command) is transmitted, and when the setting change mode ends, a command indicating that the setting change mode has ended (sometimes referred to as a setting change end command) is transmitted. . It should be noted that the number of remaining prize balls may be cleared after the setting change is effective.

<Random number update process>
In this embodiment, the random number update process is not performed while the settings are being changed. That is, the random number is updated by updating the random number in step 1018 of the main processing on the main control board side, or step 1000-2 (various random number updating processing), step 1000-3 (initial value updating type random number updating processing), or step 1000-3 of the timer interrupt processing. This is only performed in step 1000-4 (initial value random number update process), and the process of updating the random number is not provided in the setting change process.

≪Display during setting confirmation≫
Next, the display during setting confirmation (sometimes referred to as setting confirmation state or setting display) will be described.

<Display on the main control side>
First, on the main control side, as described above, the LEDs of the special symbol display devices (first main game symbol display device A20, second main game symbol display device B20) are configured to be able to display that the settings are being changed. However, even during setting confirmation, the LEDs of the special symbol display devices (first main game symbol display device A20, second main game symbol display device B20) are configured to be able to display that the setting is being confirmed. , All the LEDs of the special symbol display device are configured to blink during setting confirmation. It should be noted that it is desirable that the mode in which all the LEDs of the special symbol display device flash and display is a mode that is not displayed during the player's game (the mode that is displayed during the player's game is, for example, A certain LED and another LED are blinking alternately). Also, when the setting is being confirmed during the fluctuation of the special symbols, the fluctuation display of the main game symbols on the special symbol display device (first main game symbol display device A20, second main game symbol display device B20) is It is configured to be displayed with priority over the display of setting values.

<Display on the sub-control side>
Next, during the confirmation of the setting, on the side of the sub-control board S, the effect display device SG displays the image "Confirming the setting", and the speaker D24 outputs the voice "Confirming the setting". It should be noted that during the setting change (sometimes referred to as a setting change mode or setting change mode), game data unrelated to the main game (not controlled by the CPUMC of the main control board M and not affecting the game result) is changed. Although it is configured to be changeable (maintenance mode), even game data that is not related to the main game (not controlled by the CPUMC of the main control board M and does not affect the game result) can be changed during the setting confirmation. It is configured so that it is not possible and is configured not to be in a configurable state. In addition, it is desirable to set the output time according to the importance of other errors that extend the output time (for example, the importance of setting change notification is higher than that of initialization notification, and the is 5000 ms, the setting may be changed to a longer time of 6000 ms).

<Restrictions on input information>
Next, restrictions on input information will be described. As described above, input information is restricted during setting change, but input information is not restricted during setting confirmation. Specifically, the main control side (main Regardless of the control by the CPUMC of the control board M) or the sub-control side (control by the CPUSC of the sub-control board S), all information related to the game is detected and processed.

<External output>
Next, external output during setting confirmation will be described. First, for setting values that are to be externally output during setting change, they are configured not to be externally output during setting confirmation. Next, while the settings are being checked, a signal indicating that the settings are being checked is continuously output. Further, it is configured to continuously output until a specific time (for example, 500 ms) after the completion of setting confirmation, and is configured to output for a time shorter than the predetermined time (for example, 1000 ms) during setting change.

<Payment processing>
Next, prize ball payout control during setting confirmation will be described. First, when the prize balls are being paid out by the prize ball payout device KE, the prize ball payout control is temporarily interrupted when the setting is being checked. The setting can be confirmed by a game clerk or the like by opening the game machine frame and using the setting key switch from the back side of the game machine. In other words, by opening the game machine frame, there is a possibility that the ball supply device on the parlor side will not normally supply the balls to the game machine. Therefore, it is preferable to temporarily suspend the payout of prize balls. Although not shown, when the payout of prize balls is temporarily interrupted, the CPUMC of the main game board M shifts to the setting confirmation state of the prize ball payout control board KH (the CPU of the prize ball payout control board). A command indicating that the setting confirmation state has ended (sometimes referred to as a setting confirmation start command) is transmitted, and when the setting confirmation state ends, a command indicating that the setting confirmation state has ended (sometimes referred to as a setting confirmation end command) is transmitted. It is

<Internal processing such as random number update processing>
Next, internal processing such as random number update processing during setting confirmation will be described. The random number update process is not performed during the setting change, but the random number update process and the like are performed during the setting confirmation process in the same manner as during the game.

<<Processing when the power is restored>>
Next, the processing at the time of power failure recovery will be described.

<Normal power failure recovery>
First, if the settings are not changed and the RAM is not cleared when the power is restored, the game state including the set values is restored to the state before the power was turned off, and the game is started.

<Processing when changing settings>
Next, processing when changing settings will be described. When changing settings, all data in the RAM area including the set values are cleared, and then the set values are stored. In addition, when clearing the data in the RAM area other than the set values, the range for clearing the RAM may be changed according to the game state at the time of power failure, such as the state of the main game pattern or the auxiliary game pattern. is also possible. Specifically, when the RAM is cleared while the main game symbols are in the probability variation state, both the set value data and the state data of the main game symbols (probability variation, non-probability variation, etc.) are cleared, and the main game symbols are non-probability. When the RAM is cleared in the variable state, the set value data is cleared and the state data of the main game symbols are not cleared. Further, the auxiliary game symbols may be configured in the same manner as the main game symbols, and furthermore, it may be configured so that the RAM clearing range is varied depending on the combination of the state of the main game symbols and the state of the auxiliary game symbols. good. By configuring in this way, it is possible to reduce the processing load when clearing the RAM.

<Processing when clearing RAM>
Next, the processing when clearing the RAM will be described. When the RAM clear button is operated, game data other than the set values are cleared. In addition, in RAM clearing when there is an abnormality in the RAM area, all the data in the RAM area including the set values are cleared.

<<Command transmission timing>>
Next, in this embodiment, the command is transmitted in the control command transmission process in step 1999 in the timer interrupt process. , the CPUMC of the main game board M sends a command for starting the setting change mode (setting change start command) to the prize ball payout control board KH (CPU of the prize ball payout control board) immediately after the setting change mode is started. is transmitted, and immediately after the setting change is completed, a command for ending the setting change (setting change end command) is transmitted. Also, at the start of the game (for example, the timing of transmitting the fluctuation start command), at the end of the game (for example, the timing to stop the fluctuation stop command), at the time of pending occurrence (for example, the read-ahead pass/fail command and the read-ahead fluctuation mode, which will be described later) A command related to the setting value may be transmitted from the main control board M to the sub control board S at a timing such as command stop timing. At this time, the sub-control board S stores the received set value, compares it with the set value received in the next game, and notifies if there is a discrepancy, thereby preventing illegal actions during the game. It can also facilitate discovery of configuration changes.

≪Summary of processing related to setting change≫
As described above, the processing related to the setting change has been described, and the summary is as follows. First, in a situation where the setting is being changed, the main control means (for example, the CPUMC of the main control board M), the effect control means (for example, the CPUSC of the sub-control board S) and the payout control means (for example, the prize ball payout A command (setting change start command) indicating that the process during setting change in the main control means is to be executed is transmitted to the CPU of the control board KH), and the random number update process related to the success or failure, the starting opening sensor, etc. game-related input, for example, low-priority abnormality notification such as ball tray full (error that the sensor that detects the full tank detects game balls due to excessive game balls being stored in the upper ball tray D20) prevent it from happening. Further, the main control means outputs a signal indicating that the setting is being changed from the external terminal. It should be noted that high-priority anomaly notifications {for example, anomalies directly linked to fraud (magnetic detection, radio wave detection, etc.)} are also notified during setting changes. On the other hand, the production control means notifies that the settings are being changed, shifts to maintenance mode, and executes test output in the production control means, various production settings, setting of the effective range of player operation, etc. configured to allow Also, the payout control means is configured to prohibit both the payout process and the shooting process.

If the power is turned off while an error with a low priority or an error with a high priority is occurring (during detection), and the power is turned off, the setting key switch is turned on to turn on the power. When the change mode is entered and the setting value is changed in the setting change mode (when the setting value is confirmed), the detection and error notification of the low-priority error or high-priority error that has occurred will be terminated. may be configured. Further, even in such a configuration, if an abnormality is detected again after changing the setting value, the error detection and error notification may be performed. In addition, when an abnormality with a low priority is detected during the setting change mode, it may not be judged as an error and error notification may not be executed. is detected, the error notification may not be executed without judging that there is an error.

In a situation where the set value is being displayed on the set value display device, the main control means indicates to the effect control means and the payout control means that the main control means will execute the process during which the set value is being displayed. While sending a command (setting display command), the same processing as usual, such as update processing of random numbers related to win/fail, game-related input such as a start opening sensor, and abnormality notification, is performed. However, a signal indicating that the set value is being displayed is output from the external terminal. Similarly, the effect control means also notifies that the setting value is being displayed, but does not shift to the maintenance mode. The payout control means temporarily interrupts the payout process, but does not prohibit the operation of the shooting process.

Since it is configured as described above, in this embodiment, taking into account the fact that the setting change is based on the operation performed only by the administrator, the effect control means (for example, the CPUSC of the sub control board S) also requires the administrator to In addition, the main control means (for example, CPUMC of the main control board M) and the payout control means (for example, CPU of the prize ball payout control board KH) stop the game function. That is, when an operation that can be executed only by the administrator is executed in the other control means as well, a dedicated process is executed, and the process executed in normal game progress is not executed. Therefore, starting from one operation of changing the setting, a plurality of control means can execute corresponding management processes. On the other hand, during the confirmation work of setting display (setting confirmation state), by configuring so as to maintain normal game processing as much as possible, proper processing is realized without imposing unnecessary restrictions on control. be able to.

(How to change settings)
Next, FIGS. 62 and 63 are transition diagrams showing a setting change method using the setting key switch and the RAM clear button. The setting change method is performed according to the following procedure.
(1) A game clerk or the like releases the front frame D14 from the outer frame D12.
(2) When the game clerk opens the front frame D14, if the power switch Ea of the gaming machine is off, the setting key switch is off, and the RAM clear button is off, the next procedure is performed. If the power switch Ea of the gaming machine is on or the setting key switch is on, it is turned off to proceed to the next procedure.
(3) A game clerk or the like turns the setting key switch to the right to turn it on, turning on the RAM clear button.
(4) When the game clerk or the like turns on the power switch Ea, the game machine shifts to the setting change mode, and the set value is displayed on the set value display device. At this time, the setting value display device may be configured to display a default setting value (for example, setting 1 with the lowest jackpot probability), or may be configured to display the currently set setting value. good too. Also, in order to make it possible to grasp that the mode is the setting change mode, a configuration may be adopted in which a voice saying "setting is being changed" is output.
(5) Once the RAM clear button is turned off (6) Each time the game clerk presses the RAM clear button (every time it is turned on from off), the set value (set value data, sometimes referred to as set value candidate) ) is changed to the next set value (set value data), and the set value (set value data) is displayed on the set value display device. In the same figure, the setting value 1 is incremented by 1 and changed to the setting value 2, but the settings are jumped (for example, setting 1 → setting 3 → setting 5, setting 2 → setting 4 → setting 6, etc.). Even if it is configured, it is preferable to configure it so that the next set value (for example, set value 1 is changed to set value 3). Also, if the game clerk or the like presses the setting change button once, the setting may be decremented by -1. In this case, setting 6 is preferably the setting with the lowest jackpot probability, and the default setting value is preferably 6. Furthermore, characters or symbols that can be displayed on the set value display device of the 7-segment display may be used as settings, such as L (LOW) or H (HIGH). Here, display of setting values and selection candidates of setting values can be changed, and the setting is determined when the determination condition is satisfied. That is, the display of the setting value display device displays "1" when the mode is shifted to the setting change mode, and each time the setting change button is operated, the display switches to "1→2→3→1→2". The setting value is set (fixed) to 2 when the confirmation condition is satisfied when the display of the setting value display device is "2".
(7) The game clerk turns the setting key switch to the left to turn it off, thereby confirming the setting (ending the setting change mode), and the setting value displayed on the setting value display device of the game machine disappears. erased. It should be noted that the setting value may be displayed until a predetermined time (for example, 5 seconds) has elapsed after the setting is confirmed.
(8) Close the front frame D14. It should be noted that the configuration may be such that the game can be executed when the setting is confirmed, or the game can be executed when the front frame D14 is closed.

(Setting confirmation method)
Next, FIG. 64 is a transition diagram showing a setting confirmation method using the setting key switch and the RAM clear button. The setting confirmation method is performed according to the following procedure.
(1) A game clerk or the like releases the front frame D14 from the outer frame D12.
(2) The power switch Ea of the gaming machine is off, the setting key switch is off, and the RAM clear button is off.
(3) (4) When a game clerk turns the setting key switch to the right to turn it on and turns on the power switch Ea, the gaming machine shifts to a setting confirmation mode (also called a setting display mode). , the current set value is displayed on the set value display device. At this time, in order to make it possible to grasp that it is in the setting confirmation mode, it may be configured to output a sound "Confirming settings". is not output (the output of the game sound is stopped), and only the sound "Checking settings" is output, or the game sound and "Checking settings" are output at the same time. It is good also as a structure.
(5) When the game clerk or the like turns off the setting key switch, the game machine terminates the setting confirmation mode, and the display of the setting value displayed on the setting value display device is erased. At this time, the configuration may be such that a voice saying "The setting confirmation is finished" is output.
(6) The game clerk or the like closes the front frame D14. In the setting confirmation mode, since the progress of the game (variation of special symbols, etc.) is continued without being paused, even if the front frame is closed during the variation of the special symbols, the effect display device SG Variation of decorative patterns and effect display are continued. In the setting confirmation mode, the progress of the game may be temporarily stopped. In this case, when the setting key switch is turned on, the setting confirmation mode is entered, the progress of the game is temporarily stopped, and the setting key switch is turned on. When it is turned off, the setting confirmation mode is terminated, the temporary stop is released, and the game continues to progress. Here, when shifting to the setting confirmation mode, unlike the case of shifting to the setting change mode, the probability state is maintained in the state immediately before shifting to the setting confirmation mode.

Next, FIG. 65 is a diagram showing an example of a display mode on the effect display device SG during setting change and setting confirmation.

Next, the upper part of the figure is an image diagram showing a list of items that can be set during the maintenance mode executed by the sub control board S during the setting change process. In this example, by transmitting a command indicating that the setting change mode has been entered from the main control board M side, it is indicated that the setting is being changed on the main control board M side, and the sub control board S side It is configured so that a maintenance mode (a mode for store settings and manufacturing confirmation) can be executed. In this example, during the maintenance mode, the effect display device SG displays a setting display image SGSHG (in this example, an image showing the current setting value "4") for guiding the current setting value. configured to do so. Further, as shown in the figure, in the case of the setting change mode, the effect display device SG displays a setting change mode information display image SGHMH (an image for notifying that the setting is currently being changed). In the example, it is configured to be able to display an image displaying "in setting change mode").

As shown in the figure, in this example, a plurality of items can be selected as various settings related to information output during the maintenance mode. More specifically, in this example, during the maintenance mode, a shipping test mode (for example, a mode for executing a test of the light emitter, sound, liquid crystal display device, input confirmation, etc.) is executed (the shipping test mode , a series of actions may be completed, or, for example, by pressing and holding the sub-input button to return to the main screen, etc.), advertisement content setting {that is, at a specific timing such as the demo screen It is a setting of whether or not to display an advertisement, and a setting of specific advertisement content (for example, store name, etc.) in the case of displaying an advertisement], enabling or disabling the power saving mode (that is, during game standby, etc.) It is a setting whether to automatically shift to the energy saving mode or not), selection of valid or invalid of the RTC effect (a effect that is executed when a predetermined time is reached) (a setting of whether to perform the RTC effect, all may be set uniformly, or a plurality of RTC effects may be set individually), selection of whether or not to display the set value in the setting confirmation state {that is, the current setting of the game machine A setting display mode (display setting), which is a mode in which values can be displayed on the effect display device SG, and a setting display mode (non-display setting), which is a mode in which the current setting values of the gaming machine are not displayed on the effect display device SG. }, selection of enabling or disabling the player's volume setting, and selection of enabling or disabling the player's light intensity setting (in a normal state other than the maintenance mode, the player presses the sub-input button , a cross key, etc., to set whether or not to enable volume setting and light intensity setting). Also, when the end of the maintenance mode is selected, or when the setting change is finished (for example, based on the fact that a command indicating return from the setting change mode (end of the setting change mode) is received from the main control board M side) ) The maintenance mode is ended, and a predetermined screen such as a demo screen, normal screen, or dedicated screen is displayed.

In this example, an item is selected by operating the cross key, and the content to be changed is determined by pressing the sub-input button. Further, the effect display device SG is configured to be able to display a button operation information image SGHMB (an image for explaining button operation in the maintenance mode). In addition, at the bottom of the setting change display area (for example, the effect display device SG), there is a caption SGHMJ that suggests and guides the end condition of the maintenance mode (in this example, "Maintenance mode will be forcibly terminated when the setting change is completed. ” subtitle) is scrolled. The caption SGHMJ may be displayed when "end of maintenance mode" is selected with the cross key, or may be displayed all the time during the maintenance mode. In addition, not only subtitles SGHMJ, but also predetermined text information, voice information, etc. may be used to suggest/guidance of conditions for ending the maintenance mode, etc., or such guidance/suggestion may not be performed. Alternatively, the maintenance mode may be automatically terminated based on the fact that the sub-input button or cross key has not been operated for a predetermined period of time. It may be configured to notify that the time (less than the predetermined time) has not been reached and the remaining time until the maintenance mode is automatically terminated.

Next, an example of a display screen during setting confirmation will be described. In the middle part of the figure, the sub-control board S side is in a game standby state (a state in which no pattern variation is being executed and there is no hold), and the setting display mode in the above-described maintenance mode is changed to the setting display mode (display setting). ), and is an image diagram displayed when the main control board M side is confirming the settings. In this example, by transmitting a command indicating that the main control board M side has shifted to the setting confirmation mode, the sub control board S side indicates that while the main control board M side is confirming the settings. It is configured so that display can be executed.

In this example, the setting display image SGSHG exists in front of the image related to the demo screen displayed in the game standby state (that is, the setting display image SGSHG has priority over the image related to the demo screen). The visibility of the display of the setting display image SGSHG is not hindered depending on the image of the demonstration screen). Further, in this example, at the bottom of the demonstration screen display area (for example, effect display device SG), subtitles SGSMJ (in this example, "set display mode (Display setting is in progress. Remove the setting key to return to normal mode.") is scrolled.

Note that the device that notifies that the setting is being changed or is being displayed (setting is being confirmed) is not limited to the effect display device SG, and that it is being changed or is being displayed (setting is being confirmed) The apparatus may be configured so that the game parlor side can select whether or not to notify that the setting is being changed or the setting is being displayed. For example, the amusement arcade side can choose not to report if it is to prevent the possibility of the setting information being leaked by the clerk, and to make it to be reported if it is to prevent the clerk from changing the setting. It is also possible to configure whether or not to notify that the setting is being changed or the setting is being displayed (setting confirmation) is changed depending on the time zone. Specifically, the RTC is mounted on the sub-control board S, and the time zone (or When the time data of the RTC is within the set time range, the setting managed by the CPUSC of the sub-control board S is being changed or the setting is being displayed (setting is being checked). ) is not notified (or is notified). By configuring in this way, it is possible to set the notification to be performed during business hours when the setting confirmation and setting change are not performed, and to set the notification not to be performed after the store is closed. By doing this, the purpose of preventing fraud by notifying fraud during business hours and the purpose of suppressing suggestions that cleaning staff and part-time workers have changed settings after business hours are at the same time. can be fulfilled. Note that the above setting may be configured so that only conspicuous notification such as notification by voice can be set, or a device that performs notification (not notification) can be selected.

Specifically, if it is desired to always notify that the setting is being changed or is being checked, the setting is set so as to "perform conspicuous notification for 24 hours" (that is, there is no time for inconspicuous notification). Thereby, it is possible to perceive that setting change or setting confirmation is being performed at any time. Also, if you want to prevent other game clerks from detecting that the person in charge of the game store is changing or checking settings outside business hours (that is, if you want to prevent information leakage from the inside), It is set to "perform conspicuous notification from 9:00 to 23:00" (perform inconspicuous notification from 23:00 to 9:00). As a result, the person in charge of the game parlor can secretly change or confirm the setting by giving an unobtrusive notice to the setting change or setting confirmation performed outside business hours. Furthermore, if it is established as an operation of the game store that the person in charge of the game store changes or confirms the setting before business hours, 5:00 to 9:00), the timing of regular setting change or setting confirmation is stipulated more limitedly, so unauthorized setting change or setting confirmation outside the limited time Configuration checks can be strictly suppressed. Conversely, if it is established as an operation of the amusement arcade that the person in charge of the amusement arcade changes or confirms the setting after business hours, for example, ``make a conspicuous notification between 5:00 and 23:00'' (inconspicuous A similar effect can be obtained by setting the notification to be performed from 23:00 to 5:00. Needless to say, since the business hours differ for each amusement arcade, it is desirable to appropriately set the hours according to the business hours and operations of each amusement arcade, not limited to the exemplified hours.

(Example of how to change settings)
In this example, the game machine has a plurality of set values (three set values in this example), but the correspondence between the operation mode of the setting keys and the change in the set values of the game machine can be freely designed as appropriate. It is possible. For example, if the number of setting values in this example is 6 (the setting value is one of "1" to "6") and the setting value at power-on is "6", press the setting key once. When the setting key is operated, the setting value becomes "5", and when the setting key is operated three times, the setting value becomes "3". (Similarly, the setting value may be moved up sequentially from "1" to "6" according to the number of times the setting key is operated). Also, in this case, when the setting value is "1" and the setting key is operated once, the setting value becomes "6". The set value may be configured to shift to the upper limit value when operated. Similarly, according to the number of times the setting key is operated, the setting value is incremented. The value may be configured to transition to the lower limit (“1” in this example). Alternatively, the setting values may be changed sequentially by pressing the operation button for a long time.

The number of setting values can be freely designed as appropriate, for example, two, three, four, five, six, or the like. The smaller the number of set values (for example, when the number of set values is two or three), the more interesting the game based on having a plurality of set values is and the simpler the configuration of the game machine is. The greater the number of setting values (for example, when the number of setting values is 5 or 6), the more interesting the game can be.

(Example of change related to setting change)
Next, examples of changes related to setting changes are listed below.
≪Amusement machines that do not require setting changes≫
In the present embodiment, an example was described in which the probability of success or failure of special symbols is changed for each set value. In some cases, providing a function (setting change means) does not make much sense. However, when developing a game machine, it is not desirable from both a hardware and software standpoint to separately design a game machine equipped with a setting change means and a game machine without a setting change means. In order to reduce development costs, it is necessary to develop game machines with a wide variety of specifications using the same software and hardware configurations as much as possible. Therefore, an example of how to handle the setting change means in a gaming machine that does not require setting changes will be listed below. By configuring in this way, it is possible to develop a game machine with the same software and hardware configuration as a game machine that does not require the setting change means, even if the game machine does not require the setting change means. In addition, it is not necessary that the hardware and software configurations be the same between the game machine that does not require the setting change means and the game machine that does use the setting change means. There is no problem even if there is a design change.
<1 step setting>
A set value that can be changed by the setting change means is set to one type. As a result, the process of switching the setting value remains the same (for example, even though the setting change mode is entered, the setting value is not changed from "1" even if the setting change switch is operated). Similarly, it is possible to realize specifications similar to those of gaming machines that do not require setting changes. In this case, since there is only one type of numerical value that can be used as the setting value, by displaying "1" as the setting value data on the setting value display device, it is made to recognize that the processing for displaying the setting is being performed. It does not matter if it is displayed or not. Also, if the sub-control board is equipped with a process for displaying information about the set values, the default value (for example, "setting 1") may be sent, or the actual set values exist. You can send a command not to. When a command indicating that the setting value does not exist is transmitted, it is desirable that the sub-control board receives the command and displays that the setting value does not exist.
<Common setting value>
All setting values that can be changed by the setting changing means are set as the same setting value. Specifically, when using 6-level settings (settings 1 to 6), for example, by treating all setting values as "1", the same setting value is used regardless of which setting value is selected. can be done. This makes it possible to achieve the same specification as the one-step setting without changing the setting value switching process. When reading the set value data, the data of the set value "1" is stored in the ROM address corresponding to each of the settings 1 to 6, and the set value "1" is read from the address corresponding to the selected set value. data may be read out, or data of the setting value "1" may be stored at an address common to setting 1 to setting 6. FIG. At this time, it is conceivable that the set value display device displays the set values "1" to "6" according to the operation of the set key, but the set value "1" is displayed regardless of which operation is performed. is preferable for machines that do not require setting changes, thereby avoiding misunderstandings when confirming setting values.
<Software processing that does not refer to set values>
The setting values stored in the RAM (the setting values selected by the setting changing means) are not referred to in processing. Specifically, in the case of a gaming machine that adopts set values, when referring to the win-or-fail probability table when drawing lots for special symbols, the set values stored in the RAM as the selected set values are referred to. Select the success/failure probability table corresponding to the set value. At this time, by omitting the process of referring to the set values from the RAM and determining one predetermined win-or-fail probability table, it is possible to realize specifications similar to those of gaming machines that do not require setting changes.
<Software processing that refers to set values>
The software processing that does not refer to set values has been described above as a game machine that does not require setting changes. This is not the case. Regardless of which set value data the selected set value is, the same right/wrong probability table is determined. As a result, there is no setting difference due to the set value.
<Identification flag>
A flag is provided to distinguish between a gaming machine that requires a setting change and a gaming machine that does not require a setting change, and the flag is determined at a predetermined trigger such as a game start timing to perform processing in the gaming machine that changes the setting; To change processing in a game machine that does not require setting change. In the process when the power is turned on, the flag stored in the ROM of the main control board M is referred to before the process of step 1001 is performed. It is conceivable to proceed to the processing of step 1002 without performing any processing. In this case, software changes may occur, but at least hardware changes may not occur.
<Set number of settings>
Select the number of settings to use for setting changes. For example, three types of setting, 1-step setting, 3-step setting, and 6-step setting, are designed so that they can be appropriately selected according to game specifications. Specifically, a method of setting according to the rotational position of a setting key switch used when changing settings, and a method of selecting using an input switch such as a DIP switch are conceivable. As another means, as in the example using the identification flag, a flag indicating the number of selectable settings (1-step setting, 3-step setting, 6-step setting) stored in the ROM of the main control board M may be referred to before the process of step 1001 or before the process of step 1003-1 to enable selection of the set number. By using such a method, the specifications of current gaming machines can be divided into three types: gaming machines corresponding to 1-level setting, gaming machines corresponding to 3-level setting, and gaming machines corresponding to 6-level setting. Therefore, it is possible to easily select a process according to the set number. Further, as a result, it is possible to function as a game machine that does not require a setting change when one-step setting is selected and used, and when three-step setting and six-step setting are selected and used, the selected setting step is used. It can function as a game machine whose settings can be changed. Also, as in the example using the one-step setting above, if the sub-control board is equipped with a process for displaying setting information, a value indicating the number of settings selected (for example, "three-step setting") may be sent. As a result, the sub control board S notifies, according to the value received from the main control board M, "the currently selected setting is a three-step setting", etc., through the effect display device SG or the speaker D24. It can be carried out. Further, the configuration may not be such that the number of settings used for setting change can be selected, and the setting values to be used may be determined in advance according to the number of setting values, and the following configuration is also possible. For example, when the number of setting values is one, setting 6 (or setting 1) may or may not be preferentially used.
(1) 1 Use setting 6. Setting 1 may also be used.
(2) 2 Use setting 1 and setting 6.
(3) Three (3-1) Setting 1, setting 4 and setting 6 are used.
(3-2) Use setting 1, setting 3, and setting 6.
(3-3) Use setting 1, setting 2, and setting 3.
(3-4) Settings 4, 5, and 6 are used.
(3-5) Use setting 1, setting 2, and setting 6.
(3-6) Use setting 1, setting 5, and setting 6.
(4) 4 (4-1) Use setting 1, setting 3, setting 4, and setting 6.
(4-2) Settings 1, 2, 5, and 6 are used.
(4-3) Use setting 1, setting 2, setting 3, and setting 4.
(4-4) Settings 3, 4, 5, and 6 are used.
(4-5) Use setting 1, setting 2, setting 3, and setting 6.
(4-6) Settings 1, 4, 5, and 6 are used.
(5) Five (5-1) Setting 1, setting 3, setting 4, setting 5, and setting 6 are used.
(5-2) Settings 1, 2, 4, 5, and 6 are used.
(5-3) Use setting 1, setting 2, setting 3, setting 5, and setting 6.
(5-4) Settings 1, 2, 3, 4, and 6 are used.
(5-5) Settings 1, 2, 3, 4, and 5 are used.
(5-6) Use setting 2, setting 3, setting 4, setting 5, and setting 6.
<Others>
Functions related to setting changes (setting keys, etc.) are provided on the sub-board (power supply board, etc.) instead of the main control board, and in the case of game machines that do not require setting changes, signal input to the main control board You can choose not to do it. Specifically, there is a method that does not connect the harness between the sub-board with the function related to setting change and the main control board, and a method that does not send commands related to setting change from the sub-board to the main control board. method, etc. can be considered.

<<Configuration being checked>>
Configurations during setting confirmation applicable to the gaming machine according to this example are listed below. It should be noted that the configurations listed below are applicable to all of the above-described embodiments, and it is supplemented that there is no problem in appropriately combining one or a plurality of configurations (only when a plurality of setting values are provided).

<Action during setting confirmation>
During setting confirmation (setting confirmation state), the configuration may be as follows.
(1) Entry into the first main game start gate A10, second main game start gate B10, auxiliary game start gate H10, general winning gate, first big winning gate C10, second big winning gate C20 is invalid. Become (Only some ball entrances are invalid, and ball entrances to other ball entrances may be valid (2) 1st main game start port A10, 2nd main game start port B10, auxiliary game Entry of the ball into the starting hole H10, the general winning hole, the first big winning hole C10, and the second big winning hole C20 remains valid. (3) Operation of the shooting handle D44 becomes invalid (the game ball cannot be shot becomes)
(4) The operation of the shooting handle D44 remains valid (the game ball is not disabled to be shot).
(5) Error detection is executable, but error notification is not displayed on effect display device SG. Display an error notification at (7) Do not display the demo screen (do not shift to game standby state)
(8) Main game symbols (first main game symbol, second main game symbol) do not start changing (9) Auxiliary game symbols do not start changing

<Period during which settings cannot be confirmed>
In this example, it is configured so that turning on the setting key switch while the game machine is running allows the transition to the setting confirmation state. It may be configured so as not to shift to the confirmation state).
(1) Special game start demo time (2) Special game end demo time (3) Special game in progress (4) Main game symbols (first main game symbol, second main game symbol) fluctuating (5) Auxiliary game While the pattern is changing (6) During the operation of the normal electric accessory (for example, the second main game starter electric accessory) (7) During the specific effect (executing the effect related to RTC, etc.)
(8) During time reduction game state (9) During probability variation game state (10) During specific error (door open detection, magnet detection, etc.)

<When returning from checking settings>
In this example, it is configured to be able to return from the setting confirmation state by turning the setting key switch from ON to OFF in the setting confirmation state. ) may be configured as follows.
(1) The volume setting is set to the initial setting (2) The light intensity setting is set to the initial setting (3) The demo screen is displayed (shifts to the game standby state)

<<Configuration of setting change mode>>
Configurations of setting change modes applicable to the gaming machine according to this example are listed below. It should be noted that the configurations enumerated below are applicable to all the above-described embodiments, and it should be supplemented that there is no problem by appropriately combining one or a plurality of configurations (only when a plurality of setting values are provided).

<When power failure occurs during setting change mode>
If the power is interrupted while in the setting change mode and then recovered from the power interruption (if the setting key switch remains on),
(1) The setting change mode is restarted. (2) The setting change mode ends.
(3) Transition during setting confirmation By configuring as in (1) above, whether or not to transition to the setting change mode can be determined by checking the ON/OFF status of the setting key switch when the power is restored. It is possible to determine whether or not to switch to the setting change mode by a simple process.

<Action during setting change mode>
(1) Entry into the first main game start gate A10, second main game start gate B10, auxiliary game start gate H10, general winning gate, first big winning gate C10, second big winning gate C20 is invalid. (Only some entrances may be invalid, and other entrances may be valid (2) 1st main game start A10, 2nd main game start B10, auxiliary game Entry into the starting hole H10, the general winning hole, the first big winning hole C10, and the second big winning hole C20 remains valid. (3) The operation of the shooting handle D44 becomes invalid (the game ball cannot becomes)
(4) The operation of the shooting handle D44 remains valid (the game ball is not disabled to be shot).
(5) Error detection is executable, but error notification is not displayed on effect display device SG. Display an error notification at (7) Do not display the demo screen (do not shift to game standby state)
(8) Main game symbols (first main game symbol, second main game symbol) do not start changing (9) Auxiliary game symbols do not start changing

<When returning from the setting change mode>
The action when returning from the setting change mode may be configured as follows.
(1) The volume setting is set to the initial setting (2) The light intensity setting is set to the initial setting (3) The demo screen is displayed (shifts to the game standby state)

<Action 1 regarding setting confirmation state>
"A game ball was launched when the number of pending balls was 0 → The door unit D18 was opened while the game ball was flowing down the game area → The setting key switch was operated to enter the setting confirmation state → A game ball was released. 1st main game starting gate A10 -> 1st main game symbols start to fluctuate -> 1st main game symbols are jackpot symbols and stop display.
(1) The big win starts while the set value is displayed. (2) The set value remains displayed and the big win does not start. After that, when the setting key switch is operated and the setting confirmation state ends, the display of the set value disappears and the jackpot starts (3) An error occurs and the progress of the game is stopped. Alternatively, even if a game ball enters the first main game start port A10 (or the second main game start port B10) in the setting confirmation state, the entry may be invalidated. , A suspension based on the ball entry occurs, but the suspension may not be digested until the setting confirmation state is completed, and the symbol variation may not be started. It should be noted that even if the state is shifted to the setting confirmation state, the result of the game is not affected.

<Action 2 regarding setting confirmation state>
"A game ball was launched when the number of pending balls was 0 → The door unit D18 was opened while the game ball was flowing down the game area → The setting key switch was operated to enter the setting confirmation state → A game ball was released. 1st main game starting gate A10 ball entry → 1st main game symbols start to fluctuate → 1st main game symbols are small winning symbols and are stopped and displayed.
(1) A small win is started while the set value is displayed. (2) A small win is not started while the set value is displayed. After that, when the setting key switch is operated and the setting confirmation state is completed, the display of the set value is hidden and a small win is started (3) An error occurs and the progress of the game is stopped. good too. It should be noted that even if the state is shifted to the setting confirmation state, the result of the game is not affected.

<Action 3 regarding setting confirmation state>
"The game ball is launched → The door unit D18 is opened while the game ball is flowing down the game area → The setting key switch is operated to enter the setting confirmation state → The game ball enters the auxiliary game start opening H10 → Auxiliary game symbols start to fluctuate → Auxiliary game symbols win and stop displaying at the symbols”,
(1) The second main game starter electric accessory B11d (normal electric accessory) starts to open while the set value is displayed (2) The set value remains displayed and the second main game starter electric role is displayed The object B11d (normal electric accessories) does not start opening. After that, when the setting key switch is operated to end the setting confirmation state, the display of the set value disappears and the opening of the second main game start opening electric accessory B11d (normal electric accessory) is started. Since the game result is not affected even if the state is changed to the setting confirmation state, the game can be smoothly progressed by configuring as in (1) above.

<Action 4 regarding setting confirmation state>
In the case of "operating the setting key switch to check the settings → power failure occurs → power is restored while the setting key switch is on",
(1) Returns to the setting confirmation state based on the backup information at the time of power failure (2) Shifts to the setting change mode (3) Neither shifts to the setting confirmation state nor the setting change mode (then turns the setting key switch from off to on) If it is, the setting is being confirmed)
When the power is restored, it is determined whether the set value key switch is on, and if it is on, the setting change mode is entered. The configuration of (2) above is the most suitable because it can be determined.

<Action 5 regarding setting confirmation state>
In the case of "operate the setting key switch to confirm the settings → power failure occurs → turn off the setting key switch → turn the setting key switch back on to restore power",
(1) Returns to the setting confirmation state based on the backup information at the time of power failure (2) Shifts to the setting change mode (3) Neither shifts to the setting confirmation state nor the setting change mode (then turns the setting key switch from off to on) If it is, the setting is being confirmed)
When the power is restored, it is determined whether the set value key switch is on, and if it is on, the setting change mode is entered. The above configuration (2) is the most suitable because it can be determined.

<Action 6 regarding setting confirmation state>
In the case of "operate the setting key switch to check the settings → power failure occurs → turn off the setting key switch → restore the power while maintaining the state where the setting key switch is off",
(1) Neither transition to setting confirmation state nor setting change mode

(Example of changing the timing of setting change processing)
In this embodiment, after confirming whether or not the setting key switch is off in step 1001, if No, if the RAM clear button is on in step 1030, setting change processing is executed in step 1003. However, an initial setting process may be provided before step 1001, and the setting key switch confirmation and setting change process may be performed in the initial setting process. Specifically, in the initial setting process, first, each port and register are set, and then, if the setting key switch is turned on, the setting change process is performed.

(Example of random number range change related to setting change)
In this embodiment, the jackpot probability is changed according to the number of numerators of the random number, but it is also possible to change the jackpot probability by changing the number of denominators of the random number.

For example, first, at the time of non-probability variation game, in setting 1, the random number upper limit value of the winning lottery random number is 65535 at the time of non-probability variation game. Random numbers 0 to 204 (number 205) are set as big wins, and random numbers 205 to 65535 are set as losers. Next, in setting 2, the random number upper limit value of the winning lottery random number is 65501 during the non-probability variation game. Random numbers 0 to 204 (number 205) are set as big wins, and random numbers 205 to 65501 are set as losers. Next, in setting 3, the random number upper limit value of the winning lottery random number is 65301 during the non-probability variation game. As for random numbers, random numbers 0 to 204 (number 205) are set as big wins, and random numbers 205 to 65301 are set as losers.

Next, in the probability variation gaming state, in setting 1, the random number upper limit value of the winning lottery random number is 65535 at the time of probability variation gaming, as in setting 1 at the time of non-probability variation gaming. As for random numbers, random numbers 0 to 409 (number 410) are set as big hits, and random numbers 410 to 65535 are set as losers. Next, in setting 2, the random number upper limit value of the winning lottery random number is 65501 during the probability variation game, as in setting 2 during the non-probability variation game. As for random numbers, random numbers 0 to 409 (number 410) are set as big wins, and random numbers 410 to 65501 are set as losers. Next, in setting 3, the random number upper limit value of the winning lottery random number is 65301 during the probability variation game, as in setting 3 during the non-probability variation gaming state. As for the random numbers, random numbers 0 to 409 (number 410) are set as big wins, and random numbers 410 to 65301 are set as losers.

By configuring in this way, the difference in the winning probability due to the change in the set value is caused by the difference in the random number upper limit value under the same game state (for example, during the non-variable probability game, during the variable probability). Become. Therefore, while changing the winning probability for each setting, it is possible to share the determination table for the win/fail lottery, and reduce the necessity of executing individual processing for each set value in the look-ahead process and the win/fail lottery. .

(Embodiment of two-stage lottery)
Next, an embodiment in which the winning probability of the main game symbol is changed according to the set value will be described. This embodiment is characterized in that a two-stage lottery is performed based on the winning probability in the high-probability state (variable-probability gaming state).

For example, the first lottery random number table is 2050/65536 (1/31.969) for setting 1, 2100/65536 (1/31.208) for setting 2, and 2150/65536 (1/30.208) for setting 3. 482), and the second lottery random number table is 1/2.5 in common for all settings. That is, in this embodiment, the probability of winning (jackpot) in the normal gaming state (non-probability variable gaming state) is 1/79.92 (2050/65536×1/2.5) at setting 1, and 1/1 at setting 2. 78.02 (2100/65536×1/2.5), 1/76.20 (2150/65536×1/2.5) at setting 3, hit (jackpot) in high probability game state (probability variable game state) ) probability is the winning probability in the table of the first lottery random numbers, and is 1/31.969 for setting 1, 1/31.208 for setting 2, and 1/30.482 for setting 3. Therefore, in this embodiment, the probability change ratio between the normal game state and the high probability game state is 2.5 times in common for all set values.

As described above, by adopting two winning lottery random numbers as in the present embodiment, the winning probability during normal time (during non-probability variable gaming state) is determined on the premise that winning or losing is determined using random numbers within a predetermined range. is finely set, it is possible to obtain the effect that the winning ratio at the time of high probability (at the time of probability variable gaming state) can be completely the same for each setting.

(Another example of a two-step win-fail lottery)
In the above, the configuration has been described so as to implement a two-stage lottery based on the winning probability in the high probability state (probability variable gaming state). One determination table (one win-fail lottery table for low probability and one win-fail lottery table for high probability) is provided for each game state, and the lottery of the first stage (first lottery random number determination processing) is provided. ), it is also possible to perform a lottery using a different determination table for each set value.

Specifically, the table for the first lottery random number is 98/100 for setting 1, 99/100 for setting 2, and 100/100 for setting 3. Of these, the table for the low-probability state is 210/65536 (1/318.4) common to all settings, and the table for the high-probability state is 1001/65536 (1/65.5) common to all settings. In other words, the hit (jackpot) probability in the normal game state (non-probability variable game state) is 1/318.4 (98/100×210/65536) in setting 1, and 1/315.2 (99/100 in setting 2). × 210/65536), setting 3 is 1/312.0 (100/100 × 210/65536), and the hit (jackpot) probability in the high probability gaming state is 1/66.8 (98/100 × 1001/65536), setting 2 is 1/66.1 (99/100×1001/65536), and setting 3 is 1/65.5 (100/100×1001/65536). Therefore, the probability change ratio between the normal game state (low probability state) and the high probability game state is a common 1001/210 times (4.766... times) for all set values. That is, the ratio of the winning probability between the normal game state (low probability state) and the high probability state is the ratio between the low probability second lottery random number determination table and the high probability second lottery random number determination table. For this reason, it is extremely easy to set the ratio uniformly. The probability ratios can be the same.

It should be noted that, since whether or not a big hit is finally achieved depends largely on the parameter of the second lottery random number, it is also preferable to determine execution of the look-ahead effect based only on information regarding this parameter. More specifically, the actual winning probability (probability of finally winning the jackpot) is calculated by adding the winning probability of the first winning lottery random number and the winning probability of the second winning lottery random number. is set to be very high (98/100 even at setting 1), it depends greatly on the result of the second lottery random number. Therefore, in the look-ahead determination process for generating information indicating the degree of expectation of a big hit, the parameter of the second lottery random number is important.

For this reason, in the execution determination of the actual look-ahead effect (for example, the look-ahead processing of the sub-control board in this embodiment), in the process of determining whether the effect can be executed or not, the result of the second lottery random number It is preferable to set the degree of dependence of the information generated based on this high.

Specifically, when making step-by-step judgments using multiple random numbers, dependence on the information with the lower winning probability when deciding on the look-ahead effect (including whether to execute the look-ahead effect and the look-ahead determination process, etc.) It is preferable to increase the degree, so that the function of suggesting a hit by the anticipation effect can be appropriately achieved.

(Embodiment in which the jackpot probability at low probability differs depending on the setting value, and the high probability jackpot probability is common regardless of the setting value)
In a game machine (so-called ST machine) in which the probability variable game state ends depending on the number of times the main game pattern changes, the probability of continuation of the probability variable state is not constant due to the difference in the jackpot probability at the time of high probability. Therefore, it is preferable to use a common jackpot probability at the time of high probability regardless of the setting value.

For example, in the table referred to in the non-probability variable game state in the first main game win-fail lottery table (second main game win-fail lottery table), setting 1, The order of setting 2 and setting 3 is set. More specifically, the setting 1 winning (jackpot) winning probability in the non-probability variable gaming state is set to approximately 1/320, and the setting 2 winning (jackpot) winning probability in the non-probability variable gaming state. is set to approximately 1/318, and the winning probability of setting 3 in the non-probability variable gaming state is set to approximately 1/317. On the other hand, the first main game win/loss lottery table (second main game win/loss lottery table) is configured so that the winning (jackpot) winning probability is the same for any set value in the table referred to in the probability variable gaming state. It is More specifically, in all setting values of setting 1, setting 2 and setting 3, the winning (jackpot) winning probability is set to approximately 1/159 (412/65536).

It should be noted that, after the end of the big win, it is configured to shift to the probability variable game state regardless of the big win pattern related to the big win, and 80 times is set in the probability change number counter, in other words, the probability change number becomes 80 times. ing. In addition, since the jackpot probability in the probability variable gaming state is 412/65536, the probability of winning the jackpot in any of the 80 variations of the main game pattern, which is the probability variable number of times (sometimes referred to as the consecutive game probability), is
{1−(1−412/65536) ⁸⁰ }×100≈39.62(%)
, and even if the set values are different, the probability of consecutive residences is the same.

With the configuration as described above, there are three set values, setting 1, setting 2, and setting 3, as set values, and in a non-probability variable gaming state, the set values are different, so that the jackpot probability is different. By constructing the system so as to allow the player to play the game while guessing how advantageous the current set value is, it is possible to provide the player with novel amusement, and the probability of a big win in the probability variable game state. is set so that the same jackpot probability is obtained even if the set values are different, so that the probability variable game state is terminated by the number of times the main game pattern changes when the state shifts to the probability variable game state after the end of the special game. In a game machine with a variable probability, it is possible to prevent a situation in which the consecutive game probability in the probability variable game state differs depending on the set value, and the profit rate provided in the probability variable game state, which is an advantageous state for the player, is improved. It is possible to create a user-friendly gaming machine that does not differ depending on the gaming machine used.

(Overview of test terminals)
Here, the test terminals and the information output from the test terminals will be supplementarily described. Although it is not installed in gaming machines supplied to the market (game halls), it is equipped with connectors, buffer ICs, latch ICs, etc. dedicated to the output of test terminals only during testing, in order to facilitate various ball payout tests. (if there is no dedicated IC, only the connector is mounted), various information of the gaming machine can be output. Specifically, a test terminal mounting area is formed on the main control board M, and at the time of testing, 1 or By mounting (soldering) a plurality of buffer ICs and latch ICs (for example, 74HC244 and 74HC541) and connectors, predetermined game information can be output from the test terminals.

<Test terminal output information>
Next, the information output from the test terminals described above will be briefly described. As described above, the test terminal is intended to facilitate ball-out tests, etc., and is configured so as to be able to output information in real time as much as possible for grasping the status of winning balls and the progress of the game. In this embodiment, "out ball count", "touch state", "normal symbol operation gate", "first main game start port", and "second main game start port", which are signals input to the main control board M regarding games. "Normal winning mouth", "1st big winning mouth winning", "2nd big winning mouth winning" are output, and as signals related to abnormalities, "disconnection short circuit power supply abnormality detection signal", "door open signal", "magnetism detection signal", "radio wave detection"Signal" and "Impact detection signal" are output, and as signals related to the state of the gaming machine, "Condition device is in operation", "Accessory continuous operation device is in operation", "First main game symbol hit", "First main game symbol variation" is output. Medium""2nd main game symbol hit""2nd main game symbol fluctuating""1st main game high probability state""1st main game fluctuation time reduction state""2nd main game high probability state""2nd Main game fluctuation time shortened state "Auxiliary game symbol high probability state""Auxiliary game symbol fluctuation time shortened state""Auxiliary game open extended state""Special electric accessory in operation""1st large winning opening solenoid driven"" The 2nd big prize opening solenoid is being driven,” “assisting game symbol hit”, “auxiliary game symbol is changing”, “ordinary electric accessories are in operation”, “game machine error state” is output, and information about other symbols is “main game symbol”. 'symbol data' and 'symbol data of auxiliary game patterns' are output. Also, if a setting device (setting key switch, device related to setting value display and setting change) is installed, the operating state of the setting device (for example, in setting change mode or in setting display mode) (or) and set value information are also output, and when the ball entry state display device J10 is installed, information to be displayed on the display device is also output.

(ECO game machine)
In this embodiment, the player can touch the game balls from the ball tray (upper ball tray D20, lower ball tray D22) or the like. It may be configured such that the player cannot touch the game balls, and the game machine side (prize ball payout control board KH) manages the number of balls data and prize ball data possessed. Although simple, the basic structure of the front side of the pachinko game machine will be described with reference to FIGS. 66 and 67. FIG.

A major difference from this embodiment is the configuration of the ECO unit EU and the operation unit device 50 . Specifically, an ECO unit EU installed outside the pachinko game machine is provided, and various game information can be communicated between the pachinko game machine and the ECO unit EU. Further, the operation unit device 50 is provided with a ball number display device MU and an ECO unit operation panel ES. The number display device MU for the number of balls held and the ECO unit operation panel ES will be described in detail below with reference to FIG.

Next, FIG. 67 is a diagram showing details of the operation unit device 50 in FIG. First, the pitch number display device MU will be described. The number-of-balls display device MU is provided with a number-of-balls display unit 501, a settlement number setting display unit 502, an information display unit 503, a full settlement button 504, a partial settlement button 505, and a settlement unit number setting button 506. The unit operation panel ES is provided with a settlement completion display section 601, a replay button 602, a card balance display section 603, a lending button 604, a card return button 605, and a status display section 606.

The number-of-balls display unit 501 is composed of, for example, a 6-digit 7-segment LED, and can display up to "999,999" number of balls stored (held) on the gaming machine side. . The settlement number setting display unit 502 is composed of, for example, a 4-digit 7-segment LED, and can display up to "9,999" unit game ball counts when part of the number of owned balls is settled. By operating the upper button or the lower button of the settlement unit number setting button 506 arranged corresponding to each digit, it is possible to set the unit settlement number for each digit. The information display unit 503 is composed of an LED or the like that can display alphabetic characters (not shown), and when an error or the like occurs, it displays error information, payment confirmation, etc. ("Is it OK to pay?" display and audio output) are possible. Specifically, if there is an abnormality in communication between the prize ball payout control board KH and the number display unit 501, it is "E1", and if there is an abnormality in communication between the prize ball payout control board KH and the ECO unit EU Code information corresponding to the error such as "E2" is displayed. It should be noted that the number-of-balls-in-hand display unit 501 is preferably configured so that information other than the number of balls-in-hand (for example, error information, etc.) is not displayed. Note that the above number of digits is just an example, and there is no problem if it is changed.

The all settlement button 504 is composed of a mechanical switch or the like, and is a button to be operated when the game balls (held balls) stored (held) on the gaming machine side are settled. It is configured to be the largest among the devices MU. In order to prevent erroneous operations, it is preferable to configure the system so that the entire settlement process is performed by multiple operations. The partial settlement button 505 is configured by a mechanical switch or the like, and is a button that is operated when a portion of the game balls (held balls) stored (held) on the gaming machine side is settled. The operation surface is configured to be smaller than that of the total settlement button 504 . In order to prevent erroneous operations as in the case of the full settlement process, it is preferable to configure the partial settlement process to be performed by a plurality of operations.

Next, the ECO unit operation panel ES will be explained. For example, similarly to the number-of-balls display unit 501, the settlement display unit 601 is composed of 6-digit, 7-segment LEDs, and displays the number of balls of the player managed by the ECO unit as "999,999". ” can be displayed. The card balance display unit 603 is composed of, for example, a 3-digit 7-segment LED, and can display the balance (frequency) recorded in the IC card. The lending button 604 is, for example, a mechanical switch or the like, and is a button for operating when lending game balls within the range of the balance (frequency) recorded in the IC card. The card return button 605 is, for example, a button that is composed of a mechanical switch or the like and is operated when the player removes the IC card. The replay button 602 is, for example, a mechanical switch or the like, and is a button for enabling use of the paid game balls displayed in the paid game display section 601 when operated by the player. Controls corresponding to various button inputs provided on the ECO unit operation panel ES, display controls, and the like are performed by the control section on the ECO unit side. The status display section 606 is composed of, for example, an LED, and notifies that an error has occurred by lighting or blinking when a communication error occurs between the ECO unit EU and the ECO unit operation panel ES.

Next, with reference to FIGS. 68 and 69, functional block diagrams relating to the main control board and payout control board (prize ball payout control board) will be illustrated. In addition, the dotted line indicates the power supply route from the capacitor at the time of power failure (to maintain the data of the RAM of the main control board and the RAM of the payout control board at the time of power failure).

<Configuration 1>
In configuration 1, the power supply board and the payout control board are connected by a harness 1, and the power supply board is connected to the payout control board (a board that executes control for giving game values such as game medals, game balls, and points). is configured to supply power to In addition, a CPU is provided on the board of the main control board and on the board of the payout control board. In the same figure, the ROM and the RAM are built in the CPU, but it is not limited to this. may be set to Moreover, the payout control board and the main control board are connected by a harness 2, and power can be supplied from the payout control board to the main control board. Also, a capacitor is provided on the board of the payout control board. In addition, the capacitor can store power, and even if the power supply from the power supply board to the payout control board stops, the power stored in the capacitor will supply power from the payout control board to the main control board for a certain period of time. (when harness 2 is connected). Therefore, the data stored in the RAM built in the CPU on the payout control board and the data stored in the RAM built in the CPU on the main control board, the power supply from the power supply board to the payout control board is maintained by the power supplied from the capacitor even if the

<Configuration 2>
In configuration 2, the power supply board and the payout control board are connected by a harness 3, and the power supply board is connected to the payout control board (a board that executes control for giving game values such as game medals, game balls, and points). is configured to supply power to the Further, a CPU is provided on the board of the main control board and on the board of the payout control board. In the same figure, the ROM and RAM are built in the CPU, but this is not a limitation, and the CPU, ROM, and RAM are separated on the board of the payout control board or the board of the main control board. may be set to Moreover, the payout control board and the main control board are connected by a harness 4, and power can be supplied from the payout control board to the main control board. In the payout control board case, the board of the payout control board and the sub board provided with the capacitor are connected by a floating connector or the like. The capacitor can store power and is configured to store power from the power supply board via the payout control board. In addition, even if the power supply from the power supply board to the payout control board is stopped, the power stored in the capacitor will supply power to the sub board → payout control board → main control board for a certain period of time (harness 4 is connected). Therefore, the data stored in the RAM built in the CPU on the payout control board and the data stored in the RAM built in the CPU on the main control board, the power supply from the power supply board to the payout control board is maintained by the power supplied from the capacitor on the sub-board even if the

<Configuration 3>
In configuration 3, the power supply board and the payout control board are connected by a harness 5, and the power supply board is connected to the payout control board (a board that executes control for giving game values such as game medals, game balls, and scores). is configured to supply power to In addition, a CPU is provided on the board of the main control board and on the board of the payout control board. In the same figure, the ROM and the RAM are built in the CPU, but it is not limited to this. may be set to Moreover, the payout control board and the main control board are connected by a harness 6, and power can be supplied from the payout control board to the main control board. In the payout control board case, the board of the payout control board and the sub board provided with the capacitor are connected by a floating connector or the like. The capacitor can store power and is configured to store power from the power supply board via the payout control board. Even if the power supply from the power supply board to the payout control board is stopped, the power stored in the capacitor will supply power for a certain period of time from the sub board to the payout control board and from the sub board to the main control board. becomes (when the harness 6 and the harness 7 are connected). Therefore, the data stored in the RAM built in the CPU on the payout control board and the data stored in the RAM built in the CPU on the main control board, the power supply from the power supply board to the payout control board is maintained by the power supplied from the capacitor on the sub-board even if the

<Configuration 4>
In configuration 4, the main control board and the power supply board are connected by a harness 8, and power is supplied from the power supply board to the main control board. Also, a CPU is provided on the board of the main control board. A payout control board (a board that executes control for giving game values such as game medals, game balls, and points) and a power supply board are connected by a harness 9, and power is supplied from the power supply board to the payout control board. configured to be supplied. Also, a CPU is provided on the board of the payout control board. In addition, the payout control board and the sub-board (a board for backing up the information stored in the RAM of the payout control board) are connected by a harness 10, and power can be supplied from the sub-board to the payout control board. It is In addition, the main control board and the payout control board are connected by a harness 11, and are configured to be able to transmit and receive commands in both directions. A capacitor is provided on the sub-board. The capacitor can store power and is configured to store power from the power supply board via the payout control board. In addition, when the power supply from the power board to the payout control board is stopped, the power stored in the capacitor provided on the board of the sub board is configured to supply power to the payout control board for a certain period of time. (when harness 10 is connected). In addition, even if the power supply from the power supply board to the main control board and the payout control board is stopped, the power stored in the capacitor provided on the board of the subboard will cause the sub board → payout control board → for a certain period of time. Power is supplied to the main control board (when the harness 10 and the harness 11 are connected). In the figure, the power supply board is configured to be able to directly supply power to the payout control board, but the present invention is not limited to this, and the power supply board and the sub-board 2 (the same as the sub-board described in the same paragraph can be used without any problem). ) may be connected by a harness so that electric power can be supplied in the order of "power board→sub-board 2→payout control board". In configuration 4, a sub-board B connected to the main control board with a harness may be provided, and in such a configuration, a capacitor may be provided on the substrate of the sub-board B. .

<Configuration 5>
In configuration 5, the main control board and the power supply board are connected by a harness 13, and power is supplied from the power supply board to the main control board. Also, a CPU is provided on the board of the main control board. Also, the main control board and the sub board (a board for backing up the information stored in the RAM of the main control board) are connected by a harness 12, and power can be supplied from the sub board to the main control board. It is A capacitor is provided on the sub-board. The capacitor can store power, and even if the power supply from the power supply board to the main control board stops, the power stored in the capacitor will continue to supply power from the sub board to the main control board for a certain period of time. (when the harness 12 is connected). A payout control board (a board that executes control for giving game values such as game medals, game balls, and points) and a power supply board are connected by a harness 14, and power is supplied from the power supply board to the payout control board. configured to be supplied. Also, a CPU and a capacitor are provided on the board of the payout control board. In addition, the main control board and the payout control board are connected by a harness 15, and are configured to be able to transmit and receive commands in both directions. In addition, the capacitor can store electric power, and the payout control board having the capacitor can supply the power stored in the capacitor to the payout control board for a certain period of time even if the power supply from the power supply board to the payout control board is stopped. Power is supplied. In addition, in the same figure, although it was configured such that power can be directly supplied from the power supply board to the main control board and the payout control board, it is not limited to this. For example, a power supply board and a sub-board 2 (the same as the sub-board described in the same paragraph can be the same) are connected by a harness, and electric power can be supplied in the manner of "power supply board→sub-board 2→main control board". You may Similarly, the power supply board and the sub-board 3 (the same sub-board described in the same paragraph is acceptable) are connected by a harness, and power can be supplied in the manner of "power supply board → sub-board 3 → payout control board". may be configured. Configuration 5 may be applied to an enclosed reel type game machine or an enclosed pachinko game machine.

<Configuration 6>
In configuration 6, the main control board and the power supply board are connected by a harness 16, and power is supplied from the power supply board to the main control board. Also, a CPU is provided on the board of the main control board. A payout control board (a board that executes control for giving game values such as game medals, game balls, and scores) and a power supply board are connected by a harness 17, and power is supplied from the power supply board to the payout control board. configured to be supplied. Also, a CPU is provided on the board of the payout control board. In addition, the main control board and the payout control board are connected by a harness 19, and are configured to be able to transmit and receive commands in both directions. Also, in the payout control board case, the board of the payout control board and the sub board (board for backing up the information stored in the RAM of the payout control board) provided with a capacitor are connected by a floating connector or the like. , power can be supplied from the sub-board to the payout control board.
The capacitor can store power and is configured to store power from the power supply board via the payout control board. In addition, when the power supply from the power board to the payout control board is stopped, the power stored in the capacitor provided on the board of the sub board is configured to supply power to the payout control board for a certain period of time. connected (if the floating connector is connected). In addition, even if the power supply from the power supply board to the main control board and the payout control board is stopped, the power stored in the capacitor provided on the board of the subboard will cause the sub board → payout control board → for a certain period of time. Power is supplied to the main control board (when the floating connector and harness 19 are connected). In the figure, the power supply board is configured to be able to directly supply power to the payout control board, but the present invention is not limited to this, and the power supply board and the sub-board 2 (the same as the sub-board described in the same paragraph can be used without any problem). ) may be connected by a harness so that electric power can be supplied in the order of "power board→sub-board 2→payout control board". In configuration 6, a sub-board B connected to the main control board with a harness may be provided, and in such a configuration, a capacitor may be provided on the substrate of the sub-board B. .

(Second embodiment)
First, the gaming machine according to the second embodiment has a specific area C22 in which a game ball can enter inside the second big winning hole C20. By entering a ball, it is configured to shift to a probability variable game state after the end of the special game (so-called ball winning machine, VST machine). In addition, the probability variation gaming state is a time shortening gaming state, and the probability variation gaming state is terminated by the number of variations of the main game symbols. It should be noted that in the second embodiment, as in the present embodiment, when there is a reserved ball of the second main game pattern, regardless of the presence of a reserved ball of the first main game pattern (even if the winning order is the first main game symbol) (Even if the game symbols are reserved first), it is preferable to preferentially execute the reserved consumption of the second main game symbols. Alternatively, it may be configured to execute a parallel lottery in which both main game symbols are drawn in parallel). In addition, in the second embodiment, it is supplemented that the configuration described in the present embodiment (for example, the configuration including setting values, etc.) may be applied as appropriate.

First, FIG. 70 is a flow chart of the first (second) main game symbol display process according to the subroutine of step 1400 (1) {step 1400 (2)} of FIG. 28 in the second embodiment. First, the differences from this embodiment are step 1408 (second), step 1411 (second), step 1412-1 (second), step 1412-2 (second), step 1450 (second), This is step 1413 (second). That is, after determining the stop symbol of the main game symbol in step 1410-2, in step 1408 (second), the CPUMC of the main control board M determines whether or not the main game time saving flag is off. In the case of Yes in step 1408 (second), in step 1412-1 (second), the CPUMC of the main control board M determines the variation mode of the main game symbols based on the main game side random numbers and winning/losing lottery results. On the other hand, if No in step 1408 (second), the process proceeds to step 1411 (second), and the CPUMC of the main control board M determines whether or not the limited frequency counter value is zero. If Yes in step 1411, that is, if the limited frequency counter value is 0, in step 1412-2 (second), the CPUMC of the main control board M, based on the main game side random numbers and winning/losing lottery results, Determines the pattern variation mode. On the other hand, if No in step 1411 (second), a limited frequency variation mode determination process is executed in step 1450 (second), and a process of subtracting 1 from the limited frequency counter value is executed in step 1413 (second). do.

Here, FIG. 71 is a configuration diagram of the main game table used in the first (second) main game symbol display process on the main control board side in the second embodiment. Of the main game symbols that become a big hit, the main game symbols for executing a special game that makes it easier for the game ball to enter the specific area are "5A, 7A, 3B, 5B, 7B". The main game symbol for executing a special game in which a game ball is difficult to enter is "2A".

Next, FIG. 72 is a flow chart of the limited frequency variation mode determination process according to the subroutine of step 1450 (second) in FIG. First, in step 1452, the CPUMC of the main control board M refers to the limited frequency counter and determines whether the counter value G is within the first stage range (80≧G>50). In the case of Yes in step 1452, in step 1454, the CPUMC of the main control board M determines the variation mode (variation time) related to the main game pattern based on the main game side random number and the result of the lottery, and the next process (step 1413).

Here, FIG. 73 (limited frequency table 1) is an example of a lottery table for determining the limited frequency variation mode. As shown in this example, in the second embodiment, the limited frequency table 1 is referred to when the limited frequency counter value G is within a predetermined range (80≧G>50). The tables referred to by the first main game side and the second main game side have the same contents. Also, the variation time at the time of winning is relatively longer than the variation time at the time of loss. When compared with the limited frequency table 2 and the limited frequency table 3, the limited frequency table 1 is configured to have the shortest average fluctuation time. Further, the limited frequency table 1 is configured to refer to a similar table regardless of the number of held balls.

On the other hand, if No in step 1452, in step 1456, the CPUMC of the main control board M refers to the limited frequency counter to determine whether the counter value G is within the second stage range (50≧G>10). determine whether or not In the case of Yes in step 1456, in step 1458, the CPUMC of the main control board M determines the variation mode (variation time ) is determined, and the process proceeds to the next process (process of step 1413).

Here, FIG. 73 (limited frequency table 2) is an example of a lottery table for determining the limited frequency variation mode. As shown in this example, in the second embodiment, the limited frequency table 2 is referred to when the limited frequency counter value G is within a predetermined range (50≧G>10). The tables referred to by the first main game side and the second main game side have the same contents. Also, the variation time at the time of winning is relatively longer than the variation time at the time of loss. When compared with the limited frequency table 2 and the limited frequency table 3, the limited frequency table 2 is configured to have the longest average fluctuation time. Also, the limited frequency table 2 is configured so that the average variation time is shorter when there are two or three pending balls than when there are zero or one.

On the other hand, if No at step 1456, in other words, if the limited frequency counter value G is within the range of the third stage (10≧G), at step 1460, the CPUMC of the main control board M generates a main game side random number. , Based on the lottery result, the variation mode (variation time) related to the main game symbol is determined, and the process proceeds to the next process (process of step 1413).

Here, FIG. 73 (limited frequency table 3) is an example of a lottery table for determining the limited frequency variation mode. As shown in this example, in the second embodiment, the limited frequency table 3 is referred to when the limited frequency counter value G is within a predetermined range (10≧G). The tables referred to by the first main game side and the second main game side have the same contents. In addition, only one type of variable time can be selected in the limited frequency table 3, and is constant regardless of the lottery results and the number of pending balls.

The content of the limited frequency table is not limited to this, and only in a predetermined stage (for example, the first stage), the contents of the limited frequency table to be referred to by the first main game side and the second main game side are They may be configured to be identical. Also, in a predetermined stage (for example, the third stage), the variation mode may be determined (on both the first main game side and the second main game side) regardless of the number of reservations. If not configured as such, the first main game side selects a variation mode from the same table regardless of the number of reservations, and the second main game side selects the number of reservations when the number of reservations is equal to or greater than a predetermined number. is less than a predetermined number.

In the second embodiment, there are three types of limited frequency tables, which are switched in three stages in the order of limited frequency table 1→limited frequency table 2→limited frequency table 3 (so-called 3-stage ST). No matter how many types of limited frequency tables are used, there is no problem even if the order of the tables to be referred to is changed. Furthermore, there are two tables, a limited frequency table 1 and a limited frequency table 2, and the tables to be referred to are switched in the order of the limited frequency table 1→limited frequency table 2→limited frequency table 1 to form a three-step ST mode. good too.

Next, FIG. 74 is a flow chart of special game control processing according to the subroutine of step 1600 of FIG. 10 in the second embodiment. First, the difference from this embodiment is step 1611 (second) and step 1850 (second), the purpose of which is a distribution game (a unit game that opens the second big winning port C20 having a specific area ) can be executed. That is, after setting the special game start display instruction command to the sub side in step 1608, or when the special game execution flag is ON, in step 1611 (second), the CPUMC of the main control board M is currently It is determined whether or not the round to be executed is the distribution game execution round (second R, 4R in this example). In the case of Yes at step 1611 (second), at step 1850 (second), the CPUMC of the main control board M executes distribution game execution processing, which will be described later, and proceeds to step 1634 . On the other hand, in the case of No in step 1611 (second), the process proceeds to step 1612 to execute the same processing as in the present embodiment.

Next, FIG. 75 is a flow chart of distribution game execution processing according to the subroutine of step 1850 (second) in FIG. 74 in the second embodiment. First, at step 1852, the CPUMC of the main control board M determines whether or not the distribution game execution flag is ON. If Yes in step 1852 , go to step 1866 . On the other hand, if No at step 1852, at step 1854, the CPUMC of the main control board M determines that the stopped main game symbol is a long open symbol (the second big winning opening C20 is relatively long in the distribution game execution round). It is a big hit pattern that opens time, and in this example, it is determined whether or not it is 3B, 5A, 5B, 7A, 7B). In the case of Yes in step 1854, in step 1856, the CPUMC of the main control board M selects a long opening pattern (for example, opening for 15 seconds and specifying An open pattern designed to ensure that the ball enters area C22 is set, and the process proceeds to step 1860. In the case of No in step 1854, in other words, when the stop symbol is 2A, in step 1858, the CPUMC of the main control board M selects the short opening pattern as the opening pattern of the second big winning opening C20 having the specific area C22. - Set an open pattern (for example, an open pattern for 0.1 seconds and designed to ensure that the ball does not enter the specific area C22), and proceed to step 1860 . In addition, the long open pattern on the first main game side is "5A / 7A", the ratio to be selected at the time of the big hit is "524/1024", and the long open pattern on the second main game side is " 3B, 5B, 7B", and the ratio to be selected at the time of the big hit is "1024/1024", so the big hit on the second main game side is distributed more than the big hit on the first main game side. The ratio of the second big winning opening C20 being long open in the game execution round is high, that is, the game ball is configured to easily enter the specific area C22 at the time of the big hit.

Next, at step 1860, the CPUMC of the main control board M clears the counter value of the winning ball counter. Next, at step 1862, the CPUMC of the main control board M turns on the distribution game continuation flag. Next, at step 1864, the CPUMC of the main control board M opens the second big winning hole C20 according to the set opening pattern, and proceeds to step 1866.

Next, at step 1866, the CPUMC of the main control board M checks the counter value of the winning ball counter and determines whether or not a predetermined number (10) of game balls have entered the second big winning hole C20. If Yes at step 1866 , go to step 1870 . On the other hand, if No at step 1866, at step 1868, the CPUMC of the main control board M determines whether or not the opening period (set opening pattern) of the second prize winning opening C20 has ended. If Yes at step 1868 , go to step 1870 . Next, at step 1870, the CPUMC of the main control board M closes the second big prize winning opening C20. Next, at step 1872, the CPUMC of the main control board M turns off the distribution game running flag. Next, at step 1874, the CPUMC of the main control board M determines whether or not a game ball has entered the specific area C22 in the execution round of the distribution game. In the case of Yes at step 1874 , at step 1876 , the CPUMC of the main control board M turns on the main game probability variation transition reservation flag, and proceeds to step 1878 . If the result of step 1874 is No, the process proceeds to step 1878 as well. Next, at step 1878, the CPUMC of the main control board M adds 1 to the round number counter (ends the execution round of the distribution game), and shifts to the next process. Incidentally, even if No in step 1868, the process proceeds to the next process.

Next, FIG. 76 is a flow chart of the game state determination process after the special game is finished according to the subroutine of step 1650 of FIG. 74 in the second embodiment. In the second embodiment, in the distribution game, depending on whether or not there is a ball entering the specific area C22, the upper limit of the number of fluctuations in the probability fluctuation game state and the time reduction game state is configured to be different. there is That is, when executing this subroutine, at step 1680 (second), the CPUMC of the main control board M determines whether or not the main game probability variation shift reservation flag is ON. In the case of Yes at step 1680 (second), at step 1682 (second), the CPUMC of the main control board M turns off the main game probability variation transition reservation flag. Next, in steps 1652 and 1654, the CPUMC of the main control board M sets a predetermined number of times (in this example, 80 times) to the variable probability counter and turns on the main game variable probability flag. Next, in step 1684 (second), the CPUMC of the main control board M sets the limited frequency counter to a predetermined number of times A (80 times in this example). Next, in step 1656, the CPUMC of the main control board M sets a predetermined number of times A (80 times in this example) to the time saving counter, and proceeds to step 1658. Thereafter, in steps 1658 and 1660, A process of turning on the main game time saving flag and turning on the auxiliary game time saving flag is executed.

On the other hand, if No in step 1680 (second), in step 1686 (second), the CPUMC of the main control board M sets the time-saving counter to a predetermined number of times B (in this example, 50 times, but this However, a value equal to or less than the predetermined number of times A is preferable.

Here, in the second embodiment, regardless of whether or not a ball is entered into the specific area C22 during the special game, the state is shifted to the time shortening game state after the special game is finished. Further, when there is a game ball entering the specific area C22 during the special game, the number of fluctuations in the time shortening game state after the special game is the same predetermined number of times A as the number of fluctuations in the probability fluctuation game state. (80 times in this example), and if the game ball does not enter the specific area during the special game, the number of fluctuations in the time-reduced game state after the special game is different from the predetermined number A (smaller ), which is a predetermined number of times B (50 times in this example). As a result, even in the unlikely event that the specific area C22 is not passed during the special game in which it is easy for the ball to enter the specific area C22, a certain advantageous period can be provided, and the case where the specific area C22 is not passed can be provided. It can be expected to prevent the decline in interest in In addition, the variation mode of the main game symbols in the time-reduced game state is that, in the time-reduced game state of the predetermined number of times A, there are three stages of limited frequency tables (limited frequency table 1, limited frequency table 2, and limited frequency table 3). The main game table 3-2 is referred to during the time-reduced game state for a predetermined number of times B, and a table with different effect contents is referred to. In addition, the configuration is applied to both cases in which the jackpot symbols that triggered the execution of the special game are the same or different (for example, even if the special game is triggered by the same jackpot pattern, the special game execution The number of times of time saving differs depending on whether or not the ball enters the specific area C22, etc.). It should be noted that this example is merely an example, and is not limited to this. If the ball is not entered into the specific area C22 at the beginning of the game, the upper limit number of fluctuations in the time reduction game is determined by the jackpot pattern, etc.).

Next, FIG. 77 is an example of an effect content determination table in the second embodiment. In the second embodiment, when the game ball does not enter the specific area C22 during the special game, the game state after the special game does not become the probability fluctuation game state, but the non-probability fluctuation / time reduction game state (50 fluctuation ). In that case, the table is referenced to determine the content of the effect. It should be noted that this example is merely an example, and the number of times of variation, the contents of presentation, the manner of variation, the structure of the table, etc., are not limited to these.

As described above, according to the second embodiment, depending on whether or not the game ball enters the specific area during the special game, it is determined whether or not to shift to the probability fluctuation game state after executing the special game (specific area When a game machine (so-called ball-certain, VST type game machine) that shifts to the probability variable gaming state with a ball entering and does not shift to the probability variable gaming state without a ball entering, does not enter the probability variable gaming state Appropriate performance according to the player's profit mode by making the variation mode (and performance) during the non-probability variable game state and time shortening game state different from the variation mode (and performance) during the probability variable game state can be executed. Although not particularly shown in this example, when executing a sorting game, special effects (effects to incite whether the second big winning opening C20 will be long open, entry to the specific area C22 Effect of inciting whether or not the ball will be played, effect of notifying that the ball has been entered into the specific area C22, etc.) may be configured to be executed (the execution mode is not particularly limited, but for example , In the case of an effect to notify that the ball has entered the specific area C22, the effect display device SG or the effect display device SG is displayed at the timing (preferably immediately after) when the ball is entered. It can be exemplified that the effect device (for example, a so-called movable body accessory for performance, a light guide plate, etc.) provided on the front side is configured to execute the notification (for example, on the effect display device SG An image is displayed on the light guide plate by displaying an image drawn with "V", by displacing the movable body accessory for production from the initial position to a position where production is possible, or by irradiating the light guide plate with light. float, etc.)}. It should be noted that when executing an effect to notify that the ball has entered the specific area C22, when a special game is won in a specific game state (for example, probability variable game state) or a specific special pattern (jackpot pattern) ) is won, in a special game in which an open pattern designed to make it almost certain that the ball enters the specific area C22 is executed, an image drawn with a "V" is displayed sparingly (for example, , small display), etc., in a situation where there is a possibility that a special game will be performed in which the release pattern designed to make the ball entering the specific area C22 almost certainty is not executed (entering the specific area C22 in the special game In a situation where the ball easiness is unknown), after that, when an open pattern designed to make the ball entering the specific area C22 almost certain is executed, the ball was entered into the specific area C22 It is also preferable to execute an effect different from the effect for notifying that effect, and thereby the effect can be executed with a priority according to need.

Further, in the second embodiment, there are a plurality of opening modes (for example, two types) in the unit game (round) in which the second big winning hole C20 is open. Specifically, although not shown, a first unit game that can be opened for a first time (preferably less than or less than one shooting interval of the game ball), and a predetermined time after opening the first time and a second unit game that can be closed (or opened and closed) again for a second period longer than the first period after being closed for a period of time. Thus, by configuring the first unit game and the second unit game to be executable, the probability It is possible to have the possibility of executing the opening operation at the second time when the expectation for the fluctuation transition is high. As a result, it is possible to enhance the interest of the game during the special game. In addition, the second time is preferably more than or equal to one firing interval of the game ball in order to ensure that the ball enters the specific area. It is more preferable to be at least or more than (1 firing interval of the ball), and it is particularly preferable to be at least (upper limit winning number of the round) x (1 firing interval of the game ball) or more.

In addition, in a gaming machine (so-called ball securing machine, VST machine) that can shift to the probability variable gaming state after the special game ends by entering the specific area C22 during execution of the special game like the second embodiment (1) Only one big winning hole is provided, and the normal round (round in which the ball entering the specific area C22 is invalid) and the distribution game execution round (to the specific area C22) (2) A large winning hole A and a large winning hole B having a specific area C22 are provided, and a normal round is executed in the big winning hole A, Execute the distribution game execution round at the winning opening B. (3) Arrangement such that the large winning opening A and the large winning opening B having the specific area C22 overlap vertically (large winning opening B is on top ), the normal round is executed at the big winning opening A, the distribution game execution round is executed at the big winning opening B, and only during the execution of the distribution game execution round, the ball can be entered into the specific area C22. (4) A large winning opening A and a large winning opening B having a specific area C22 are arranged so as to overlap each other (large winning opening B is on top). , the normal round is executed, the distribution game execution round is executed at the big winning opening B, and the game ball can enter the specific area C22 only during the execution of the distribution game execution round (a shielding member is provided , when the shielding member is in the open state, it becomes easy to enter the specific area C22, and when the shielding member is in the closed state, it becomes difficult to enter the specific area C22). good.

(Modification 1 from the second embodiment)
In addition, in the second embodiment, the configuration of the gaming machine that shifts to the probability variable gaming state after the special game is completed by entering the specific area C22 during the execution of the special game has been exemplified. The configuration is not limited to the two embodiments. Therefore, the configuration having the specific region C22 different from that of the second embodiment is defined as Modification 1 from the second embodiment, and only the points of modification from the second embodiment will be described in detail below.

First, FIG. 78 is a main flow chart showing the flow of general processing performed by the CPUMC of the main control board M in Modification 1 from the second embodiment. The difference from the present embodiment is the number of prize balls corresponding to the winning opening, that is, the number of prize balls at the first main game start opening A10 is three, and the number of prize balls at the second main game start opening B10. is 1 ball, the number of prize balls in the first big prize hole C10 is 15 balls, the number of prize balls in the second big prize hole C20 is 13 balls, and the general prize holes (left general prize hole, right general prize hole ), the number of prize balls is 10. Thus, in Modification 1 from the second embodiment, the number of prize balls in the second big prize hole C20 is smaller than the number of prize balls in the first big prize hole C10.

Next, FIG. 79 shows the first (second) main game symbol display process according to the subroutine of step 1400 (1) {step 1400 (2)} of FIG. 27 in modification 1 from the second embodiment. It is a flow chart. First, the changes from the second embodiment are step 1450 (second variant 1), step 1431-1 (second variant 1) and step 1431-2 (second variant 1). If the limited frequency counter value is not 0, at step 1450 (second variation 1), the CPUMC of the main control board M executes a limited frequency variation mode determination process, which will be described later, and proceeds to step 1413 .

In step 1440, after the condition device operation flag is turned on, in step 1431-1 (second variation 1), the CPUMC of the main control board M determines that the stop pattern is a limit frequency jackpot pattern (shortening the time after the jackpot ends). It is determined whether or not it is a jackpot pattern that becomes a limited frequency state after the game state is finished, and in this example, 7B). If Yes in step 1431-1 (second variation 1), in step 1431-2 (second variation 1), the CPUMC of the main control board M stores a predetermined number of times (100 times in this example) in the limit frequency counter. set and go to step 1500 .

Next, FIG. 80 is a flow chart of the limited frequency variation mode determination process according to the subroutine of step 1450 (second variation 1) of FIG. 79 in modification 1 from the second embodiment. First, in step 1451-1, the CPUMC of the main control board M determines whether or not the limited frequency counter value G is within the first stage range (100≧G>21). In the case of Yes in step 1451-1, in step 1451-2, the CPUMC of the main control board M refers to the main game table 3, and based on the main game side random number and the lottery result, the variation mode related to the main game symbol ( fluctuation time) is determined, and the process proceeds to the next process (process of step 1413). On the other hand, if No at step 1451-1, at step 1451-3, the CPUMC of the main control board M determines whether or not the limited frequency counter value G is within the second stage range (G=21). do. Incidentally, when the limited frequency counter value is 21, it is the final variation in the time shortening game state. In the case of Yes at step 1451-3, at step 1451-4, the CPUMC of the main control board M determines whether or not the current gaming state is the probability variation gaming state. In the case of Yes at step 1451-4, at step 1451-5, the CPUMC of the main control board M refers to the limited frequency table 1, and based on the main game side random number and the winning/failing lottery result, the variation mode related to the main game symbol. (Variation time) is determined, and the process proceeds to the next process (process of step 1413). If No in step 1451-4, the process proceeds to step 1451-2, and the main game table 3 is referenced to determine the variation mode (variation time) related to the main game symbol. Thus, in the modification 1 from the second embodiment, in the final variation of the time shortening gaming state, when determining the variation mode in the case of the probability variation gaming state and the case of the non-probability variation gaming state The table referred to is different. In other words, the final symbol variation in the time-reduced gaming state after the end of the big hit depending on whether or not the game ball enters the specific area C22 during the execution of the big hit related to "7B", which is the limit frequency big hit pattern. are configured so that the tables referred to when determining the variation mode are different. In the case of No at step 1451-3, at step 1451-6, the CPUMC of the main control board M refers to the limited frequency table 2, and based on the main game side random number and the winning/failing lottery result, A variation mode (variation time) is determined, and the process proceeds to the next process (process of step 1413). In addition, in the modification 1 from the second embodiment, when the jackpot related to "7B", which is the limit frequency jackpot pattern, ends, the limited frequency counter is set to 100 times, and the time saving counter is set to 100 times. 80 times is set. Because of this configuration, when the limited frequency counter value is not within the first stage range, that is, when the limited frequency counter value is a value of 20 or less, the non-time-reduced game state and the limited frequency counter value is 0. A bigger situation. In such a state, by referring to the limited frequency table to determine the variation mode of the main game pattern, when the jackpot related to the limit frequency jackpot pattern "7B" ends, the "symbol Time shortening game state for 80 times of variation→Limited frequency state for 20 times of symbol variation (non-time shortening game state)”. In addition, it is not limited to such a configuration, and in the time shortening game state, the limited frequency state A (the limited frequency table to be referred to is "limited frequency table A1 → limited frequency table A2 → limited frequency table A3”), and the limited frequency state B (the limited frequency table to be referred to is “limited frequency Table B1" only), that is, the limited frequency state may be configured so as not to straddle different game states. In addition, when "7B", which is the limit frequency jackpot pattern, is won, 80 times are set in the time-saving number counter regardless of whether or not the ball enters the specific area C22 during execution of the special game related to "7B". , 100 times is set in the limited frequency counter, that is, after the time-reduced game state ends, the state is shifted to the limited frequency state. In addition, when the limited frequency counter value is not 0 and the jackpot is hit, it may be regarded as a jackpot during consecutive games, and the above-mentioned consecutive game number counter value may be added (when the time reduction game state is Even if it has ended, if you win a jackpot in a limited frequency state, you can regard it as a Renso jackpot). In addition, it is not limited to this, and when "7B", which is a limit frequency jackpot symbol, is won, when the ball is entered in the specific area C22 during the execution of the special game related to "7B", the time saving number counter is set to 80. The number of times is set, and 100 times is set to the limited frequency counter. On the other hand, if the ball does not enter the specific area C22, 50 times is set to the time saving number counter and 70 times is set to the limited frequency counter. can be configured to In addition, when "7B", which is the limit frequency jackpot symbol, is won and the ball is not entered in the specific area C22 during the execution of the special game related to "7B", in the time-reduced game state after the special game ends In the final variation, the variation mode of the main game symbols may be determined by referring to a limited frequency table (for example, a limited frequency table 3) referenced only in the final variation. Incidentally, the content of the limited frequency table 3 may be configured so that a uniform variation time of 7 seconds is determined regardless of the number of reservations, regardless of whether the game is a win or a loss. In addition, when "7B", which is the limit frequency jackpot symbol, is won and the ball is not entered in the specific area C22 during the execution of the special game related to "7B", in the time-reduced game state after the special game ends The limited frequency table referred to in the final variation is the limited frequency referred to in the final variation in the time-reduced gaming state after the end of the special game when the ball is entered in the specific area C22 during execution of the special game related to "7B". The tables may be configured to be the same, and in the case of such a configuration, the effect contents and effect tendencies in the final variation in the time-reduced game state may be the same.

Here, FIG. 81 is a configuration diagram of the main game table used in the first (second) main game symbol display process on the main control board side in Modification 1 from the second embodiment. The difference from the second embodiment is that the combinations of main game symbols that result in big wins are different, and the configuration of the limited frequency table. In addition, among the main game symbols that become a big hit, the main game symbols that make it easier for the game ball to enter the specific area and that the special game is executed are "5A, 7A, 3B, 5B, 7B". The main game symbol for executing a special game in which it is difficult for a game ball to enter the area is "4A". In addition, when the above-mentioned jackpot related to the limit frequency jackpot pattern "7B" is completed, the state shifts to the time reduction game state of 80 pattern fluctuations (the fluctuation time is determined by referring to the main game table 3). ), and when the 80 symbol variations are completed, the system is configured to shift to a limited frequency state of 20 symbol variations (variation time is determined by referring to the limited frequency table 2). In addition, in the case of the limited frequency state in which the limited frequency table 2 is referred to, the variation time of the main game symbols is configured not to be selected for a long time exceeding 10 seconds regardless of the result of the lottery. In addition, in the final variation (80th variation after the end of the jackpot) of the time-reduced gaming state that shifts when the jackpot related to the limit frequency jackpot pattern “7B” ends, it is specified during the execution of “7B” When there is a ball entering the area C22, the limited frequency table 1 is referred to determine the variation mode. The game table 3 is referred to to determine the variation mode (the shortest variation time in the loss of the limited frequency table 1 is longer than the shortest variation time in the loss of the main game table 3). . In the final variation in the time shortened gaming state, the limited frequency table 1 or the main game table 3 is configured to be referred to. The effect contents in the final variation may be different depending on whether or not the game ball enters the specific area C22 during the special game. good. For example, when referring to the limited frequency table 1, which is a relatively long-time pattern variation, the pattern variation will encourage whether the probability variation game state and the time reduction game state will end or a big hit will be achieved. You may perform a performance.

Next, FIG. 82 is a flow chart of special game control processing according to the subroutine of step 1600 of FIG. 10 in Modification 1 from the second embodiment. First, the changes from the second embodiment are steps 1635-1 (second variation 1) and 1635-2 (second variation 1) and step 1800 (second variation 1). If it is the final round in the special game, at step 1635-1 (second variant 1), the CPUMC of the main control board M sets the end demonstration execution permission flag (the special game end demonstration time is started by turning it on). flag) is turned on, and the process proceeds to step 1635-2 (second variation 1). Note that even if No in step 1634, the process proceeds to step 1635-2 (second variation 1). Next, at step 1635-2 (second variation 1), the CPUMC of the main control board M determines whether or not the end demonstration execution permission flag is ON. If Yes in step 1635-2 (second variation 1), the process proceeds to step 1800 (second variation 1), and if No, the next process is performed.

Next, FIG. 83 is a flowchart of end demonstration time control processing according to the subroutine of step 1800 (second modification 1) of FIG. 82 in modification 1 from the second embodiment. First, at step 1802, the CPUMC of the main control board M determines whether or not the end demonstration running flag is off. In the case of Yes in step 1802, in step 1803 (second variation 1), the CPUMC of the main control board M determines whether or not a ball has entered the specific area C22 in the special game. If Yes in step 1803 (second variation 1), the process proceeds to step 1806 , and if No, the process proceeds to step 1808 . At step 1806, the CPUMC of the main control board M sets a long time (for example, 10 seconds) to the end demonstration time timer (main side timer for measuring the end demonstration time of the special game) and starts. Go to 1810. On the other hand, if No in step 1804, in other words, if the stopped symbol is a short demo time jackpot symbol (3A, 3B, 5A, 5B), in step 1808, the CPUMC of the main control board M sets the end demo time timer. Set a short time (eg, 3 seconds) to start and go to step 1810 . Next, at step 1810, the CPUMC of the main control board M sets a special game end display instruction command to the sub side and a command related to the determined end demo time information (by the control command transmission processing at step 1999, the sub main control unit sent to the SM side). Next, at step 1812 , the CPUMC of the main control board M turns on the end demonstration execution flag, and proceeds to step 1814 . It should be noted that even if No in step 1802 , the process proceeds to step 1814 .

Next, at step 1814, the CPUMC of the main control board M determines whether or not the timer value is zero. If Yes at step 1814, at step 1816, the CPUMC of the main control board M turns off the end demonstration running flag. Next, at step 1818, the CPUMC of the main control board M turns off the end demonstration execution permission flag. Next, at step 1820, the CPUMC of the main control board M turns off the special game execution flag. Next, at step 1650, the CPUMC of the main control board M executes the aforementioned game state determination processing after the end of the special game, and shifts to the next processing. Incidentally, even if the result in step 1814 is No, the process proceeds to the next step.

Thus, in the modification example 1 from the second embodiment, the special game end demo time, which is the period after the final round of the special game ends, is the time when the game ball enters the specific area C22 during execution of the special game. It is configured so that the time value differs depending on whether or not there is a ball. Incidentally, the condition for the special game end demonstration time to be different is not limited to this, and for example, the difference may be made according to the game state at the time of the big win. Specifically, (1) It differs depending on whether it is a probability variation gaming state or a non-probability variation gaming state, (2) It differs depending on whether it is a time shortening gaming state or a non-time shortening gaming state, ( 3) probability variation gaming state and time shortened gaming state, probability variation gaming state and non-time shortening gaming state, non-probability variation gaming state and time shortening gaming state, non-probability variation gaming state and non-time shortening gaming state, (4) probability variation gaming state and time shortening gaming state, probability variation gaming state and non-time shortening gaming state, non-probability variation gaming state and time shortening gaming state, non-probability variation gaming state and It may be configured such that it is different in some combinations of the non-time-reduction gaming state.

In addition, in this example, regarding a special game related to a certain jackpot pattern, (1) special game is won in a non-time-reduced game state, and there is a ball entering the specific area C22 during the special game. The game end demo time is the first period (10 seconds), (2) the special game end demo time when the special game is won in the non-time-reduced game state and no ball is entered into the specific area C22 during the special game. is the second period (3 seconds), (3) If the special game is won in the time-reduced game state and there is a ball entering the specific area C22 during the special game, the special game end demonstration time is the second period ( 1 second), (4) If the special game is won in the time-reduced game state and no ball is entered into the specific area C22 during the special game, the special game end demonstration time is the third period (3 seconds). Thus, it may be configured such that "second period<third period<first period". It should be noted that such a configuration is preferably applied to a special game won in the non-probability varying gaming state and non-time shortening gaming state or the probability varying gaming state and time shortening gaming state. In addition, as a specific example of the effect executed during the special game end demo time, in the first period, the effect of notifying the transition to the probability variable game state, forgetting to take out the IC card used for lending the game ball , a slogan display effect to prevent addiction, and an effect to display the logo of the game machine manufacturer. An effect for notifying, an effect for calling attention to forgetting to take the IC card is executed, and an effect for notifying that the probability variable game state (continuous game state) will continue is executed in the second period. In this way, it may be configured such that the effect to be executed differs depending on the length of the special game end demonstration time. In addition, comparing the length of the special game end demo time by situation, the special game end demo time when the non-probability variable game state is before the special game starts and the probability variable game state is after the special game (first hit) is 10 seconds, the special game end demo time is 3 seconds when the special game is in a non-probability variable game state and a time shortened game state, the probability variable game state is before the special game starts, and the probability variable state is after the special game ends. It may be configured such that the special game ending demonstration time in the case of entering the game state (continuous game continuation) is 1 second.

Next, FIG. 84 is a flowchart of special game-related display control processing according to the subroutine of step 2900 of FIG. 53 in Modification 1 from the second embodiment. Differences from the present embodiment are steps 2980 (second variant 1) to step 2984 (second variant 1). That is, after turning off the special game in step 2930, in step 2980 (second variation 1), the CPUSC of the sub control board S determines that the special game end command is a long open command (end demo set in step 1810). It is determined whether the command is a command related to time information and a command related to the fact that the end demonstration time is 10 seconds, which is a long time. In the case of Yes in step 2980 (second variation 1), in step 2982 (second variation 1), the CPUSC of the sub-control board S displays a continuous game continuation image (notifying that the game will shift to the probability variation game state after the special game ends) For example, a command is set to display for a long time (10 seconds in this example), and the process proceeds to the next step. On the other hand, if No in step 2980 (second variation 1), that is, if the special game end command is a short open command, in step 2984 (second variation 1), a continuous villa end image (probability after special game ends Set a command to display for a short time (three seconds in this example) an effect that notifies that the variable game state will not be entered, for example, display "See you later!", and then proceed to the next process. It should be noted that the special game end demonstration time is configured to be different depending on whether the special game end demonstration time is long (10 seconds) or short (3 seconds). A performance mode (trend of performance) in a time-reduced game state after a special game ends when the game end demo time is long (10 seconds), and a special effect when the special game end demo time is short (3 seconds). It is configured to be the same as the production mode (drawing tendency) in the time-reduced game state after the end of the game.

By configuring as described above, in the gaming machine according to Modification Example 1 from the second embodiment, a special game end demonstration time is set after the final round of the special game ends, and the special game end demonstration time is specified in the special game being executed. By configuring the period of the special game end demonstration time to be different depending on whether or not the game ball enters the area C22, it is possible to increase the profit for the player when the game ball enters the specific area C22. On the other hand, if the player does not enter the specified area C22, it is not profitable for the player. The game machine can have more intonation.

Incidentally, in the modification 1 from the second embodiment, a special game start demonstration time may be provided. It should be noted that during the special game start demonstration time, it is not determined whether or not the game ball enters the specific area C22 in the special game, so depending on whether or not the game ball enters the specific area C22, the special game start demonstration time period shall not differ. However, the special game start demonstration time may be changed according to the game state when the special game is won. 3 seconds if the special game is won in a non-time-reduced game state short time). In addition, when a special game is performed in which an opening pattern designed to make the ball entering the specific area C22 almost certain is performed, during the special game start demo time, a message such as "SUPER Lucky!" Inflation may be heightened by executing an effect suggesting that the game state will be changed to a probability variable game state after the end of the special game.

(Modification 2 from the second embodiment)
In addition, in the second embodiment and the modification 1 from the second embodiment, the configuration of the gaming machine is changed to the probability variable game state after the special game is completed by entering the specific area C22 during the execution of the special game. Although exemplified, such a configuration is not limited to only the configuration of the second embodiment and the configuration of Modification 1 from the second embodiment. Therefore, the configuration having the specific region C22, which is different from the second embodiment and Modification 1 from the second embodiment, is defined as Modification 2 from the second embodiment, and only the changes from the second embodiment are described in detail below. describe.

First, FIG. 85 is a flow chart of special game control processing according to the subroutine of step 1600 of FIG. 10 in Modification 2 from the second embodiment. First, the difference from the second embodiment is step 1609-1 (second variant 2) and step 3100-1 (second variant 2). After setting the command, in step 1609-1 (second variation 2), the CPUMC of the main control board M turns on the start demonstration execution permission flag, and proceeds to step 3100-1 (second variation 2). On the other hand, also in the case of Yes in step 1610, the process proceeds to step 3100-1 (second variation 2). Next, at step 3100-1 (second variation 2), the CPUMC of the main control board M executes start demonstration time control processing, which will be described later, and proceeds to step 1610-1.

Next, FIG. 86 is a flow chart of distribution game execution processing according to the subroutine of step 1850 (second) in FIG. 85 in Modification 2 from the second embodiment. First, the differences from the second embodiment are step 1851-1 (second modification 2), step 1899-1 (second modification 2) to step 1899-7 (second modification 2), that is, step At 1851-1 (second variation 2), the CPUMC of the main control board M determines whether or not the during distribution demonstration time flag is off. If Yes in step 1851-1 (second variation 2), go to step 1852; if No, go to step 1854; Also, after setting the long open pattern in step 1856 or after setting the short open pattern in step 1858, in step 1899-1 (second variation 2), the CPUMC of the main control board M determines that the stop symbol is It is determined whether or not it is the first main game symbol (first main game jackpot symbol). If Yes in step 1899-1 (second variation 2), in step 1899-2 (second variation 2), the CPUMC of the main control board M sets the distribution start demo timer for a long time {step 1899-3 (second variation 2). A time value that is longer than the time value set in Variant 2), in this example, 10 seconds} is set and started, and the process proceeds to step 1899-4 (Second Variant 2). On the other hand, if No in step 1899-1 (second variation 2), in other words, if the stop symbol is the second main game symbol (second main game jackpot symbol), step 1899-3 (second variation 2) ), the CPUMC of the main control board M is a time value that is shorter than the time value set in the distribution start demo timer for a short time {step 1899-2 (second variation 2), and in this example, 3 Seconds} is set to start, and the process proceeds to step 1899-4 (second variation 2). Next, in step 1899-4 (second variation 2), the CPUMC of the main control board M issues a command (a command to the sub-side) related to the determined distribution start demo time information, and distributes the special game being executed. Set the minute demo time command). Next, in step 1899-5 (second variation 2), the CPUMC of the main control board M turns on the during distribution demonstration time flag (flag for starting the distribution demonstration time when it is turned on), and step 1899-6 (2nd Variation 2). Note that even if No in step 1851-1 (second variation 2), the process proceeds to step 1899-6 (second variation 2). Next, at step 1899-6 (second variation 2), the CPUMC of the main control board M determines whether or not the value of the distribution start demo timer is zero. If Yes in step 1899-6 (second variation 2), in step 1899-7 (second variation 2), the CPUMC of the main control board M turns off the distribution demonstration time flag, and proceeds to step 1860. . If No in step 1899-6 (second variation 2), the process proceeds to the next step. Thus, in the modification 2 from the second embodiment, the distribution start demo time, which is the start demonstration time of the distribution game execution round, is the second when the jackpot on the first main game side. The time is longer than in the case of a big hit on the main game side.

Next, FIG. 87 is a configuration diagram of an example of the opening pattern of the big winning opening. The jackpot patterns in the second embodiment are 3 types of 1st main game jackpot patterns "4A, 5A, 7A" and 3 types of second main game jackpot patterns "4B, 5B, 7B" for a total of 6 jackpot patterns. There are only two types of opening patterns in one round: "Short opening = 500 ms open -> close" and "Long opening = 30000 ms open -> close". In addition, the opening pattern of the big winning opening (the first big winning opening C10 or the second big winning opening C20) is not limited to this. An open pattern (for example, "open for 10000 ms→close for 10000 ms→open for 10000 ms→close") may be used. Here, only the second main game length opening jackpot "5B/7B" has a long opening pattern in all rounds (10R). Also, the distribution game execution round to be opened by the second big winning hole C20 is the fourth round, and the other rounds are to be opened by the first big winning hole. In addition, in all big hits, the number of rounds to be executed is 4 rounds or more, and a distribution game execution round is always executed. In this way, the first main game length opening jackpot "5A/7A" has a short opening round (second R), while the second main game length opening jackpot "5B/7B" has a short opening round. There is no short open round, that is, the number of short open rounds is configured so that the first main game length open jackpot is larger than the second main game length open jackpot.

Next, FIG. 88 is a flow chart of start demonstration time control processing according to the subroutine of step 3100-1 (second modification 2) of FIG. 85 in modification 2 from the second embodiment. First, at step 3102, the CPUMC of the main control board M determines whether or not the start demonstration running flag is off. In the case of Yes in step 3102, in step 3104, the CPUMC of the main control board M sets the start demonstration time (in this example, 3 seconds) to the start demonstration time timer and starts it. Next, at step 3106, the CPUMC of the main control board M determines whether or not the stopped jackpot symbols are the second main game jackpot symbols (3B, 5B and 7B in this example). In the case of Yes at step 3106, at step 3108, the CPUMC of the main control board M issues a second length release command (a special game related to the second main game jackpot pattern is started) as a special game start display instruction command to the sub side. command) is set, and the process proceeds to step 3116. On the other hand, if No at step 3106, at step 3110, the CPUMC of the main control board M determines whether or not the stopped jackpot pattern is the first main game length open jackpot pattern (5A and 7A in this example). do. In the case of Yes in step 3110, in step 3112, the CPUMC of the main control board M issues a first long open command (a second big winning opening among the first main game jackpot symbols) as a special game start display instruction command to the sub side. A command indicating the start of a special game in which C20 is long open) is set, and the process proceeds to step 3116. On the other hand, if No in step 3110, in other words, if the stopped jackpot symbol is not the first main game long open jackpot symbol, that is, if it is the first main game short open symbol (2A in this example). , in step 3114, the CPUMC of the main control board M issues a first short opening command (the second big winning opening C20 of the first main game jackpot symbols is short opening) as a special game start display instruction command to the sub side. A command indicating that a special game has started) is set, and the process proceeds to step 3116.

Next, at step 3116, the CPUMC of the main control board M sets a command related to the determined start demonstration time information to the sub side. Next, at step 3118, the CPUMC of the main control board M turns on the start demonstration execution flag, and proceeds to step 3120. FIG. It should be noted that even if No in step 3102 , the process proceeds to step 3120 . Next, at step 3120, the CPUMC of the main control board M determines whether or not the timer value of the start demonstration time timer is zero. If Yes at step 3120, at step 3122, the CPUMC of the main control board M turns off the start demonstration running flag. Next, at step 3124, the CPUMC of the main control board M turns off the start demonstration execution permission flag. Next, at step 3124, the CPUMC of the main control board M turns on the special game execution flag, and proceeds to the next process. On the other hand, also in the case of No in step 3120, the process proceeds to the next process.

Next, FIG. 89 is a flowchart of special game-related display control processing according to the subroutine of step 2900 of FIG. 53 in Modification 2 from the second embodiment. The changes from the second embodiment are steps 2903-1 (second variation 2) to step 2903-11 (second variation 2) and step 2350 (second variation 2). After turning off the middle flag, in step 2903-1 (second variation 2), the CPUSC of the sub control board S turns on the start demonstration flag (when it turns on, the special game start demonstration time is started). flag) is off. If Yes in step 2903-1 (second variation 2), the process proceeds to step 2904; Next, if Yes in step 2904, in step 2903-2 (second variant 2), the CPUSC of the sub control board S sets a predetermined time (for example, 3 seconds) to the start demonstration display timer and starts the timer. Start. Next, in step 2903-3 (second variation 2), the CPUSC of the sub control board S turns on the start demonstration flag. Next, at step 2350 (second variant 2), the CPUSC of the sub control board S executes start demonstration effect execution processing, which will be described later, and proceeds to step 2903-4 (second variant 2). Note that even if No in step 2903-1 (second variation 2), the process proceeds to step 2903-4 (second variation 2).

Next, in step 2903-4 (second variation 2), the CPUSC of the sub control board S determines whether or not the timer value of the start demonstration time timer is zero. If Yes in step 2903-4 (second variant 2), in step 2903-5 (second variant 2), the CPUSC of the sub control board S turns off the start demonstration flag and proceeds to step 2912. On the other hand, if No in step 2903-4 (second variation 2), the process proceeds to the next step.

Also, after setting the command for displaying the start of the big win in step 2914, in step 2903-6 (second variation 2), the CPUSC of the sub control board S receives the command for the distribution start demonstration time information from the main side. determine whether or not If Yes in step 2903-6 (second variation 2), in step 2903-7 (second variation 2), the CPUSC of the sub control board S sets the distribution start demonstration time to a long time (10 seconds in this example). ). Here, there are two types of time values of the distribution start demonstration time, that is, the start demonstration time of the distribution game execution round, long time and short time. In the case of Yes in step 2903-7 (second variation 2), in step 2903-8 (second variation 2), the CPUSC of the sub-control board S determines whether it is easy to enter or not during the long distribution start demonstration time. A notification effect (a effect that does not definitely notify the player whether or not the second big winning port C20 will be long open in the distribution game execution round) is executed, and step 2903-10 (second change 2) Transition. On the other hand, if No in step 2903-7 (second variation 2), in step 2903-9 (second variation 2), the CPUSC of the sub control board S enters the ball at the distribution start demonstration time, which is a short time. Easy notification effect (effect for definitely notifying the player that the second big winning port C20 will be long open in the distribution game execution round) is executed, and the process proceeds to step 2903-10 (second change 2). do. If No in step 2903-6 (second variation 2), the process proceeds to step 2903-10 (second variation 2). In this way, in the distribution game execution round related to the first main game pattern, the easy-to-enter non-notification effect is executed, and in the distribution game execution round related to the second main game pattern, the easy-to-enter ball notification effect is executed. is configured as follows. It should be noted that the present invention is not limited to this, and it is also possible to make a difference as to which of the easy-to-ball-enter non-reporting effect and the easy-to-ball-notifying effect is to be executed depending on the game state. For example, in the distribution game execution round related to the long open jackpot (5A/7A) on the first main game side won in the non-time reduction game state and non-probability variation game state, an easy-to-enter ball unnotified effect is executed, In the distribution game execution round related to the long-open jackpot (3B, 5B, 7B) on the second main game side won in the time reduction game state and the probability variation game state, an easy-ball entry notification performance is executed. good too. In addition, it may be configured so that the ending effect can be executed, and in the case of such a configuration, during the execution of the special game that executes the ending effect, the easy-to-enter non-notification effect and the easy-to-enter ball notification effect are the game. It is preferable to configure the display so as to be inconspicuous to the user. With such a configuration, it is possible to make the player pay more attention to the ending effects that are difficult to achieve. Similarly, it is configured to be able to execute a reservation internal rendezvous effect for informing the player that there is a big hit reserving in the reservations that exist during the execution of the special game, and Even when executed, the easy-to-ball-enter non-notification effect and the easy-to-ball-entering notification effect may be displayed inconspicuously for the player.

Next, in step 2903-10 (second variation 2), the CPUSC of the sub control board S determines whether or not the special game being executed is a special game related to the second main game length open big hit symbol ( The second main game length open jackpot symbols are 3B, 5B and 7B). If Yes in step 2903-10 (second variation 2), step 2916 is entered. On the other hand, if No in step 2903-10 (second variation 2), in step 2903-11 (second variation 2), the CPUSC of the sub control board S sets a command to sequentially display the number of winning prizes (short open In the case of a big hit with such a round, the number of rounds is not reported), and the process proceeds to step 2926. Thus, in the modification example 2 from the second embodiment, the second main game length open jackpot pattern is a jackpot pattern in which the first big prize hole C10 or the second big prize hole C20 is long open in all rounds. In the jackpot related to , the round being executed is notified when each round is executed (notifying which round is currently being executed), and the first big prize opening C10 or the second big prize in any round In a big win with a short opening of the opening C20 (or in a big winning having rounds with a short opening of the first big winning opening C10), the round being executed is not notified when each round is executed. In addition, if the round being executed is not notified, instead of the display notifying the round, an object image (for example, a treasure box, etc.) corresponding to the number of rounds (actually the number of rounds) is displayed in the first big prize opening C10 or the second It may be configured to additionally display each time a round in which the big winning opening C20 is long open is executed. In addition, at the start of the special game (or immediately after the start of the special game), a plurality of object images are displayed, and an effect is executed to ensure that the number of rounds corresponding to the number of the object images is long open. You may When the special game is executed in which all rounds are long open, the effect may or may not be executed, but if not executed, the number of rounds currently being executed is displayed. is desirable. In addition, in a big win in which the first big winning hole C10 or the second big winning hole C20 is short-opened in any round (or in a big win having a round in which the first big winning hole C10 is short-opened), It may be configured to notify only the number of rounds in which the first big prize opening C10 or the second big prize opening C20 is long open (for example, "1st R = long open, 2nd R = short open, 3rd R = long open In the case of "open", notify that it is the second round in the 3rd round, etc.). It should be noted that the effect executed during the execution of the special game is not limited to this, for example, a jackpot is held in a predetermined round (or a distribution game execution round) after the distribution game execution round during execution of the special game. In the case where there is a reservation to become a big hit, it may be constructed so as to be able to execute a reservation-in-reservation effect for informing that it is certain that the game will be a big hit. In addition, in the case of such a configuration, when the reservation inner rendezvous effect is executed in the round before the distribution game execution round, the game state after the special game is not determined (to the specific area C22 (It has not been decided whether or not the ball has entered), so despite the notification that it will be a big hit, there is a possibility that the pattern change related to the suspension that was the subject of the notification will be lost. The execution timing of the manor effect is preferably after the ball enters the specific area C22 in the distribution game execution round, or after the distribution game execution round ends. In addition, the distribution game execution round may be any round, for example, the first round may be configured to be the distribution game execution round (applicable even when there is one big winning hole) However, even if there are no game balls to hit (for example, if all the game balls are cut off during the pattern change that will be a hit), the second round is designed so that there is enough time to lend out additional game balls. It is desirable to do so later.

Next, FIG. 90 is a flow chart of start demonstration effect execution processing according to the subroutine of step 2350 (second modification 2) of FIG. 89 in Modification 2 from the second embodiment. First, in step 2352, the CPUSC of the sub control board S determines whether or not the second length open command is received from the main side. If Yes in step 2352 , go to step 2360 . On the other hand, if No at step 2352, at step 2354, the CPUSC of the sub control board S determines whether or not the first long open command is received from the main side. In the case of Yes at step 2354, at step 2356, the CPUSC of the sub-control board S informs that the second big winning opening C20 will be opened for a long time in the special game being executed in the fixed effect execution lottery that wins at 1/5. or not) is executed. Next, at step 2358, the CPUSC of the sub control board S determines whether or not the winning of the finalized effect execution lottery is made. If Yes at step 2358 , go to step 2360 . Next, at step 2360, the CPUSC of the sub-control board S executes a long-open determination notification effect (a effect to notify that the second big winning hole C20 will be long-opened in the special game being executed) as a start demonstration effect. Then, the process proceeds to the next process {process of step 2903-4 (second variation 2)}. If No at step 2354 (if the first short open command is received from the main side) or if No at step 2358, then at step 2362, the CPUSC of the sub control board S determines whether or not long open is present as a start demonstration effect. A notification effect (a effect of not notifying whether the second big winning opening C20 is to be opened for a long time or for a short time in the special game being executed) is executed, and the following processing {process of step 2903-4 (second variation 2)}. transition to It should be noted that even at the special game start demo time when the start demo effect is executed, as with the distribution start demo time, the first main game side jackpot (high percentage) is 10 seconds, the second main game A side jackpot (a high percentage of which) may be configured to be 3 seconds.

By configuring as above, in the second modification example from the second embodiment, in the special game related to the second main game side, the second big winning opening in the distribution game execution round in all special games C20 is long open, and in the special game related to the first main game side, a special game in which the second big winning opening C20 is long open and a special game in which the second big winning opening C20 is short open are provided in the distribution game execution round, In the special game on the side of the second main game, while notifying that the second big winning port C20 will be open for a long time at the start demonstration time of the special game, in the special game on the side of the first main game, the second big winning. Even if it is a special game in which the opening C20 is long open, it is configured to have a case where it is notified that the second big winning opening C20 is long open at the start demonstration time of the special game and a case where it is not notified, and during the special game. In the special game on the side of the second main game in which it is certain that the ball will enter the specific area C22, the player is notified that the second big winning hole C20 will be opened for a long time, while the player enters the specific area C22 during the special game. In the special game on the side of the first main game where it is not definite to open the second big prize opening C20, an effect is basically executed to prompt the player whether or not the second big prize opening C20 will be opened for a long time. With such a configuration, it is possible to provide a highly entertaining gaming machine capable of executing an effect corresponding to the ease with which a ball can be entered into the specific area C22.

In addition, in the modification 2 from the second embodiment, the easy-ball-entering notification effect and the easy-ball-unnotifying effect are configured to be executed at the distribution start demonstration time. It may be executed during execution of the round to be executed (may be executed over a plurality of rounds), or may be executed during execution of the distribution game execution round.

(Conditions for ending the probability variable gaming state)
As described above, in the second embodiment and these modified examples, the conditions for ending the probability variable gaming state are the case of ending with the winning of a big win, the case of ending with the number of fluctuations of the main game pattern after the end of the big win, and the probability variable fall. For example, the process may be terminated by a lottery. Here, with reference to FIG. 91, the case of ending by the probability fall lottery will be described.

Features of this example in FIG. In the second change 3), the CPUMC of the main control board M determines whether or not the main game probability change flag is on. If Yes in step 1448-1 (second variation 3), in step 1448-2 (second variation 3), the CPUMC of the main control board M wins with a predetermined probability (for example, 1/50). (lottery to determine whether or not the probability variation gaming state will end) is executed. Next, at step 1448-3 (second variation 3), the CPUMC of the main control board M determines whether or not the probability variable fall lottery has been won. If Yes in step 1448-3 (second variation 3), in step 1448-4 (variation 1), the CPUMC of the main control board M turns off the main game probability variation flag, and proceeds to step 1410-1. If No in step 1448-1 (second variation 3) or step 1448-3 (second variation 3), the process proceeds to step 1410-1.

By constructing as described above, in the case of shifting to the probability variable gaming state after the end of the big hit, the probability variable gaming state is set so that the probability variable gaming state does not end due to the number of fluctuations of the main game symbols. A probability variable drop lottery is executed for each change in the main game pattern executed in (timing immediately before the winning lottery execution), and if the probability variable drop lottery is won, the probability variable game state ends (probability variable game state to a non-probability-fluctuation game state), so that the player pays attention to when the probability-fluctuation game state ends, and the interest of the pattern variation of the main game pattern in the probability-fluctuation game state is improved. can be done.

In addition, by adjusting the winning probability of the probability variable fall lottery, the probability variable number of times, etc. for each set value, the configuration of the gaming machine in which the expected value of the probability variable gaming state that is advantageous to the player is unlikely to differ for each setting is illustrated. By combining and adjusting the above-described elements, a gaming machine may be constructed in which the expected value of the probability variable gaming state that is advantageous to the player is unlikely to differ from one setting to another. Specifically, by appropriately adjusting the probability of winning a jackpot in the variable probability gaming state, the probability of winning a variable drop lottery, and the variable number of times given after the end of the jackpot, the expected value of the probability variable gaming state that is advantageous to the player is increased. A gaming machine may be configured in which the settings are unlikely to differ for each setting.

(Performance to increase the number of balls with a small hit)
In addition, in the present embodiment, the second embodiment, and modifications thereof, the explanation is given on the premise that the gaming machine is provided with the V winning opening C22 inside the second big winning opening C20. The first main game pattern display device A20 and the second The second main game symbol display device B20 can be provided with a small win, and the second main game symbol display device B20 can be applied to a game machine having a configuration in which a small win is likely to occur. Below, the playability of the gaming machine will be briefly described.

First, the first main game symbol display device A20 becomes a big hit, and the transition to the time saving state makes it easier to open the second main game starter electric accessory B11d, so the main game is played by the second main game symbol display device B20. becomes. When the second main game symbol display device B20 is configured so that many small wins occur (for example, the configuration shown in FIG. 29), in the time saving state, the second main game symbol display device B20 wins the first big prize due to the small win. The opening C10 (or the second big winning opening C20) is opened, and it becomes possible to win the ball.

In such a gaming machine, the game feature mainly based on the game by the second main game symbol display device B20 is continued until the conditions for ending the time-saving state are satisfied. It is a gaming machine capable of acquiring balls.

(Example regarding execution of look-ahead effect)
In the second embodiment, the configuration without setting values has been described, but as described above, the second embodiment may be configured with a plurality of setting values. An example of execution will be described below as a modification 4 from the second embodiment.

FIG. 92 is an example of the first main game win/loss lottery table (second main game win/loss lottery table) in the case of changing the winning probability of the main game symbols according to the set value. In this example, the setting 1, the setting 2, and the setting 3 are configured so that the profit rate given to the player increases in that order. More specifically, the setting 1 win (jackpot) winning probability during the non-probability variation game is set to about 1/320, and the setting 2 win (jackpot) winning probability during the non-probability variation game is It is set to about 1/318, and the winning probability of setting 3 in the non-probability variation game is set to about 1/317. In addition, the winning (jackpot) winning probability of the setting 1 during the probability variation game is set to about 1/160, and the winning (jackpot) winning probability of the setting 2 during the probability variation game is set to about 1/159. The winning probability of setting 3 (jackpot) during the probability variation game is set to about 1/158. Therefore, the winning (jackpot) winning probability during the probability variation game is about twice the winning (jackpot) winning probability during the non-probability variation game, and the ratio is configured to be common to all settings. . This point is the same for the first main game side and the second main game side.

In addition, as shown in the figure, it is determined to be a hit (big hit) in the setting 2 of the non-probability variation game even in the random value range determined to be a hit (big hit) in the setting 1 at the time of the non-probability variation game. Both the random number range and the random number range determined as winning (jackpot) in the setting 3 at the time of non-probability variation game include "0 to 204" as a common range. Therefore, for example, when a hold with a random value of one of "0 to 204" occurs during a non-probability variation game, the hold is won ( (and if the random number determined to be a hit (jackpot) outside the range of "0 to 204" is not notified in advance), that The higher the frequency that the hold is digested and the winning lottery is performed (resulting in a big hit) without the advance notification (prefetching effect) being executed, the higher the possibility of setting 3 (the set value It can also be configured so that suggestions can be made) (In the order of setting 1, setting 2, and setting 3, the number of random numbers determined as hits (big hits) outside the range of “0 to 204” increases. be). This point can be similarly applied to the probability variation game, and can be applied to both the first main game side and the second main game side. Also, since the random number range determined to be a hit (small hit) for a certain set value does not overlap with the random number range determined to be a hit (big hit) for other set values, which set value is Regardless of whether or not a hit (minor hit) is determined to be a random number that belongs to the range of random values, if a hold occurs, the hold will be a hit (small hit) before the hold is digested and the lottery If you pre-notify that you are going to be a hit), you can pre-notify a win (minor win) regardless of the set value (pre-determination processing related to the look-ahead effect can be shared).

On the other hand, it is also possible to configure so that setting values are not suggested by the look-ahead effect, and an example thereof will be shown below. The look-ahead determination table in the table below is a pre-determination table that the main control board M has. When a suspension occurs, the main control board M derives a prefetch code by referring to the prefetch determination table based on the random value associated with the suspension, and transmits it to the sub control board S. For example, if the main control board M side is set to 3, the sub control board S corresponds to one of the prefetch codes A, B, and C based on the information related to the setting value transmitted from the main control board M in advance. If the main control board M side is set to 2, advance notification of a hit (big hit) is made only in the case of either the look-ahead code A or B, and the main control If the board M side is set to 1, advance notice to the effect that it is a hit (big hit) is given only in the case of the look-ahead code A. By configuring in this way, it becomes difficult to guess the setting on the main control board M side from the execution tendency of the look-ahead effect.

As described above, in order to perform the look-ahead effect, based on the game state (for example, non-probability variation game) and the setting value (for example, setting 1), the random number held as pending is the hit ( It can be inaccurate unless it is determined in advance whether it belongs to the random value range (eg, "0 to 204") that is determined to be a big hit. At that time, if the sub control board S side decides whether or not to execute the look-ahead effect, for example, whether or not the random number value held as reserved belongs to the random number range determined to be a hit (big hit). is required to be determined in advance on the sub-control board S side, and in that case, the sub-control board S side needs information about the set values. However, sending the information about the set values held by the main control board M to the sub control board S is not preferable in terms of security or ensuring the fairness of the game. There is a risk that the information about the setting value may be intercepted and misused at the time, and the information about the setting value is clearly notified to the outside on the sub control board S side (for example, the game hall operator displays it for maintenance purposes). There is also a risk that things can be snooped on by game players}. Therefore, a method for accurately performing the look-ahead effect without transmitting the information on the set values held by the main control board M to the sub-control board S will be described in detail below.

First, in this example, when a new hold occurs, the probability of execution or non-execution of the look-ahead effect lottery is different depending on whether or not the new hold is a hold that will result in a big hit (i.e. , At the time of the look-ahead effect lottery, it is configured to refer to the information on the "win-win lottery random number" related to the new reservation).

In this case, even if the winning/failing lottery random number related to the new reservation is the same, the winning/failing lottery result (whether it is a big hit or not) may differ for each setting. As a result, even if the same variation mode lottery random number is obtained, a situation may arise in which the selected variation mode (for example, variation time) is different. As an example, when a hold occurs where "the ``win-fail random number'' is ``206'' and the variation mode lottery random number is ``900'', the set value 3 results in a ``jackpot'' and a ``fluctuation time of 60 seconds''. , the setting value 1 is "losing" and it is determined that the "fluctuation time is 30 seconds". In this case, in the setting 3, it is configured so that the prefetching effect lottery is easily executed (to increase the probability of the prefetching effect lottery) (in order to notify that the expectation of the big win related to the new reservation is high). is desirable, in setting 1, it may be desirable to configure so that the prefetching effect lottery is difficult to be executed (so that the prefetching effect lottery probability is low). However, if the sub-control board S side does not have information related to the current setting value (the sub-control board S side does not hold the current setting value), the sub-control board S determines that the lottery random number "206" is , As a result of not being able to determine whether it is determined as a "big hit" or a "losing", it is assumed that it is difficult to execute an accurate look-ahead effect.

Therefore, in a gaming machine having a set value, when deciding whether to execute a look-ahead effect lottery (drawing a lottery), without referring to information about the "win-win lottery random number", the "fluctuation mode lottery random number" and/or Alternatively, the configuration may be such that only the information on the "symbol lottery random number" is referred to. As an example, it is confirmed that the fluctuation time related to the newly occurring hold is a long time (for example, 60 seconds). For example, in the main game table 3 of FIG. 92, when the value is any of "1000 to 1023", a long-time (for example, 60 seconds) variation mode is selected regardless of whether it is a big hit or not. }, while executing a prefetch effect lottery that wins with a specific probability (for example, 1/3), it is possible that the fluctuation time is short (for example, 3 seconds, 5 seconds, or 10 seconds). {This is the case where it is a "variation mode lottery random number" belonging to such a fixed random number range, for example, when it is one of "0 to 2" in the main game table 3 of FIG. , a short-time (for example, 3 seconds, 5 seconds, or 10 seconds) variation mode is selected regardless of whether it is a big hit}, a predetermined probability that is lower than the specific probability ( For example, a pre-reading effect lottery that wins at 1/50) is executed. By configuring in this way, it is possible to accurately carry out the look-ahead effect with respect to "suggesting that the variable time related to the newly occurring suspension is scheduled to be long" as the look-ahead effect.

Similarly, when executing a pre-reading effect lottery by referring only to the "symbol lottery random number", "when a new reservation occurs, a pre-reading effect lottery is performed based only on the symbol lottery random number, and the newly generated reservation It can also be read as "a production that suggests which of the stopped symbols is" (a production that suggests the type of symbol (whether or not it is a probability fluctuation jackpot symbol) if the new hold is a jackpot). .

Next, another method for accurately performing the look-ahead effect without transmitting information about the set values held by the main control board M to the sub-control board S method) will be described below as a modification 5 from the second embodiment.

FIG. 93 is a flowchart of main game content determination random number acquisition processing in this example. The difference from FIG. 26, which is the present embodiment, is that in step 1316-1 (second variation 5), the CPUMC of the main control board M performs pre-reading determination processing.

Next, FIG. 94 is a flow chart relating to a subroutine of pre-reading determination processing in this example. First, in step 1316-1-2, the CPUMC of the main control board M determines whether or not the current setting value is 3 (=setting 3). In the case of Yes in step 1316-1-2, in step 1316-1-3, the CPUMC of the main control board M displays the success/failure determination table in setting 3 (this success/failure determination table has the same contents as the success/failure lottery table). , which is provided as a separate table because the reference timing is different), and determines whether or not the acquired second main game content determination random number is a win (jackpot). In the case of Yes in step 1316-1-3, in step 1316-1-4, the CPUMC of the main control board M changes the limited frequency counter value, pending information (holding number including the acquired random value, variable mode random number) Based on this, refer to the corresponding limited frequency table for judgment at the time of winning (this limited table for judgment has the same contents as the limited frequency table, but is provided as a separate table because the reference timing is different). , determine the variation mode. On the other hand, in the case of No in step 1316-1-3, the CPUMC of the main control board M, based on the limited frequency counter value and the hold information (the number of holds including the obtained random number, the variable random number), The variation mode is determined by referring to the limited frequency table of . Next, if No at step 1316-1-2, at step 1316-1-6, the CPUMC of the main control board M determines whether or not the current setting value is 2 (=setting 2). In the case of Yes in step 1316-1-6, in step 1316-1-7, the CPUMC of the main control board M displays the success/failure determination table in setting 2 (this determination table has the same content as the success/failure lottery table, Since the reference timing is different, it is provided as a separate table), and it is determined whether or not the acquired second main game content determination random number is a win (jackpot). In the case of Yes in step 1316-1-7, in step 1316-1-8, the CPUMC of the main control board M sets the limited frequency counter value, pending information (holding number including the acquired random value, variable mode random number) Based on this, refer to the corresponding limited frequency table for judgment at the time of winning (this limited table for judgment has the same contents as the limited frequency table, but is provided as a separate table because the reference timing is different). , determine the variation mode. On the other hand, in the case of No in step 1316-1-7, in step 1316-1-9, the CPUMC of the main control board M outputs the limited frequency counter value, pending information (a pending number including the obtained random value, a variation mode random number ), the variation mode is determined by referring to the corresponding limited frequency table at the time of loss. Next, if No at step 1316-1-6, at step 1316-1-10, the CPUMC of the main control board M determines whether or not the current setting value is 1 (=setting 1). In the case of Yes in step 1316-1-10, in step 1316-1-11, the CPUMC of the main control board M displays the success/failure determination table in setting 1 (this determination table has the same content as the success/failure lottery table, Since the reference timing is different, it is provided as a separate table), and it is determined whether or not the acquired second main game content determination random number is a win (jackpot). In the case of Yes in step 1316-1-11, in step 1316-1-12, the CPUMC of the main control board M changes the limited frequency counter value, pending information (holding number including the acquired random value, variable mode random number) Based on this, refer to the corresponding limited frequency table for judgment at the time of winning (this limited table for judgment has the same contents as the limited frequency table, but is provided as a separate table because the reference timing is different). , determine the variation mode. On the other hand, in the case of No in step 1316-1-11, the CPUMC of the main control board M, based on the limited frequency counter value and the hold information (the hold number including the obtained random number, the variation mode random number), The variation mode is determined by referring to the limited frequency table of . After the processing of steps 1316-1-4, 1316-1-5, 1316-1-8, 1316-1-9, 1316-1-12, and 1316-1-13, step 1316- At 1-14, the CPUMC of the main control board M sets the read-ahead pass/fail command and the read-ahead variation mode command based on the pass/fail determination result and the variation mode determination result, and proceeds to the next process (step 1318). Transition. Note that even if No in step 1316-1-10, the process proceeds to the next process (step 1318).

In this way, when the CPUMC of the main control board M acquires a random number value (for example, a random number value for the main game, a variation mode random number value), it determines whether it is right or wrong according to the set value, and then determines the variation mode. , and by transmitting the pass/fail judgment result (read-ahead pass/fail command) and the variation mode result (pre-read variation mode command) to the CPUSC of the sub-control board S, the CPUSC of the sub-control board S can change the set value on the main control side It is possible to determine the execution of the prefetch effect according to the success or failure result and the variation mode without being affected by the result.

In this example, the configuration is such that the read-ahead judgment processing is performed before the acquired random number is reserved (that is, the random number acquired in the acquired register is directly judged). It is also possible to configure such that after once storing the random number value in the RAM, the stored random number value is read out and pre-reading determination processing is performed.

Next, FIG. 95 is a flow chart of the look-ahead effect execution determination process in this example. In this example, in the pending information management process of the present embodiment, the look-ahead effect execution determination process (step 2150 (second variant 5)) is executed before the process of step 2418-1 is executed.

In the look-ahead effect execution determination process, first, in step 2152, the CPUSC of the sub control board S determines whether or not the look-ahead effect execution counter value is zero. If Yes at step 2152 , at step 2155 , the CPUSC of the sub control board S determines whether or not there is a hit hold in the hold. On the other hand, if No in step 2155, the process proceeds to the next step. Next, at step 2156, the CPUSC of the sub control board S determines whether or not the currently set (temporarily stored) stay stage is the "long effect stage".

In the case of Yes in step 2156, in step 2158, the CPUSC of the sub control board S prejudges the variation time based on the look-ahead variation mode command transmitted from the CPUMC of the main control board M. FIG. Next, at step 2160, the CPUSC of the sub-control board S determines whether or not it is confirmed that the new suspension fluctuation time will be a predetermined time (for example, 10 seconds) or longer. Here, when determining the fluctuation time in advance, for example, if the new hold fluctuation mode random value is 900 to 1023, regardless of the number of holds at the time of digestion of the new hold, the fluctuation time is 10 seconds or more. It can be determined that

In the case of Yes at step 2160, at step 2162, the CPUSC of the sub control board S determines whether or not the new hold is a hold that will result in a big hit (for example, the determination is made based on a winning lottery random number). In the case of Yes at step 2162 , at step 2164 , the CPUSC of the sub control board S executes a pre-reading effect lottery to win with a predetermined probability (for example, 1/3), and proceeds to step 2176 . On the other hand, in the case of No in step 2162, in step 2166, the CPUSC of the sub control board S determines that the winner is selected with a predetermined probability (for example, 1/5, but the probability is lower than the winning probability in step 2164). A look-ahead effect lottery is executed, and the process proceeds to step 2176.例文帳に追加

On the other hand, if No at step 2156, at step 2168, the CPUSC of the sub control board S determines whether or not the stay stage currently set (temporarily stored in the RAM area) is the "fixed effect stage". In the case of Yes at step 2168, at step 2170, the CPUSC of the sub control board S determines whether or not the new hold is a hold that will result in a big hit (for example, the determination is made based on the winning lottery random number). In the case of Yes in step 2170 , in step 2172 , the CPUSC of the sub control board S executes a pre-reading effect lottery to win with a predetermined probability (for example, 1/4), and proceeds to step 2176 . On the other hand, in the case of No in step 2170, in step 2174, the CPUSC of the sub control board S determines that the winner is selected with a predetermined probability (for example, 1/6, but the probability is lower than the winning probability in step 2172). A look-ahead effect lottery is executed, and the process proceeds to step 2176.例文帳に追加

Next, at step 2176, the CPUSC of the sub-control board S determines whether or not the prefetch effect lottery (lottery of step 2164, step 2166, step 2172, or step 2174) has been won. In the case of Yes at step 2176, at step 2178, the CPUSC of the sub control board S refers to the pending number temporarily stored in the RAM area of the sub control board S, and the hold (trigger hold) winning the lottery is canceled. To derive the fluctuation stop count Ha (0 to 4 times) of the main game pattern. Next, at step 2180, the CPUSC of the sub-control board S refers to the stay stage management counter, and based on the counter value, derives the number of times Hb of fluctuation stop of the main game symbols until the current stay stage ends.

Here, the fluctuation stop count Hb also includes the fluctuation stop count of the symbol that is currently being variably displayed. In addition, as will be described later, whether or not the look-ahead effect can be executed is determined at the start of the fluctuation, so if the pattern is in the process of changing, the look-ahead effect can be executed from the next change after the design during the change stops. be.

Next, in step 2182, the CPUSC of the sub control board S determines that the number of times of executing the look-ahead effect (Ha in this example) is the minimum number of times of look-ahead effect (the minimum number of times for executing an effective look-ahead effect, for example , twice). In the case of Yes in step 2182, in step 2184, the CPUSC of the sub control board S determines that the derived Ha and Hb satisfy the relationship Ha≦Hb (the look-ahead effect ends during the current stay stage). Determine whether or not In the case of Yes at step 2184, at step 2186, the CPUSC of the sub control board S sets Ha to the look-ahead effect execution counter, and proceeds to the next process. If No in any of steps 2152, 2154, 2160, 2168, 2176, 2182, and 2184, the process proceeds to the next step.

In this way, if the look-ahead effect over multiple variations does not end during the current stay stage, the look-ahead effect is not executed (especially step 2184), so that the table switching and the look-ahead effect are executed at the same time. Therefore, it is possible to avoid a situation in which the player is confused. After executing the prefetch effect lottery, it may be configured to determine whether or not the prefetch effect can be executed according to the determination whether to step over the stay stage, or the order of processing related to the prefetch effect may be changed as appropriate. For example, it may be configured to execute the prefetch effect lottery after it is determined that the stay stage is straddled (that is, if it is planned to straddle the stay stage, the prefetch effect lottery itself is not executed in the first place. ).

Note that the look-ahead effect in this example may also include a change related to the trigger hold, that is, the multiple changes in the look-ahead effect over multiple changes may include the change related to the trigger hold. For example, an effect of the same mode or an effect of the same system may occur from a change before the change related to the trigger suspension to the change related to the trigger suspension.

Note that this example is only an example, and is not limited to this. For example, even if the end of the look-ahead effect over multiple fluctuations is after the current stay stage ends (or switches), the look-ahead effect can be executed, When the look-ahead effect that spans multiple fluctuations straddles the end (or switching) of the stay stage, the expectation of a big hit in any of the fluctuations related to the look-ahead effect is a look-ahead that does not straddle the end (or switching) of the stay stage It may be configured to be relatively higher than when performing the production. In such a configuration, it is possible to attract the player's attention to whether or not the look-ahead effect will occur across the end (or switching) of the stay stage (and effect), and the interest of the game. It is possible to improve the quality of the product.

In addition, if the pre-reading effect over multiple fluctuations can be executed even after the current stay stage ends (or switches), the pre-reading effect will continue until the final change when the current stay stage ends. It may be configured to end (interrupt) with Further, when the look-ahead effect is interrupted, a look-ahead effect different from the interrupted look-ahead effect (for example, a look-ahead effect in line with the effect at the stay stage after switching or other effects) can be executed instead. may Furthermore, it is possible to configure so that the current stay stage is not finished (or switched), at least visually, until the look-ahead effect over multiple variations is finished.

In addition, in a certain stay stage, a foreseeing effect informing that a high-expectation-level effect or a variation mode with a long variation time will be selected in subsequent fluctuations occurs, and at the certain stay-stage, the high-expectation-level effect or If a variation mode with a long variation time is not selected, the high expectation performance or a variation mode with a long variation time may be selected in the next stay stage. In addition, in such a configuration, it is desirable that the look-ahead effect in the next stay stage should be the effect in line with the next stay stage.

(Another example of execution of look-ahead effect)
Further, the information about the random number held as pending in the main control board M can be transmitted to the sub-control board S, and whether or not it is determined to be a hit (jackpot) at the end of the hold can be determined by the main control. By transmitting information on whether or not a special game has occurred from the board M to the sub control board S, the sub control board S side can grasp it. Focusing on such a premise configuration, another technique for accurately performing the look-ahead effect without holding the information on the set value on the sub-control board S side can be mentioned.

More specifically, under the non-probability variation gaming state, the information about the random number held as a certain reservation in the main control board M is transmitted to the sub control board S as "204", and the certain When information to the effect that there is a special game occurrence is transmitted from the main control board M to the sub control board S at the end of the hold, the main control is performed after the special game is executed and in a non-probability variable game state. When the information about the random value held as another hold in the board M is transmitted to the sub-control board S as "204", the sub-control board S side will Since it can be presumed that a special game is scheduled to occur in advance, the sub-control board S, based on this presumption, performs a pre-reading effect (advance notification) regarding a hit (jackpot) before the other hold is completed. become executable.

That is, on the sub-control board S side, the information about the retained random number value and the event that occurred when the retention was completed are accumulated as a game history (the sub-control board S side learns and By doing so, the look-ahead effect based on the game history can be accurate as advance notification of a hit (big hit).

However, in this way, the information about the random number held as a hold and the event that occurred when the hold was completed are accumulated as a game history (the sub control board S side learns). In the method of improving the accuracy of the look-ahead effect based on the game history, it is necessary as a precondition that the setting on the main control board M side is maintained (fixed) at a certain set value, so the main control When the sub-control board S side guesses and grasps that the setting value on the board M side has been changed (for example, when there is a power failure, a command to the effect that the setting value has been changed is issued from the main control board M side. is sent), it is desirable to clear the information accumulated up to that point and re-accumulate it.

In addition, when the first main game success/failure lottery table (second main game success/failure lottery table) possessed by the main control board M is set in a random number range as shown in FIG. 92, a non-probability variable gaming state. In this situation, the information about the random value held as a certain hold in the main control board M is transmitted to the sub control board S as "206", and when the certain hold is completed, the main control board M sends a special When information indicating that a game has occurred is sent to the sub control board S, {because only setting 3 is determined to be a hit (jackpot) with the random value "206"}, the main control board M holds it. Even if the information about the set values that are currently set is not transmitted to the sub control board S (in other words, even if the information about the set values is not held on the sub control board S side), the sub control board S side (In that case, the sub-control board S side holds in advance the correspondence relationship that the random number "206" is determined to be a hit (jackpot) = setting 3. must be kept).

Furthermore, the first main game win-fail lottery table (second main game win-fail lottery table) of the main control board M has a random value range as shown in FIG. If it is set and the sub control board S side has a similar table, that is, the random value range determined to be a hit (big hit) at a certain set value is determined to be a hit (big hit) at another set value. If it does not overlap with the random value range to be determined (in this example, non-probability fluctuation gaming state and setting 1: 0 to 204, non-probability fluctuation gaming state and setting 2: 205 to 410, non-probability fluctuation gaming state and setting 3: 411 to 617), under the non-probability variation gaming state, the information about the random number held as a certain hold in the main control board M is sent to the sub control board S as any of "411 to 617". , when information indicating that a special game has occurred is transmitted from the main control board M to the sub control board S at the end of the certain hold, the information on the set values held by the main control board M is sent to the sub control board S (in other words, even if the sub control board S side does not hold information about the set value), the sub control board S side can grasp that the main control board M side is setting 3. . Therefore, when configured in this way, the sub control board S side can quickly grasp which setting value is set on the main control board M side.

Similarly, under the non-probability variation gaming state, the information on the random number held as a certain reservation in the main control board M is transmitted to the sub control board S as any one of "0 to 204". , when the main control board M does not send the information indicating that there is a special game to the sub control board S at the end of the certain hold (in the case of "losing"), the sub control board S side is the main control board. Since it is possible to grasp that the control board M side is set to 2 or 3, from this point of view, the sub control board S side can determine which setting value is set on the main control board M side. It can be said that it is possible to quickly grasp whether there is

In each embodiment described above (particularly, an embodiment having a plurality of setting values), the main control board M grasps the setting value information, and based on the grasped setting value information, draws a lottery table for the main game symbols. In the past, processing such as selection was performed, but by configuring not only the sub control board S but also the control program of the main control board M so that the setting information cannot be grasped, it can be expected to strengthen against fraud etc. . Therefore, as a modified example, a configuration in which parameters such as winning values can be set independently of the control program of the main control board M (CPU) will be exemplified as Modified Example 7 from the second embodiment.

Specifically, in this modified example, a winning probability table corresponding to set values (three levels of settings 1 to 3 in this modified example) is stored in the winning value data storage device Q20, which is an area separate from the normal storage area. , the CPUMC of the main control board M can read the data such as the winning value according to the setting value set by the setting changing means Q10 among the data such as the winning value stored in the winning value data storage device Q20. configured to allow 97, the CPUMC of the main control board M and the winning value data storage device Q20 are connected by an 8-bit data bus. They are electrically connected so as to be able to transmit a lower address (for example, the lower 2-bit "A0/A1" address signal line) of the data storage device (ROM) Q20 and a read request signal (for example, a read signal). In addition, a terminal corresponding to the upper address (for example, the address of "A14/A15") of the winning value data storage device (ROM) Q20 is connected to the setting change means Q10. The corresponding signal is designed to be designated data of the upper address (for example, the address of "A14 and A15") of the winning value data storage device Q20.

Next, the configuration of the setting change means Q10 in the schematic block diagram will be described in detail. The setting change means Q10 in this modified example includes a setting key switch similar to a rotary switch, and three set value display LEDs for informing setting values 1 to 3 operated by the setting key switch. The setting key switch in this modified example is configured to rotate two steps to the right after the setting key is inserted, and is urged to the first step position between the first step and the second step. there is When a setting key is inserted into such a setting key switch and rotated one step to the right, the setting value display LED corresponding to the currently selected setting value lights up. The set value is incremented by 1 each time it is rotated to the right rotatable position. In addition, the set value is configured to return to the minimum value of 1 when the dial is rotated once more in a state where the maximum set value of 3 is set. Then, the setting value set by the setting key switch is held by the setting change means Q10, and is a 2-bit signal ("01" for setting 1, "10" for setting 2, and "11" for setting 3). ”), and the output data is electrically connected so as to be input to the high-order bit terminals of the winning value data storage device (ROM) Q20 as described above.

Next, the configuration of the winning value data storage device (ROM) Q20 in the schematic block diagram will be described in detail. The winning value data storage device (ROM) Q20 in this modified example exemplifies a storage device having 8-bit data storage areas corresponding to 16-bit addresses from 0000h to FFFFh, as shown in the table of FIG. As shown, the hit value for each set value is a non-probability fluctuation game state (low probability)/probability fluctuation game It is stored for each state (high probability). The read terminal (terminal requesting readout) of the winning value data storage device (ROM) Q20, the lower 2-bit address, and the data bus are connected to the CPUMC of the main control board M. FIG. Although illustration is omitted in the schematic block diagram, the address buses from "A3" to "A13" are connected to GND, and access to areas other than the storage areas corresponding to the addresses shown in the table of FIG. has become impossible.

(action)
Next, regarding the flow of reading the winning value corresponding to each set value in this modified example, the set value "1" is set by the setting change means Q10, and the game state is the normal game state (non-probability variable game state). A certain case will be exemplified and explained. When the CPUMC of the main control board M executes a predetermined process to refer to the winning value (for example, when performing a winning lottery), among the addresses corresponding to the normal gaming state (non-probability variable gaming state), A data address (00h) corresponding to the lower value of the value is specified, and the data of the specified address is read. Then, since the upper address of the winning value data storage device (ROM) Q20 is fixed to "4000h" corresponding to the set value "1" by the output data from the setting change means Q10, it is the data of "4000h". "11001100" is output from the data bus. Then, the CPUMC of the main control board M takes in the value "11001100" output to the data bus once into a register or the like, and then selects the winning value from the addresses corresponding to the normal game state (non-probability variation game state). The data (01h) corresponding to the upper value of is specified, and the data of the specified address is read. Then, since the upper address of the winning value data storage device (ROM) Q20 is fixed to "4000h" corresponding to the set value "1" by the output data from the setting change means Q10, the data of "4001h" is changed to " 00000000” is output from the data bus. Then, the CPUMC of the main control board M takes the value "00000000" output to the data bus into a register or the like, and combines it with the data "11001100" of the lower address previously taken in to obtain a 16-bit value "0000000011001100". (205 in decimal)” is obtained. Then, the CPUMC of the main control board M compares the random number "N" for winning/failure judgment with the winning value obtained as described above, and the random number "N" is equal to or less than the winning value (N≦winning value). If the winning value is equal to or less than the winning value, it is determined as winning.

With the configuration as described above, the CPUMC of the main control board M can implement a lottery according to the set value, although it does not know what the set value is in the first place. Amusement machines can be provided.

In this modified example, a storage device (ROM) storing a normal program and another storage device (ROM) are used, but a common storage device (ROM) is used to store part of the winning value data. It is also possible to allocate data to a storage area and operate the read target address from the outside as described above for the corresponding area. In addition, in this modified example, hardware is configured to read the storage area corresponding to the set value, but it is also possible to secure fraud prevention by imposing certain restrictions on software.

Specifically, in the process (initialization process after power-on) before shifting to the main routine in the main control board M in each embodiment, the output information (set value) from the setting change means Q10 is read and read. To specify a storage area for a winning value according to output information (to specify a storage area to be read at the time of winning/failure lottery). In other than the initialization process, that is, in the main routine process and the interrupt process that shift after the completion of the initialization process, there is no need to provide the process of reading the output information (set value) from the setting change means Q10. configured to use the winning value of By configuring in this way, it is possible to configure a program that cannot read the set value information except at a specific time (other than the initialization process) such as after power-on, which can be expected to contribute to fraud prevention. .

As described above, in each embodiment, by specifying the storage area of the winning value table according to the set value under predetermined conditions (under predetermined restrictions) by hardware and software, While the lottery etc. are performed with a high probability, the set value information cannot be confirmed in the normal processing routine in the main control board M, so the set value information can be obtained not only in the main control board M but also in the sub control board S. can be expected to effectively deter fraud such as stealing setting value information.

In the pre-reading determination process described above, it is configured to determine whether or not to execute the pre-reading effect by referring to the set value, but the present invention is not limited to this, and the pre-reading effect is executed without referring to the set value. may be configured to Specifically, the prefetching code A (random number range that becomes a big hit regardless of the setting value) and the prefetching code D (random number range that becomes a small hit regardless of the setting value), the prefetching code E (the setting value If it is determined to be a random number range that will result in a loss regardless of the value), the prefetch lottery can be executed, while the prefetch code B and C (random numbers that may result in a big hit or a loss depending on the set value) are determined. In this case, the prefetch lottery may be configured not to be executed.

By configuring as described above, the sub-control board can be configured to be able to execute the look-ahead effect using common processing regardless of the set value.

It should be noted that the setting values may be grasped by the sub-control board S side by configuring so that the information about the setting values can be transmitted from the main control board M side to the sub-control board S side. In such a configuration, a specific advance notice effect may be configured to be executable, and the probability of occurrence of the specific notice effect may differ depending on the setting value, or a specific setting value (for example, setting It may be configured so that a specific advance notice effect can be executed only in the case of 6). In addition, an upper limit number of selections for a predetermined effect is provided for each set value (for example, the upper limit number of selections is reset by clearing the RAM), and in setting 1 to setting 5, the upper limit number of selections is less than the specific number of times. In 6, the upper limit number of selections may be configured to be a specific number of times or more, so that the player can recognize that the set value is the setting 6 when a predetermined effect is executed more than the specific number of times. With such a configuration, the player can play the game while estimating the set value currently set by paying attention to whether or not the specific effect is executed or the execution frequency of the specific effect. It is possible to provide a game machine with a high

(Structure for transmitting a command related to a setting change operation from the CPUMC of the main control board M to the CPUSC of the sub control board S)
As described above, in a game machine that does not transmit setting values from the CPUMC of the main control board M to the CPUSC of the sub-control board S, by configuring to transmit information different from the setting values, the CPUSC of the sub-control board S It is possible to comprehend the setting value currently set, but a switch (for example, RAM clear button, setting change button, etc.) for changing settings from CPUMC of main control board M to CPUSC of sub control board S It is also preferable to send a command to press a button) and infer the setting value based on this information. Specifically, in the case of a configuration in which the setting value is changed by pressing the RAM clear button, when the RAM clear button is pressed (during RAM clearing, setting change operation), a command indicating pressing of the RAM clear button is sent to the main control board By configuring to transmit from the CPUMC of M to the CPUSC of the sub-control board S, the CPUSC of the sub-control board S can check the number of times the command is received after power-on under a predetermined condition (for example, the first time after power-on). command is ignored because it is the operation of the RAM clear button for executing the setting change). For example, the CPUSC of the sub-control board S controls the end of the setting change after the setting key switch is turned ON until the setting key switch is turned OFF (that is, when the command indicating the start of the setting change is received). counts the number of times the RAM clear button (or setting change button) input command is received. For example, the initial value of the counter that counts the number of times the input command of the RAM clear button (or setting change button) is received is set to "1" (setting 1) in 6 steps from "1" to "6". In this case, if eight RAM clear button input commands are received while the settings are being changed, when the RAM clear button is pressed once, the value of the counter that counts the number of times the RAM clear button input command is received becomes "2". When the RAM clear button is pressed twice, the value of the counter that counts the number of times the input command of the RAM clear button is received becomes "3", and the RAM clear button is changed to "setting 3". When the RAM clear button is pressed three times, the value of the counter that counts the number of times the input command of the RAM clear button is received becomes "4" and is changed to "setting 4", and when the RAM clear button is pressed four times, the input command of the RAM clear button If the RAM clear button is pressed five times, the value of the counter that counts the number of times the input command of the RAM clear button is received changes to "5" and changes to "setting 5". is changed to "setting 6", and when the RAM clear button is pressed six times, the value of the counter that counts the number of times the input command of the RAM clear button is received becomes "1" and changed to "setting 1", and the RAM is cleared. When the button is pressed 7 times, the value of the counter that counts the number of times the input command of the RAM clear button is received becomes "2" and changes to "setting 2", and when the RAM clear button is pressed 8 times, the RAM clear button Since the value of the counter that counts the number of times the input command is received becomes "3" and is changed to "setting 3", the CPUSC of the sub-control board S presumes that the current setting value is set to "setting 3". be able to. The value of the counter that counts the number of times the RAM clear button input command is received is configured so that it is not cleared by a power failure due to a backup power source or the like. The value of the counter that counts the number of times starts from "3", and when the RAM clear button is pressed once, the value of the counter that counts the number of times the input command of the RAM clear button is received changes to "4" and becomes "setting 4". Be changed. In this way, the CPUSC of the sub-control board S stores the information of the estimated setting value so that it will not be cleared even when the power is cut off. It is possible to continue counting the number of times the button input command is received. It is supplemented that the set value on the main control side and the set value on the sub control side become the same by configuring to clear the counter that counts the number of times the input command of the RAM clear button on the board S side is received. . At this time, the CPUSC of the sub-control board S determines that the counter for estimating the setting value is a counter that makes one round with the number of maximum setting values (=N) (in this example, N=“6”, so 6 counts). However, a counter for cumulatively counting the number of receptions of all RAM clear button input commands during setting change is provided, and the number of N-1 (5 in this example) is provided. ) can also be calculated. For example, when the counter is 211, division by 5 gives a remainder of 42, and the remainder "1" represents the set value. Here, the value of the counter for counting the number of times the input command of the RAM clear button received from the main control board M in the sub control board S was explained using "1" to "6". , may be replaced with set value data "0" to "5" for processing.

It should be noted that the input command of the RAM clear button is transmitted from the CPUMC of the main control board M to the CPUSC of the sub control board S every time the RAM clear button is pressed as the setting value change operation, but the present invention is not limited to this. The CPUMC of the main control board M counts the number of times the RAM clear button is pressed during the setting change, and transmits a command based on the counted count to the CPUSC of the sub control board S when the setting change is completed. Alternatively, the CPUMC of the main control board M may be configured to transmit to the CPUSC of the sub control board S a command based on the difference between the previous set value and the current set value.

Next, a configuration in which it is difficult for the player to determine whether the setting has been changed or a configuration in which the player can determine (guess) whether the setting has been changed will be shown.

(Third Embodiment)
In the above embodiment, the RAM is cleared when the settings are changed. B21g), there is a concern that the symbols displayed in the auxiliary game symbol display portion H21g will be cleared, and the player will be able to easily determine that there is a possibility that the settings have been changed. More specifically, when the power is restored only by turning on the power switch Ea, the RAM is not cleared, and regardless of whether or not the setting has been changed, the RAM is cleared, and the RAM is not cleared. , the symbols displayed in the main game symbol display portion and the auxiliary game symbol display portion H21g are different (When the RAM is cleared: the symbol data is cleared. When power is restored only by turning on the power switch Ea: the symbol data is not cleared). This means that if the design data has been cleared, at least the RAM has been cleared by operating the RAM clear button or by changing the settings. Conversely, if the design data has not been cleared. indicates that the setting has not been changed. That is, after the opening of the gaming parlor, the player confirms whether or not the symbols in the main game symbol display portion or the auxiliary game symbol display portion H21g of the first selected gaming machine are cleared, thereby changing the setting. Although it is not possible to accurately grasp whether or not the setting has been changed, at least it is possible to distinguish between "tables on which settings may have been changed" and "tables on which settings have not been changed." Therefore, as a third embodiment, a configuration of a gaming machine in which it is difficult to determine whether or not the setting has been changed will be described. Since the third embodiment additionally includes a configuration that makes it difficult to determine whether or not a setting change has been made in the above-described embodiment, the description of the same processing as in the present embodiment is omitted or A simplified description will be given with reference to the drawings, focusing on the differences.

FIG. 98 is a flowchart of the main control board side main processing performed by the CPUMC of the main control board M in the third embodiment. Differences from this embodiment are step 1005 (third), step 1011-1 (third), step 1011-2 (third), and step 1011-3 (third). In this embodiment, although not shown (FIG. 7), when the RAM is cleared, the first main game symbol display portion A21g, the second main game symbol display portion B21g, the auxiliary game symbol display portion As display data to H21g, the data at the time of RAM clearing (light-off data) is set, and when RAM clearing is not performed, the data at the time of power failure is set.

That is, after the setting change processing in step 1003 is performed, or after it is determined that the RAM clear button is operated in step 1002, the RAM is cleared in step 1004, and then in step 1005 (third). , the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g. Next, if No at step 1010, at step 1011-1 (third), it is determined whether or not the player is waiting for a game. If Yes in step 1011-1 (third) {That is, during fluctuation, during design determination (during the design fixing time at the time of loss, during the start demonstration at the time of winning, etc.), during the game standby such as during the big hit, during the small hit, etc. If not}, in step 1011-2 (third), set the data at the time of power failure to be displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g. . If No in step 1011-1 (third) (that is, in the case of game standby), in step 1011-3 (third), the first main game symbol display portion A21g and the second main game symbol display portion B21g, the initial data to be displayed in the auxiliary game symbol display portion H21g are set. After the processing of steps 1011 - 2 (third) and 1011 - 3 (third) is completed, the process proceeds to step 1012 . Based on the data set in step 1005 (third), step 1011-2 (third), and step 1011-3 (third), after enabling the timer interrupt, LED output processing of timer interrupt processing (see FIG. 10). The symbol is displayed by step 1550-6). As a supplement, "during game standby" means a situation in which the main game patterns can be started to change, and "determining the patterns" means that the main game patterns are being displayed and the change is to be started. is impossible. For example, during the design fixing time of the losing pattern (for example, 500 ms), it is not possible to start the fluctuation even if there is a hold, so it can be said that "the design of the losing pattern is being fixed", and the design fixing time of the losing pattern , it is possible to start the variation, so it can be said that it is "playing standby".

When the RAM is cleared, the design of the initial data is displayed, and it is possible to determine that there is a possibility that the setting has been changed by confirming whether it is the mode of the stop design of the previous day or the design of the initial data. However, in this way, when changing settings, when clearing the RAM, when power is restored when the game is not in progress (=during game standby), the first main game symbol display portion A21g and the second main game symbol display portion A21g are displayed. By configuring B21g and the auxiliary game symbol display part H21g to display predetermined initial data, is it a state in which the RAM has been cleared, or a state in which the power failure has been restored without clearing the RAM? becomes difficult to determine.

(Modification 1 of the third embodiment)
Next, FIG. 99 is a flowchart of main processing on the main control board side performed by the CPUMC of the main control board M in Modification 1 of the third embodiment. Differences from the third embodiment are step 1005-1 (third variant 1) and step 1011-2-1 (third variant 1).

That is, after the setting change processing in step 1003 is performed, or after it is determined that the RAM clear button has been operated in step 1002, the RAM is cleared in step 1004, and then step 1005-1 (third In variation 1), the configuration is such that the losing symbols to be displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are selected, and the selected losing symbols are set as initial data. It is Next, if No in step 1007 and step 1010, in step 1011-2-1 (third variation 1), the first main game symbol display portion A21g, the second main game symbol display portion B21g, the auxiliary game symbol display portion Data at the time of power failure to be displayed in H21g is set, and the process proceeds to step 1012. Based on the data set in step 1005-1 (third variation 1) and step 1011-2-1 (third variation 1), after enabling the timer interrupt, LED output processing of the timer interrupt processing (step in FIG. 10 1550-6) displays the design.

The difference from the third embodiment is that the pattern data to be set after the RAM is cleared and the pattern data to be set when power is restored without clearing the RAM. In 1, the data of the lost pattern is set after the RAM is cleared, and the data at the time of the power failure is set regardless of whether or not the game is on standby when the power failure is restored without clearing the RAM. When changing from the present embodiment, either the third embodiment or modification 1 of the third embodiment may be adopted.

In this way, when the settings are changed and the RAM is cleared, the selected losing symbols are displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g. It becomes difficult to determine whether the RAM has been cleared or whether the game has stopped after a failure.

(Modification 2 of the third embodiment)
Next, FIG. 100 is a flow chart of the main control board side main processing performed by the CPUMC of the main control board M in Modification 2 of the third embodiment. Differences from the third embodiment are step 1005-2 (third variation 2) and step 1011-2-2 (third variation 2).

That is, after the setting change process in step 1003 is performed, or after it is determined that the RAM clear button has been operated in step 1002, the RAM is cleared in step 1004, and then step 1005-2 (third In variation 2), the symbols displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are all symbols (all symbols including winning symbols and losing symbols). , and the selected pattern is set as initial data. Next, if No in step 1007 and step 1010, in step 1011-2-2 (third variation 2), the first main game symbol display portion A21g, the second main game symbol display portion B21g, the auxiliary game symbol display portion Data at the time of power failure to be displayed in H21g is set, and the process proceeds to step 1012. Based on the data set in step 1005-2 (third variation 2) and step 1011-2-2 (third variation 2), after enabling the timer interrupt, LED output processing of timer interrupt processing (step in FIG. 10 1550-6) displays the design.

In this way, at the time of changing the settings and clearing the RAM, the symbols randomly selected from all symbols are displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g. This configuration makes it difficult to determine whether the setting has been changed and the RAM is cleared, or whether the setting has not been changed and the RAM is cleared.

In the case of recovery from power failure {step 1011-2-2 (third variation 2)} without clearing the RAM, the pattern to be displayed is randomly selected and data is set in the same way as when clearing the RAM. may be With such a configuration, it becomes impossible to determine the possibility that the RAM has been cleared by confirming whether or not the mode of the stop symbols has been changed since the previous day. In particular, in the case of a gaming machine having a plurality of losing symbols, by comparing the losing symbols of the previous day and the next day, it becomes easy to determine the possibility that the RAM has been cleared. However, this configuration makes it impossible to determine that the RAM may have been cleared.

(Modification 3 of the third embodiment)
Next, FIG. 101 is a flow chart of the main control board side main processing performed by the CPUMC of the main control board M in Modification 3 of the third embodiment. Differences from the third embodiment are step 1004 (third variant 3), step 1050 (third variant 3), step 1005-3 (third variant 3), step 1052 (third variant 3), step 1011 -2-3 (3rd variation 3).

That is, after the setting change process of step 1003 is performed, or after it is determined that the RAM clear button has been operated in step 1002, RAM clear is performed in step 1004 (third change 3). However, in the RAM clearing of step 1004 (third variant 3) in modification 3 of the third embodiment, the data of the first main game symbols, second main game symbols, and auxiliary game symbols are configured not to be cleared. Next, at step 1050 (third variation 3), it is determined whether or not data of the first main game symbol, the second main game symbol and the auxiliary game symbol are correctly stored in the RAM. If Yes at step 1050 (third variation 3), at step 1005-3 (third variation 3), the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g It is configured to set the power failure data to be displayed. If No at step 1050 (third variation 3), at step 1052 (third variation 3), the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g It is configured to set predetermined initial data to be displayed. Next, if No in step 1007 and step 1010, in step 1011-2-3 (third variation 3), the first main game symbol display portion A21g, the second main game symbol display portion B21g, the auxiliary game symbol display portion Data at the time of power failure to be displayed in H21g is set, and the process proceeds to step 1012. Based on the data set in step 1005-3 (third variant 3), step 1052 (third variant 3), and step 1011-2-3 (third variant 3), timer interrupt processing after enabling timer interrupt The pattern is displayed by the LED output processing (step 1550-6 in FIG. 10).

Thus, when the data of the first main game symbols, the second main game symbols, and the auxiliary game symbols are correctly stored in the RAM after the RAM is cleared, the first main game symbol display area A21g and the second main game symbol display area A21g are displayed. When the predetermined initial data is displayed on the display portion B21g and the auxiliary game symbol display portion H21g, and the data of the first main game symbol, the second main game symbol, and the auxiliary game symbol are not correctly stored in the RAM after clearing the RAM. When the RAM is cleared by operating the RAM clear button, or when the power is restored when the RAM clear button is not operated, the first main game symbol display portion A21g, the second main game symbol display portion B21g, the auxiliary game symbol display By constructing the part H21g to display the data at the time of power failure, the power supply is turned on except when the data of the first main game pattern, the second main game pattern, and the auxiliary game pattern are not correctly stored in the RAM after clearing the RAM. At the time of power-on, it is difficult to determine whether the RAM has been cleared and the power has been restored, or whether the RAM has not been cleared and the power has been restored.

(additionable configuration or changeable configuration)
In the above-described embodiment, the basic configuration of the gaming machine in which it is difficult for the player to determine whether or not the RAM has been cleared has been described. Configurations that can be added or changed are listed below.
<Available configuration 1>
In the third embodiment and modification examples 1 to 3 of the third embodiment, a configuration was described in which it is difficult to determine whether or not the RAM has been cleared by the symbols displayed when the power is turned on. It is possible to add an erase configuration.

Specifically, the CPUMC of the main control board M measures the period after the fluctuation of the main game symbols has stopped, and when a predetermined period (for example, 242 seconds) is reached, the CPUSC of the sub control board S is sent to the CPUSC of the sub control board S to demonstrate the game standby. Along with transmitting the start command, the display of the main control display device D53 controlled by the CPUMC of the main control board M is cleared (turned off). Further, when the CPUSC of the sub control board S receives a game standby demonstration start command transmitted from the CPUMC of the main control board M, it displays a game standby demonstration screen (game standby demo movie, etc.) based on the reception of the command. , decorative pattern, background image, production stage, sound volume, amount of light, etc. are cleared or reset to return to default settings. With this configuration, it becomes impossible to compare the pattern displayed before the power is turned off with the pattern displayed when the power is turned on, making it difficult to determine whether or not the RAM has been cleared. Become.

<Changeable configuration 1>
In the third embodiment and modification examples 1 to 3 of the third embodiment, the symbols displayed when the power is turned on make it difficult to determine whether or not the RAM has been cleared. At the time of power failure recovery (=during game standby), initial symbols (data) predetermined in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are randomly selected. In the above description, the patterns that have been turned on are displayed, and the patterns that existed before the power interruption is displayed when the setting is changed for the second time or later. It is also possible to adopt a configuration that makes it difficult to determine whether or not. In addition, the initial pattern may be any one of a losing pattern, a winning pattern, or a small winning pattern, or if there are multiple types of losing patterns, it may be any one of the plurality of types of losing patterns. Alternatively, it may be a pattern that can be displayed only when power is restored (a pattern that does not indicate the result of the lottery).

Specifically, the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are initialized according to the number of times the power is turned on (power failure recovery) regardless of whether or not the setting has been changed. Display the pattern. For example, if the power is turned on for the first time, the first main game symbol display portion A21g of the present embodiment lights up "a", the second main game symbol display portion B21g lights up "k", and the auxiliary game symbols are lit. "1" is lighted in the display portion H21g, and if the power is turned on for the second time, "b" is lighted in the first main game symbol display portion A21g, and "l" is lighted in the second main game symbol display portion B21g. , and "2" is lit up in the auxiliary game symbol display portion H21g. In this way, in the main game symbol display section, when the number of power-on increases by one, the light-emitting body to the right of the light-emitting body that was lit up last time is lit up, and in the auxiliary game symbol display section H21g, "1" is displayed. and "2" are lit alternately. In this configuration example, after "h" is lit up in the first main game symbol display portion A21g, "a" is lit up again, and "r" is lit up in the second main game symbol display portion B21g. After that, "k" is illuminated again, but it may be configured so that "g" is illuminated next to "h" and gradually changes toward "a". The initial symbols displayed for the first time may be winning symbols, losing symbols, fluctuating symbols, etc. used as symbols related to the game of the gaming machine, or may be used as symbols related to the game of the gaming machine. It may be a pattern that is not displayed and is displayed only in the initial pattern. With such a configuration, it is possible to make it difficult to determine whether or not the RAM has been cleared, as in the third embodiment and modification examples 1 to 3 of the third embodiment.

<Changeable configuration 2>
In the third embodiment and modification examples 1 to 3 of the third embodiment, the symbols displayed when the power is turned on make it difficult to determine whether or not the RAM has been cleared. At the time of power failure recovery (=during game standby), initial symbols (data) predetermined in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are randomly selected. In the above description, the pattern data is displayed after the setting is changed for the second time or later. It is possible to make it difficult to determine whether or not the RAM has been cleared by the change.

Specifically, the CPUMC of the main control board M clears the set value data and the data related to the lottery when clearing the RAM due to the setting change, and controls the other parts not to be cleared. Here, the data related to the lottery includes a flag indicating whether or not the main game pattern is in the probability fluctuation state, a flag indicating whether or not the auxiliary game pattern is in the probability fluctuation state, pattern data during stop display, and the like. However, it controls not to clear at least the area related to the design data among the data related to the lottery. On the other hand, in the case of RAM clearing (set key off, RAM clear button on, power switch on) not depending on setting change, all RAM areas are cleared and the first main game symbol display portion A21g and the second main game symbol display portion A21g are cleared. The symbols displayed in B21g and the auxiliary game symbol display portion H21g are controlled so as to be the initial symbols when the RAM is cleared without changing the setting.

With this configuration, even if the RAM is cleared by changing the setting, the pattern before the power failure is continuously displayed, so that it is difficult to determine whether the RAM is cleared by changing the setting. It is possible. At this time, by clearing the data related to the lottery by clearing the RAM due to the setting change, the game state is changed. There is a possibility that a contradiction may occur in the performance display. Therefore, as a countermeasure against the read-ahead effect, the CPUSC of the control board S can be configured so as not to execute the read-ahead effect that was being executed before the power interruption when the RAM is cleared due to the setting change.

Specifically, when a power failure occurs in a situation where the prefetch effect (hold change effect) is being executed in the hold display, and the power is restored by clearing the RAM by changing the setting, the prefetch effect (hold change effect) is performed in the hold display. is not executed, and the default hold display is performed. The look-ahead effect is a pre-determination effect executed by the sub control board S based on the look-ahead command transmitted based on the result determined by the main control board M in the look-ahead determination process of FIG. Also, if the look-ahead stage was being executed, when the power is restored, it will become the normal stage that is displayed when the RAM is cleared, and if the chance display where the decorative pattern of the same color is displayed when the fluctuation stops is being executed, the power will be displayed. There is a method of controlling so that the display of the chance eye is not continued when the recovery is interrupted. With this configuration, the game state is changed by clearing the data related to the lottery by clearing the RAM by changing the setting while continuously displaying the symbols before the power failure. It is possible to prevent a contradiction from occurring in the performance display such as the pre-reading performance determined in advance.

In addition to the above-described specific examples, the CPUSC of the sub-control board S, based on commands newly received from the CPUMC of the main control board M (commands indicating game status, etc.) when recovering from a power failure without clearing the RAM, It is also preferable to perform control so as to newly perform the execution lottery of the prefetching effect or the effect pattern lottery of the prefetching effect for the existing hold. By constructing in this way, it is possible to re-execute the look-ahead effect anew at the time of power failure recovery without RAM clearing.

<Changeable configuration 3>
In the third embodiment, when power is restored without clearing the RAM and the game is on standby, the symbols to be displayed are different from the symbols displayed before the power failure. However, it is possible to change the pattern to be displayed only when the lost pattern is displayed before the power failure when the power is restored without clearing the RAM.

Specifically, when power is restored (turned on) without clearing the RAM, if a predetermined pattern was displayed before the power failure, it is changed to a specific initial pattern. For example, when the RAM is not cleared when the power is restored, the CPUMC of the main control board M displays the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbols before the power failure. When a losing pattern is displayed on the display portion H21g, it is changed to a pattern that can be displayed only when the power is restored (a pattern that is neither a losing pattern nor a winning pattern. That is, a pattern that does not indicate the result of the lottery. The same applies hereinafter). . In addition, when the RAM is cleared based on the setting change at the time of power failure recovery, the CPUMC of the main control board M displays the first main game symbol display portion A21g, the second main game symbol display portion B21g, When a hit pattern is displayed in the auxiliary game pattern display part H21g, the same initial pattern as when the RAM is cleared without changing the setting is displayed as in the conventional case, and the RAM is not cleared when the power is restored. In this case, when the CPUMC of the main control board M hits the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g before the power is cut off, the symbols are displayed. , the winning pattern is displayed again. By configuring in this way, whether the pattern that can be displayed only at the time of power failure recovery is displayed by RAM clearing, or the power failure recovery is due to the fact that the RAM clear is not performed and the lost pattern was displayed before the power failure. It is possible to configure so that it is difficult to determine whether a pattern that can be displayed only when the display is displayed is displayed.

<Changeable configuration 4>
In the third embodiment, when power is restored (power is turned on) without clearing the RAM and the game is on standby, the symbols to be displayed are different from the symbols displayed before the power failure. However, it is possible to change the pattern to be displayed regardless of which pattern was displayed before the power failure at the time of power failure recovery without RAM clearing.

Specifically, when the power is restored (turned on) without clearing the RAM, a specific initial pattern is displayed regardless of the pattern displayed before the power failure. For example, when the power is turned on (recovery from power failure without changing settings), the CPUMC of the main control board M displays the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display before the power failure. Regardless of whether the pattern displayed in the part H21g is a winning pattern or a losing pattern, a pattern that can be displayed only when power is restored is displayed. With this configuration, even if the RAM is cleared and a pattern that can be displayed only when the power is restored is displayed, the pattern that has not been cleared by the RAM can be displayed by turning on the power again. Therefore, it is possible to make it difficult to determine from the displayed pattern whether or not the setting has been changed. With this configuration, a different initial pattern will be displayed unless the power is turned on again. As a result, if the amusement arcade wants to leave a trace of intentionally clearing the RAM (setting change), it is possible to select not to turn on the power again, and display the initial pattern that meets the needs of the amusement arcade. can.

<Changeable configuration 5>
In the third embodiment, when the game is on standby at the time of power failure recovery after RAM clearing due to setting change and power failure recovery without RAM clearing, the symbols to be displayed are displayed before power failure. Although the configuration has been explained in which the pattern is different from the one previously displayed, the pattern that was displayed before the power failure is displayed when the setting is changed (RAM clear) or when the power is restored without clearing the RAM. It is possible to adopt a configuration in which the design is changed.

Specifically, regardless of setting changes and RAM clearing, when power is restored (turned on), control to change to a specific initial pattern according to the pattern displayed before power failure, setting change, RAM Regardless of the presence or absence of clearing, at the time of power failure recovery, adopting control to change to a specific initial pattern according to the pattern group displayed before power failure is adopted. For example, regardless of setting changes or RAM clearing, at the time of power failure recovery, the CPUMC of the main control board M displays the first main game symbol display portion A21g, the second main game symbol display portion B21g, the auxiliary game symbol before the power failure. Depending on whether the pattern displayed in the pattern display part H21g is a winning pattern or a losing pattern, the pattern is changed to a pattern that can be displayed only when power is restored. With this configuration, whether the RAM is cleared and the patterns corresponding to the winning patterns or the patterns corresponding to the losing patterns, which can be displayed only when the power is restored, are displayed, or the RAM is not cleared. It is possible to configure such that it is difficult to determine whether a pattern corresponding to a winning pattern or a pattern corresponding to a losing pattern, which can be displayed only when power is restored, is displayed.

In addition, regardless of setting changes or RAM clearing, when power is restored (turned on), the CPUMC of the main control board M displays the first main game symbol display area A21g and the second main game symbol display area A21g before the power failure. B21g, the symbol group displayed in the auxiliary game symbol display portion H21g {for example, winning symbol 1 (per 10R full open), winning symbol 2 (per 10R: practically 8R per), winning symbol 3 (per 8R full open), The pattern is changed to a pattern that can be displayed only when power is restored according to the lost pattern, etc.). With this configuration, whether the RAM is cleared and the symbols corresponding to the winning symbol group or the symbols corresponding to the losing symbol group, which can be displayed only when the power is restored, are displayed, or the RAM is cleared. It is possible to make it difficult to determine whether symbols corresponding to a winning symbol group and symbols corresponding to a losing symbol group, which are not performed and can be displayed only when power is restored, are displayed.

In addition, at the time of power failure recovery (power on) in which the RAM is cleared by changing the setting, the CPUMC of the main control board M displays the main game symbol display part (first main game symbol display part A21g, second main game symbol display part A21g, second A specific initial pattern (symbols that can be displayed only when power is restored) corresponding to the symbols (hitting symbols, losing symbols, etc.) displayed in the main game symbol display portion B21g) or the auxiliary game symbol display portion H21g) is determined. If the configured and determined specific initial symbol is a symbol corresponding to a winning symbol, it is more preferable to change it to an initial symbol corresponding to a losing symbol. By configuring in this way, it is possible to prevent the notification mode between the initial symbols and the game state, and the initial symbols and the game state from being different.

To elaborate on this point, when the RAM is cleared by changing the settings in each example of the above-mentioned "changeable configuration 5", the symbols displayed in the main game symbol display portion or the auxiliary game symbol display portion H21g are Since it is a pattern group that was displayed before the decision, there is a possibility that the initial pattern corresponding to the probability variation pattern group will be displayed, but since the RAM is cleared, the actual game state is a non-probability variation state. It is assumed that the probability variation pattern is in a non-probability variation state even though it is stopped and displayed. Moreover, when the variable probability indicator lamp of the main game pattern indicates whether or not the variable probability indicator lamp of the main game pattern is displayed at the time of power failure recovery, there is a problem that the variable probability indicator lamp of the main control display device D53 may be extinguished. However, if this configuration is adopted, the initial symbols and the game state, and the initial symbols and the notification mode of the game state can be matched. It is possible to avoid a situation in which there is a contradiction with the game state indicated by the indicator lamp.
<Changeable configuration 6>
In the changeable configuration 5, the configuration for displaying symbols that can be displayed only at the time of power failure recovery according to symbols (win symbols, losing symbols, etc.) and symbol groups (win symbol groups, losing symbol groups, etc.) has been described. Since it cannot be applied to a gaming machine that does not have a non-probability variation pattern, it is also possible to adopt a configuration that can be applied to a gaming machine that does not have a non-probability variation pattern. However, focusing on the point that such a gaming machine clears the RAM regardless of the setting change so as not to start the game from the probability variable game at the start of business on the next day, the following configuration results in the following: It is possible to make it difficult to determine from the pattern whether or not the setting has been changed.

Specifically, in a gaming machine that does not have a non-probability variable pattern that always enters a probability variable state after a big hit (for example, a 100% ST machine, etc.), the CPUMC of the main control board M displays a winning pattern when the power is cut off. When the pattern has been cleared, a common pattern that can be displayed only when the RAM is cleared is displayed when the RAM is cleared by changing the setting of the pattern and when the RAM is cleared by not changing the setting. By constructing in this way, it becomes difficult to determine whether the RAM is cleared by changing the setting or the RAM is cleared by not changing the setting for the gaming machine having no non-probability variable symbols. It is possible to make it difficult to determine whether or not the setting has been substantially changed for a gaming machine that does not have non-probability variation symbols.
<Changeable configuration 7>
In the third embodiment and modification examples 1 to 3 of the third embodiment, a configuration has been described in which it is difficult to determine whether or not the RAM has been cleared by changing the pattern displayed when the power is turned on. , it is also possible to display an initial pattern corresponding to the individual ID of the CPUMC of the main control board M, thereby making it difficult to determine whether or not the RAM has been cleared.

Specifically, at the time of power failure recovery (power on) regardless of setting changes or RAM clearing, the CPUMC of the main control board M refers to the identification information (individual ID of the CPUMC of the main control board M), Initial symbols to be displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are displayed according to the reference result. By configuring in this way, an initial pattern unique to each game machine is displayed, and it is possible to make it difficult to determine whether or not the RAM has been cleared. It should be noted that one-to-one initial patterns may be set corresponding to the reference result. In addition to making it difficult to determine whether the main control board has been changed, it is possible to recognize that the main control board has been illegally replaced at night. Of course, it is also possible to randomly display a plurality of initial patterns based on other parameters and reference results.
<Changeable configuration 8>
In the third embodiment and modification examples 1 to 3 of the third embodiment, the configuration in which it is difficult to determine whether or not the RAM has been cleared by changing the pattern displayed when the power is turned on has been described. As such, by displaying an initial pattern according to the processing result of the CPUMC of the main control board M, it is possible to make it difficult to determine whether or not the RAM has been cleared.

Specifically, at the time of power failure recovery (power on) regardless of setting changes or RAM clearing, the CPUMC of the main control board M performs error judgment (checksum). , the initial symbols to be displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are displayed. With this configuration, the checksum value that is always referred to in the power restoration process and that differs depending on the processing status (processing result) at the time of power failure is used, thereby eliminating unnecessary random number acquisition and random number generation. A random initial pattern can be selected, and it is possible to make it difficult to determine whether or not the RAM has been cleared.
<Changeable configuration 9>
In the third embodiment and modification examples 1 to 3 of the third embodiment, the configuration in which it is difficult to determine whether or not the RAM has been cleared by changing the pattern displayed when the power is turned on has been described. Alternatively, by displaying an initial pattern corresponding to specific address data of the CPUMC of the main control board M, it is possible to make it difficult to determine whether or not the RAM has been cleared.

Specifically, at the time of power failure recovery (power-on) regardless of setting changes or RAM clearing, the CPUMC of the main control board M stores specific address data (for example, (2) and (4) in FIG. 61). , any data shown in (7)), and according to the reference result, the initial stage to display in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g Decide on the pattern. By configuring in this way, by using address data that has some degree of randomness depending on the processing status (processing result) at the time of power failure, a random initial pattern can be selected without unnecessary random number acquisition or random number generation. Moreover, it is possible to make it difficult to determine whether or not the RAM has been cleared.
<Changeable configuration 10>
In the third embodiment and modification examples 1 to 3 of the third embodiment, the configuration in which it is difficult to determine whether or not the RAM has been cleared by changing the pattern displayed when the power is turned on has been described. As such, the CPUMC of the main control board M can be configured to make it difficult to determine whether or not the RAM has been cleared by displaying an initial pattern corresponding to the model name.

Specifically, regardless of setting changes or RAM clearing, at the time of power failure recovery (power on), the CPUMC of the main control board M responds to the model name (the name of the gaming machine stored in the program). , the initial symbols to be displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are determined. By configuring in this manner, an initial pattern unique to each model is displayed, and it is possible to make it difficult to determine whether or not the RAM has been cleared. It should be noted that one-to-one initial patterns may be set corresponding to the model names. Not only is it difficult to determine whether or not it is installed, but it is also possible to recognize whether or not the main control board M corresponding to the model is mounted at the time of manufacture. Of course, it is also possible to randomly display a plurality of initial patterns based on other parameters and reference results.
<Changeable configuration 11>
In the third embodiment and modification examples 1 to 3 of the third embodiment, a configuration has been described in which it is difficult to determine whether or not the RAM has been cleared by changing the pattern displayed when the power is turned on. As such, the CPUMC of the main control board M can be configured to make it difficult to determine whether or not the RAM has been cleared by displaying an initial pattern corresponding to the rotation speed of the setting key.

Specifically, regardless of setting changes or RAM clearing, at the time of power failure recovery (power on), the CPUMC of the main control board M displays the first main game symbol display part according to the speed at which the setting key is rotated. The initial symbols to be displayed in A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are determined. By configuring in this way, the situation in which the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are turned off after the setting change (RAM clearing) is eliminated. It becomes difficult to determine whether or not the RAM has been cleared. Also, if the initial pattern displayed when the game clerk slowly rotates the setting key is displayed, there is a high possibility that the setting has been changed at the game store. , it is also possible to suggest to the player that the setting has been changed. If the pattern is selected so that the same pattern may be displayed when the setting key is not rotated and when the setting key is rotated at a predetermined speed, even if the setting key is not inserted, the same pattern may be displayed. The pattern displayed when the setting key is operated can be selected, making it more difficult to determine whether or not the RAM has been cleared.
<Changeable configuration 12>
In the third embodiment and modification examples 1 to 3 of the third embodiment, the configuration in which it is difficult to determine whether or not the RAM has been cleared by changing the pattern displayed when the power is turned on has been described. As such, the CPUMC of the main control board M can be configured to make it difficult to determine whether or not the RAM has been cleared by displaying an initial pattern corresponding to the timing at which the setting key is rotated.

Specifically, regardless of setting changes or RAM clearing, when the power is restored (power is turned on), the CPUMC of the main control board M displays the first main game symbols according to the timing of rotating the setting key. Initial symbols to be displayed in the portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are determined. For example, the CPUMC of the main control board M measures the elapsed time after the power is turned on, and displays the initial pattern according to the elapsed time during which the setting has been changed. By configuring in this way, the situation in which the first main game symbol display portion A21g, the second main game symbol display portion B21g and the auxiliary game symbol display portion H21g are turned off after the setting change (RAM clearing) is eliminated. It becomes difficult to determine whether or not the setting has been changed. In addition, since the initial pattern differs depending on the timing at which the game clerk changes the settings (elapsed period after turning on the power), it is displayed when the game clerk changes the settings after a predetermined period of time (for example, 300 seconds) has passed since the power was turned on. If the initial pattern is displayed, it suggests that the setting has been changed to the player according to the rules unique to the game store, such as the high possibility that the setting has been changed at the game store. is also possible. If the pattern is selected so that the same pattern may be displayed when the setting key is not rotated and when the setting key is rotated at a predetermined timing, even if the setting key is not inserted. The pattern displayed when the setting key is operated can be selected, making it more difficult to determine whether or not the RAM has been cleared.
<Changeable configuration 13>
In the third embodiment and modification examples 1 to 3 of the third embodiment, the configuration in which it is difficult to determine whether or not the RAM has been cleared by changing the pattern displayed when the power is turned on has been described. As such, the CPUMC of the main control board M can be configured to make it difficult to determine whether or not the RAM has been cleared by displaying the initial pattern according to the period during which the RAM clear button is pressed.

Specifically, at the time of power failure recovery (power-on) regardless of setting changes or RAM clearing, the CPUMC of the main control board M clears the RAM for a certain period of time (for example, 3 minutes after power-on). Initial symbols to be displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are determined according to the period during which the button is pressed. With this configuration, the initial pattern is selected depending on the operation time of the RAM clear switch regardless of whether the setting has been changed or whether the RAM has been cleared. As a result, it becomes difficult to determine whether the initial pattern is selected or the initial pattern is simply selected by operating a RAM clear switch, and it becomes difficult to judge whether RAM clear or setting change is performed. Also, if the game clerk presses the RAM clear button for a long time (for example, 5 seconds or more) and the initial pattern displayed is displayed, there is a high possibility that the setting has been changed at the game parlor. It is also possible to suggest to the player that the setting has been changed according to rules unique to the game arcade.
<Changeable configuration 14>
In the third embodiment and modification examples 1 to 3 of the third embodiment, a configuration was described in which it is difficult to determine whether or not the RAM has been cleared by the pattern displayed when the power is turned on. It is also possible to make it impossible to determine whether or not the RAM has been cleared by changing the settings (RAM clearing) so that the game can be played when a predetermined time or more has elapsed since the RAM clearing.

Specifically, when the power is turned on after a predetermined period of time or more has passed since the power was turned off, the CPUMC of the main control board M changes the setting (RAM clear) to make the game ready for play. For example, when the power is turned on 6 hours or more after the power was turned off, the game cannot be started unless the setting is changed. An RTC is provided on the main control board M, and the CPUMC of the main control board M grasps the time when the power is turned off and the time when the power is turned on from the RTC, and the power is turned on based on these times. It is possible to grasp the period when it is turned off. With such a configuration, there will be no game machines whose settings have not been changed (RAM cleared) on the next day, and it will be impossible to determine that the settings have been changed (RAM cleared) from the display mode of the game machine after the power is turned on. .
<Changeable configuration 15>
In the third embodiment and modification examples 1 to 3 of the third embodiment, the configuration that makes it difficult to determine whether or not the RAM has been cleared by the pattern displayed when the power is turned on has been described, but the special variation pattern is referred to on the previous day. When the game ends in the game state, depending on whether the special variation pattern is continued to be referred to the next day or whether the special variation pattern is not referred to, the presence or absence of the setting change (whether or not the RAM is cleared) is determined. It is possible that it can be identified. Therefore, the CPUMC of the main control board M continues to refer to the special variation pattern table that was referenced before the power failure even after the power failure is restored, thereby making it impossible to determine whether or not the setting has been changed (RAM cleared). It is also possible to make it possible.

Specifically, when power is restored (power is turned on) in which the RAM is cleared by changing settings, the CPUMC of the main control board M determines that the winning probability of the main game symbols is low and the main game symbols are selected before the power failure. Even if a special variation pattern table (limited frequency table) with different types and / or selection rates of variation modes is referenced, the special variation pattern table is referenced a predetermined number of times. continue until it reaches By configuring in this way, even when the RAM is cleared due to the setting change, even when the power is restored (turned on), the special fluctuation pattern table is continuously referred to. RAM clear) can be made indistinguishable.

(Fourth embodiment)
In the third embodiment and modification examples 1 to 3 of the third embodiment, the displayed pattern is changed by changing or unifying the pattern displayed after the power is turned on according to the setting change process or the like. However, in the fourth embodiment, there is no pattern like the initial pattern, and whether or not the setting has been changed is determined from the displayed pattern. A mode for determining whether or not will be described.

First, in the present embodiment, when the stop symbol of the auxiliary game symbol becomes "win" and the second main game starter electric accessory B11d of the second main game starter B10 is opened, the second main game starter B10 It is configured to detect that the game ball has entered only when the game ball has entered. In such a configuration, when the RAM is cleared by changing the settings, the symbol data (main game symbol data) displayed in the second main game symbol display portion B21g is cleared, and the predetermined data such as the initial data is cleared. Therefore, it may be easy to determine whether the setting has been changed or not.

Therefore, when a game ball enters the second main game start port B10 within a predetermined period (for example, 5 seconds) after turning on the power (or clearing the RAM), it is configured to detect that the ball has entered. , the game clerk or the like can change the symbols displayed in the second main game symbol display portion B21g. For example, the symbols that may be displayed in the second main game symbol display portion B21g are "4B (4R hit)", "5B (5R hit)", "7B (7R hit)", "F (losing)", and "2BK". (minor win)” and “7BK (minor win)”. ' and 'r' are lit, if 'k' and 'r' of the second main game symbol display portion B21g are lit, the player can determine that there is a high possibility that the setting has been changed. Therefore, before the opening of the amusement arcade, the game clerk or the like causes the game ball to enter the second main game start port B10 within a predetermined time (for example, 5 seconds) after the power is turned on (maintenance, etc.), and the second By changing the symbols displayed in the main game symbol display part B21g from "k" and "r", it becomes difficult for the player to determine whether or not the setting has been changed. Symbols to be changed from "k" and "r" include winning symbols and losing symbols.

However, in general, when clearing the RAM or turning on the power (without clearing the RAM), a predetermined pattern combination (for example, "331" for clearing the RAM, "246" for turning on the power, etc.) is displayed in the decorative pattern display area SG11. In many cases, it is configured to be displayed, and if the game ball is entered into the second main game start port B10 as described above, the decorative pattern will change, so it is displayed in the decorative pattern display area SG11. There is a possibility that the predetermined symbol combination that has been used may be changed. Therefore, when a game ball enters the second main game start port B10 within a predetermined time (for example, 5 seconds) after the power is turned on, the CPUSC of the sub-control board S is configured so as not to change the decoration pattern. is preferred.

(Fifth embodiment)
In the fifth embodiment, a configuration of a gaming machine that is different from the third embodiment, modified examples 1 to 3 of the third embodiment, and the fourth embodiment and makes it difficult to determine whether or not the setting has been changed will be described. do.

In the fifth embodiment, by performing a predetermined operation (for example, pressing the RAM clear button, etc.) within a predetermined period (for example, 10 seconds) after turning on the power (or clearing the RAM), the second main game symbol display unit It is configured so that the design displayed in B21g can be changed. For example, the symbols that may be displayed in the second main game symbol display portion B21g are "4B (4R hit)", "5B (5R hit)", "7B (7R hit)", "F (losing)", and "2BK". (minor win)” and “7BK (minor win)”, and when “k” and “r” are lit as the symbols displayed in the second main game symbol display portion B21g when the setting is changed (when the RAM is cleared), the second If "k" and "r" are lit in the second main game symbol display portion B21g, the player can determine that there is a high possibility that the setting has been changed. , the RAM clear button is pressed within 10 seconds after the power is turned on, and the symbols displayed in the second main game symbol display area B21g are randomly changed from "k" and "r" or set in advance. By changing to symbols (for example, lighting of the losing symbols “q” and “r”), it becomes difficult for the player to determine whether or not the setting has been changed.

In this embodiment, the RAM is cleared when the setting is changed, and the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion are displayed when the RAM is cleared. There is a concern that the symbols displayed in H21g may be cleared and the player may easily recognize that the settings may have been changed. In the sixth embodiment and 1 to 3 of the sixth embodiment, the store clerk or the like selects whether to allow the player to distinguish the setting change or to make it difficult for the player to distinguish the setting change. A possible gaming machine configuration will be described.

(Sixth embodiment)
The gaming machine according to the sixth embodiment has the following configuration.
(1) In "RAM clearing by setting change (perform setting change operation)", the RAM is cleared, but the pattern data of the main game pattern and the pattern data of the auxiliary game pattern are kept without being cleared (2 ) "RAM clear without setting change (only RAM clear operation without setting change operation)" includes the main game pattern pattern data and the auxiliary game pattern pattern data, and clears the RAM. By configuring as above, if the game parlor side wants the player to discriminate that the setting has been changed, after performing "RAM clearing by setting change", "RAM clearing without setting change" is performed. Then, it is sufficient to change the setting and clear the RAM containing the main game symbol data and the auxiliary game symbol data. By performing "Clear", setting change and RAM clearing other than the symbol data of the main game symbols and the symbol data of the auxiliary game symbols can be performed.

(1 of the sixth embodiment)
The gaming machine according to 1 of the sixth embodiment has the following configuration.
(1) "When changing settings, fix the set value without making one cycle from the current set value", clears the RAM, but clears the design data of the main game design and the design data of the auxiliary game design. (2) ``When changing the setting, the setting value is fixed by making one or more cycles from the current setting value'', including the pattern data of the main game pattern and the pattern data of the auxiliary game pattern, Clearing the RAM Specifically, for example, when the current setting value is 2 and the setting value is to be changed to 3 in the 6-step setting, there are the following two methods.
1. When the set value is changed from the set value 2 to the set value 3 and the set value is confirmed, the design data of the main game design and the design data of the auxiliary game design are kept without being cleared.2. Set value 2 → set value 3 → set value 4 → set value 5 → set value 6 → set value 1 → set value 2 → set value 3. When the set value is confirmed, the symbol of the main game pattern is changed. Data and pattern data of auxiliary game patterns are included, and the RAM is cleared. The setting value is fixed by making one or more cycles from the current setting value.” By changing the setting and clearing the RAM including the main game pattern pattern data and the auxiliary game pattern pattern data, the player can change the setting. If you don't want to discriminate, "When changing the setting, fix the setting value without making one cycle from the current setting value". All that is necessary is to clear the RAM other than the pattern data.

(2 of the sixth embodiment)
The gaming machine according to 2 of the sixth embodiment has the following configuration.
・Perform the display processing of the pattern according to the input status of the predetermined input unit when the setting change is completed and the completion operation of the setting change. When the setting key is turned off, the RAM is cleared, but the symbol data of the main game symbols and the symbol data of the auxiliary game symbols are kept without being cleared. When confirming the setting value, "turn off the setting key while pressing the RAM clear button", the pattern data of the main game pattern and the pattern data of the auxiliary game pattern are included, and the RAM is cleared.
With such a configuration, if the game parlor wants the player to recognize that the setting has been changed, the setting value can be confirmed by ``turning off the setting key while pressing the RAM clear button''. Therefore, it is sufficient to change the settings and clear the RAM containing the main game symbol data and the auxiliary game symbol data. By "turning off the setting key without pressing the RAM clear button", the setting change and the RAM clearing other than the main game pattern pattern data and the auxiliary game pattern pattern data may be performed.

(3 of the sixth embodiment)
The gaming machine according to 3 of the sixth embodiment has the following configuration.
・The first main game symbol display area A21g, the second main game symbol display area A21g, the second The initial symbols to be displayed in the main game symbol display portion B21g and the auxiliary game symbol display portion H21g are determined. The initial pattern is determined according to the number of times the button is pressed. For example, when "a" and "h" are lit in the first main game symbol display area A21g, it indicates that the RAM clear button has been pressed once, and "a" and "h" are lit in the main game symbol display area A21g. If "g" is illuminated, it means that the RAM clear button has been pressed twice, and if "a" and "f" are illuminated in the main game symbol display area A21g, the RAM clear button Depending on the number of times the RAM clear button has been pressed, the combination of "a" and which light emitter is turned on is different, so as to indicate that it has been pressed three times. In other words, if "a" and "g" are illuminated in the first main game symbol display area A21g, it indicates that the RAM clear button has been pressed twice, and the player has increased the set value by two steps from the previous day ( setting value changed from 2 to 4). On the other hand, on the amusement arcade side, the set value can be changed many times before the amusement arcade opens. Change (operate the RAM clear button 5 times, and "a" and "d" light up in the first main game symbol display area A21g), and then change the setting value to 2 in the second setting change (RAM clear button is operated once), ``a'' and ``h'' will light up in the first main game symbol display area A21g, and the set value has increased by one step even though the set value has not been changed from the previous day. It is also possible to provide a display indicating that there is a possibility.

In this embodiment, the RAM is cleared when the settings are changed, and the RAM is cleared to display the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion. There is a concern that the symbols displayed in H21g may be cleared and the player may easily recognize that the settings may have been changed. In the seventh embodiment and 1 to 5 of the seventh embodiment, the symbols displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g at various timings. It is difficult for the player to determine that there is a possibility that the setting has been changed by changing to a different display mode or returning from the changed pattern display mode at a predetermined timing. However, a description will be given of the construction of a gaming machine capable of displaying appropriate symbols during a game.

(Seventh embodiment)
The gaming machine according to the seventh embodiment has a configuration in which the display of symbols is erased when fluctuation stops or power is turned on.
(1) After a certain period of time (for example, 60 seconds) has passed since the fluctuation stopped, the main game symbol display area (first main game symbol display area A21g, second main game symbol display area B21g) and auxiliary game symbol display area H21g Turn off the displayed symbols (after the main game symbols stop changing, turn off the main game pattern display part, and after the auxiliary game patterns stop changing, turn off the auxiliary game pattern display part)
(2) When the power is turned on {setting change (RAM clear) / power failure recovery without setting change}, the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g With this configuration, the first main game symbol display area A21g and the second main game symbol display area A21g and the second main game symbol display area A21g and the second main game symbol display area A21g and the second main game symbol display area A21g and the second main game symbol display area A21g and the second main game symbol display area A21g and the second main game symbol display unit Since the symbols are turned off in the game symbol display portion B21g and the auxiliary game symbol display portion H21g, the player can display the first main game symbol display portion A21g and the second main game symbol display portion A21g without playing the game just before closing of the previous day. The symbols displayed in the game symbol display portion B21g and the auxiliary game symbol display portion H21g are confirmed, and on the next day, the symbols are displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g and the auxiliary game symbol display portion H21g. When is extinguished, it becomes difficult to determine that the setting has been changed (RAM clear). It should be noted that, when the power is restored without changing the setting, the stored pattern before the power failure may be displayed first, and the display may be turned off after a certain period of time (for example, 100 ms) has elapsed.

(1 of the seventh embodiment)
The gaming machine according to 1 of the seventh embodiment has a configuration regarding the timing at which the symbols are displayed when the symbols are not displayed.
・When the power is turned on {setting change (RAM clear) / power failure recovery without setting change}, the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g display When the pattern does not fluctuate, the pattern is turned off, and when the game is started, the pattern is displayed. Sometimes the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are always turned off, so the player can determine whether or not the setting has been changed. becomes difficult, and since the symbols are displayed when the game is started, the player can recognize that the game is in progress. If the main game symbols or the auxiliary game symbols are changed when the power is turned on, they are changed as they are. Further, the start of the game means, for example, starting gate winning (main game symbol starting gate, auxiliary game symbol starting gate), passing through the out gate, contacting or firing the shooting handle, and the like. It should be noted that, when the power is restored without changing the setting, the stored pattern before the power failure may be displayed first, and the display may be turned off after a certain period of time (for example, 100 ms) has elapsed.

It is also possible to add the following configuration to the gaming machine according to 1 of the seventh embodiment.
・Even if the pattern does not change, the indicator light that displays the error (for example, the main control error indicator light) is not turned off ・Even if the pattern does not change, the indicator light that displays the game state ( For example, by adding a configuration like this, information (error information, etc.) that the amusement arcade must be able to confirm is displayed, and there is a possibility that the setting has been changed. The symbols may be turned off so that it is difficult for the player to discern that there is something there.

(2 of the seventh embodiment)
The gaming machine according to 2 of the seventh embodiment has a configuration in which the symbols are turned off when power is restored, and the display of the symbols is restored when a predetermined condition is satisfied.
(1) When recovering from power failure {recovery from power failure without changing settings (RAM clearing)}, the symbol information before the power failure is retained, but the first main game symbol display area A21g and the second main game symbol are retained. In the display portion B21g and the auxiliary game symbol display portion H21g, the symbols are turned off. By configuring in this way, after the power is turned on, the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are turned off. In a situation where a player selects a gaming machine, it can be difficult to determine whether or not a setting change (RAM clear) has been made. etc.), it is possible to clearly display the last stop symbol by displaying the symbol held before the power is turned off.

(3 of the seventh embodiment)
The gaming machine according to 3 of the seventh embodiment has a configuration in which the symbol display is erased after the symbol fixing time elapses.
(1) After the fluctuation has stopped, the first main game pattern display area A21g after the elapse of the symbol fixing time (the time to maintain the stopped state when the fluctuation of the main game symbols stops, for example, 500 ms); The symbols displayed in the second main game symbol display portion B21g and the auxiliary game symbol display portion H21g are extinguished (after the main game symbol fluctuation is stopped, the main game symbol display portion is extinguished and the auxiliary game symbol fluctuation is After it stops, turn off the auxiliary game pattern display part)
(2) When the power is turned on {setting change (RAM clear) / power failure recovery without setting change}, the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g , The symbols are turned off. By configuring in this way, when the fluctuation is stopped and after the power is turned on, the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are displayed. Since the symbol is turned off at , it becomes difficult for the player to determine whether or not the setting has been changed (RAM cleared). It should be noted that, when the power is restored without changing the settings, it may be configured such that the stored pattern before the power failure is first displayed, and then turned off after a certain period of time (for example, 100 ms) has elapsed.

(4 of the seventh embodiment)
The game machine according to 4 of the seventh embodiment has a configuration in which the symbols are not turned off when the power is restored, but are turned on so that it cannot be determined that the setting has been changed (RAM cleared).
・At the time of power failure recovery {power failure recovery without setting change (RAM clearing)}, the LEDs of the first main game symbol display area A21g, the second main game symbol display area B21g, and the auxiliary game symbol display area H21g are all lit up. With this configuration, after the power is turned on, the LEDs of the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g are all lit up. It becomes difficult for the player to judge whether or not the setting has been changed (RAM cleared). Furthermore, an LED is provided that lights up only when the power is restored (or when the RAM is cleared), and after the power is turned on (or the RAM is cleared), the first main game symbol display portion A21g, the second main game symbol display portion B21g, It is also possible to configure so that all LEDs, including the LEDs of the auxiliary game symbol display portion H21g and the LEDs that are lit only at the time of recovery from power failure, are lit. It should be noted that the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g may not all be turned on. One of the eight LEDs of the first main game symbol display portion A21g and the second main game symbol display portion B21g may be extinguished, and two of the eight LEDs may be extinguished.

(5 of the seventh embodiment)
In the gaming machine according to 5 of the seventh embodiment, the display of the symbols is erased after the restoration from the power failure, but has a configuration indicating that it is after the restoration from the power failure.
・When recovering from power failure {recovery from power failure without changing settings (RAM clearing)}, the first main game symbol display portion A21g, second main game symbol display portion B21g, and auxiliary game symbol display portion H21g turn off the symbols. and light up the power failure recovery LED indicating that the power failure recovery has been completed. Since the symbols are turned off in the game symbol display portion H21g, it becomes difficult for the player to determine whether or not the setting has been changed (RAM cleared). In addition, since the LEDs of the main game symbol display section and the auxiliary game symbol display section are turned off (the symbols are turned off), it becomes difficult for the game clerk and the player to determine whether the game is possible or not. Although there is a risk, it can be easily determined that a game can be played by turning on the power interruption recovery LED.

In this embodiment, the RAM is cleared when the settings are changed, and the RAM is cleared to display the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion. There is a concern that the symbols displayed in H21g may be cleared and the player may easily recognize that the settings may have been changed. However, there is also a demand for a gaming machine that allows a player to play a game while guessing whether or not setting changes have been made and setting values by utilizing such concerns. Therefore, in the eighth embodiment and the eighth embodiment 1, the CPUSC of the sub-control board S suggests setting changes and setting values, thereby allowing the player to guess setting changes and setting values. will be described.

(Eighth embodiment)
The gaming machine according to 1 of the eighth embodiment has a configuration in which the gaming parlor side can set decorative symbols to be displayed when the settings are changed regardless of the setting values.
・Amusement arcades (game clerks, etc.) set the decorative symbols (combination of decorative symbols) to be displayed when changing settings (clearing RAM) and/or the decorative symbols (combination of decorative symbols) to be displayed when power is restored without changing settings. For example, after the game clerk turns on the power, the setting can be changed (RAM Clear) and/or decorative patterns (combination of decorative patterns) to be displayed at the time of recovery from power failure without changing settings can be set. That is, setting is performed by the effect display device SG (display of decorative patterns) controlled by the CPUSC of the sub-control board S, the effect light emitter (game machine frame LED, board surface LED, etc.), the operation means (sub-input button SB, etc.), etc. It is configured so that it is possible to suggest changes and setting values. As for the decorative patterns (combination of decorative patterns) to be displayed, for example, if there is a high possibility that the settings have been changed or if the set values are good, the good set values "4", "5", "6"("4 , "5" and "6" are good setting values) is likely to be displayed, and if there is a low possibility that the setting has been changed or if the setting value is bad, the bad setting values "1" and "2" and "3" (if "1", "2", and "3" are bad setting values) are likely to be displayed. If the value is good, you can also set it to increase the likelihood of displaying puns {e.g. 114 (okay)}, one off (e.g. 112), or consecutive numbers (e.g. 123). be. It is also possible to configure the operation means such that the operation means vibrates, or that the performance LED has a high ratio of a specific color (for example, red).
By configuring in this way, it is highly likely that a game store that wants to indicate that a setting has been changed or a set value has changed the setting by displaying a decorative pattern (combination of decorative patterns) based on its own rules. It is possible to suggest a value, and it is possible to provide a highly entertaining gaming machine that allows the player to change the setting or guess the setting value.

(1 of the eighth embodiment)
The gaming machine according to 1 of the eighth embodiment has a configuration in which setting changes are estimated on the sub-control board S side, and display is performed based on the estimated results.
(1) The CPUMC of the main control board M transmits a command related to the setting value to the CPUSC of the sub control board S. (2) The CPUSC of the sub control board S transmits information related to the setting value based on the received command related to the setting value. Stored (not cleared even when RAM is cleared)
(3) When the power is turned on (when the settings are changed), the CPUSC of the sub-control board S transfers information about the stored set values and information about the set values indicated by the commands received when the power is turned on (when the settings are changed). If it is determined that the setting values are different from each other, it is notified or suggested that there is a high possibility that the setting has been changed. Examples include the color of the performance LED, the display on the performance display device SG (decorative pattern, background image, frequency of performance), the difference in sound, and the like.
By constructing in this way, it is possible to realize suggestion of setting change rather than mere notification of setting. The sub-control board S side can be configured to suggest setting changes and setting values, and it is possible to provide a highly entertaining gaming machine that makes the player guess setting changes and setting values.
Even if the setting values are different, it may be notified or suggested that the possibility of the setting change is low, or if the setting values are the same, the possibility of the setting change may be indicated. is low, or even if the set values are the same, it may be notified or suggested that there is a high possibility that the setting has been changed.

In this embodiment, the RAM is cleared when the settings are changed, and the RAM is cleared to display the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion. There is a concern that the symbols displayed in H21g may be cleared and the player may easily recognize that the settings may have been changed. Furthermore, the decoration pattern is often different when changing the settings (when clearing the RAM) and when recovering from a power failure {recovering from a power failure without changing settings (RAM clearing)} (for example, when clearing the RAM: 331, after power failure hour: 246, etc.). In addition, the CPUSC of the sub control board S stores stop symbol information and limited frequency table information of the main game symbols based on commands transmitted from the main control board M, stage information stored only on the sub control board S side, and internal When the counter value, notice information, etc. are backed up (the data is not erased when the power is cut off), if the RAM is cleared, the player can determine that the setting has been changed. Therefore, in the ninth embodiment and 1 and 2 of the ninth embodiment, the information (stage display, internal counter value, advance notice display, etc.) controlled by the CPUSC of the sub-control board S allows the player to notify that the setting has been changed. The configuration of the gaming machine, which is difficult to distinguish, will be described.

(Ninth embodiment)
The gaming machine according to the ninth embodiment has a configuration that enables clearing of data stored on the sub-control board S side only by control on the sub-control board S side.
(1) The CPUSC of the sub control board S stores backup data (e.g., transmitted from the main control board M side) stored on the sub control board S side in a specific operation mode (e.g., turning on the power while pressing the sub input button SB). Main game pattern information (stop pattern information) and limited frequency table information stored on the sub control board S side based on the command given, stage information stored only on the sub control board S side, internal counter value, notice information, etc.) At least part of them is cleared. With this configuration, the RAM on the sub control board S side is cleared by operating the RAM clear button to clear the RAM on the main control board M side, and by changing the settings, the RAM on the main control board M side is cleared. It is possible to clear the backup data stored on the sub-control board S side only by controlling the CPUSC of the sub-control board S regardless of whether or not the RAM is cleared. In addition, in the case of a configuration in which the internal counter of the CPUSC of the sub control board S measures the fluctuation stop period and displays the game standby demo screen (movie that starts when the fluctuation stop period reaches a certain period), the above sub control board Due to the RAM clearing on the S side, there is a risk that the display status of the game standby demo screen will be different between the plurality of gaming machines, and the player will be able to determine that the setting has been changed due to this deviation. put away. Therefore, it is preferable to configure the start and progress management of the game standby demo screen to be controlled by an RTC (real time clock) provided on the sub control board S side.

It is also possible to configure as follows.
・The CPUSC of the sub control board S stores backup data stored by the CPUSC of the sub control board S (for example, main Main game pattern information (stop pattern information) and limited frequency table information stored on the sub control board S side based on commands sent from the control board M side, stage information stored only on the sub control board S side, internal counter value , advance notice information, etc.) are cleared. It is also possible to clear the stored backup data when power is restored after the date is changed on the following day.
・A game clerk or the like can use a predetermined operation mode (for example, operate the sub-input button SB within 10 seconds after turning on the power) to store backup data ( For example, stage information, internal counters, advance notice information, etc.) are cleared or not. A user menu screen is displayed, and it is possible to set "whether or not to clear the backup data stored in the sub-control board S each time the power is turned on". In addition, if the setting "does not clear the backup data stored on the sub control board S side every time the power is turned on" is set, the above-mentioned "(1) The CPUSC of the sub control board S can (For example, by turning on the power while pressing the sub-input button SB), the backup data (eg, stage information, internal counter values, advance notice information, etc.) stored on the sub-control board S side may be cleared. By configuring in this way, it becomes possible to manage whether or not to clear the information managed (controlled) by the CPUSC of the sub-control board S according to the intention of the game parlor side.

(1 of the ninth embodiment)
In the gaming machine according to ninth embodiment 1, any one of the following configurations is provided as a configuration that makes it difficult to determine whether or not the setting has been changed by the display controlled by the CPUSC of the sub-control board S. there is
・At the time of power-on {setting change (RAM clear) / power failure recovery without setting change}, the display controlled by the CPUSC of the sub-control board S is fixedly displayed ・Power-on {setting change (RAM clear) / setting The display controlled by the CPUSC of the sub-control board S is displayed at random when the power is restored without change}. Traffic light SG15, 4th pattern SG16, etc. are mentioned. Further, when the power is turned on, the display of the decorative pattern, the traffic light SG15, the fourth pattern SG16, etc. may be erased. With this configuration, it is difficult to determine whether or not the player has changed the settings by the main game symbol display device controlled by the CPUMC of the main control board M (when the power is turned on). , the symbols displayed on the main game symbol display device are fixed or made random), and the effect display device SG controlled by the CPUSC of the sub-control board S also determines whether or not the player has changed the settings. It is possible to configure such that it is difficult to distinguish.

In addition, since there may be a case where the amusement arcade wants to suggest that the setting has been changed, it is possible that "when the power is turned on, some of the displays controlled by the CPUSC of the sub-control board S are not fixed, but set. Change (RAM clear) and power failure recovery without setting change are differentiated, and other displays controlled by the CPUSC of the sub-control board S are fixed. can be intentionally suggested. For example, it may be configured such that only the fourth pattern is different between setting change (RAM clear) and power failure recovery without setting change. In addition, a display unit or the like for suggesting a setting change controlled by the CPUSC of the sub-control board S is provided, and when the power is turned on, a display suggesting the setting change such as "setting change?" Alternatively, a lottery may be made to determine whether or not to display "Change settings?"

In the case of "randomly displaying the display controlled by the CPUSC of the sub-control board S when power is turned on {setting change (RAM clear) / power failure recovery without setting change}", a predetermined dedicated power-on A configuration may be adopted in which a decorative pattern to be displayed is determined by lottery from among the decorative patterns (decorative pattern combination). It should be noted that the display is not limited to the decorative pattern, and can be configured in the same manner as the effect stage dedicated to turning on the power, the display of the traffic light SG15 dedicated to turning on the power, the display of the fourth pattern SG16 dedicated to turning on the power, and the like.

(2 of the ninth embodiment)
The gaming machine according to the second embodiment of the ninth embodiment has a configuration for performing display controlled by the CPUSC of the sub-control board S in accordance with the display of symbols controlled by the CPUMC of the main control board M. FIG.
・When power is turned on {setting change (RAM clear) / power failure recovery without setting change}, the display controlled by the CPUSC of the sub control board S is performed based on the command sent from the CPUMC of the main control board M. Specifically, when the CPUMC of the main control board M randomly determines the symbols to be displayed in the main game symbol display section when the power is turned on, the main control board M displays the determined main game symbol display section. A command related to the pattern to be displayed is transmitted to the CPUSC of the sub-control board S, and the CPUSC of the sub-control board S displays a production stage, a decorative pattern (decorative pattern combination), a traffic light SG15, a fourth pattern SG16, etc. based on the received command. Determines what is displayed.
For example, when the CPUMC of the main control board M randomly determines the symbols to be displayed in the main game symbol display section when the power is turned on, the CPUMC of the main control board M may select the first main game symbols when the power is turned on. Losing symbols (“g” and “h” lit up) are determined as symbols to be displayed on the display portion A21g, and losing symbols (“q” and “r” lit up) are determined as symbols to be displayed on the second main game symbol display portion B21g. When the design to be displayed in the auxiliary game design display portion H21g is determined to be a losing design (“1” and “2” are extinguished), the CPUMC of the main control board M sends the CPUSC of the sub control board S to the first A command indicating that the symbol displayed on the main game symbol display portion A21g is a lost symbol (lighting of "g" and "h"), and a symbol displayed on the second main game symbol display portion B21g is a lost symbol ("q", " A command indicating that the symbol to be displayed in the auxiliary game symbol display portion H21g is a losing symbol (lighting of "1" and "2"), respectively. In the CPUSC of the sub-control board S, if the game state when the power is turned on is the normal state, the symbols displayed in the received first main game symbol display area A21g are lost symbols (“g” and “h” lit up). Based on the command indicating that, the contents to be displayed on the effect display device SG include the effect stage in the normal state, decorative symbols (for example, 253 or the like) indicating that the first main game symbol is a losing symbol, and the second ``O'' of the traffic light SG15 indicating that the variation of the 1st main game pattern is stopped, and ``☆ (no color)'' of the 4th symbol SG16 indicating that the 1st main game pattern is stopped due to loss. do.
With this configuration, there is no discrepancy between the contents displayed by the CPUMC of the main control board M and the contents displayed by the CPUSC of the sub-control board S, so that the player can determine that the settings have been changed. becomes difficult.

In the gaming machine with the ``ability to increase the number of balls with a small hit'' described in the present embodiment, the first main game symbols and the second main game symbols can be changed simultaneously (parallel lottery). machine). Since the game is played with the first main game symbols during normal times (when the base is low), the variation time of the second main game symbols is relatively long (for example, 10 minutes, etc.) compared to the variation time of the first main game symbols. ), and on the contrary, during time saving (at high base), the game is played with the second main game pattern, so the fluctuation time of the first main game pattern is compared with the fluctuation time of the second main game pattern. Then, it is designed to be relatively long (for example, 10 minutes, etc.). With such a configuration, there is a possibility that the power will be restored in the middle of a long fluctuation, and the player will be able to determine that the setting has been changed. Therefore, in the tenth embodiment and tenth embodiment 1, a configuration in which it is difficult for the player to determine that the setting has been changed in a gaming machine with "ability to increase the number of balls with a small hit" will be described.

(Tenth embodiment)
In the normal state, when the first main game symbols are in a stopped state and the second main game symbols are fluctuating, power failure → power failure recovery {power failure recovery without setting change (RAM clear)}, the effect display device SG. etc., the display of the decorative symbols that indicate the variation of the second main game symbols is displayed extremely small, so that it is difficult to see. There is a risk that you might miss something. Therefore, there is a demand for a gaming machine that does not overlook that the game clerk is changing.

Therefore, in the present embodiment, referring to FIG. 102, in the normal time, when power failure is restored while the first main game symbol is in a stopped state and the second main game symbol is fluctuating, power failure recovery (setting change ( A description will be given of the configuration of a game machine that does not overlook that it is in the process of changing after a power failure recovery without RAM clearing.

After the power is restored, the first main game symbols do not fluctuate on the first main game symbol display device and remain stopped with "g" and "h" lit up. On the second main game symbol display device, the second main game symbols are changing, and "q" and "r" are blinking here. Next, on the performance display device, a "△" indicating that the variation is due to the second main game symbols is displayed blinking in the same manner as the second main game symbols. The game machine frame LED continues to emit light in a different light emission mode from when neither the first main game pattern nor the second main game pattern fluctuates or when the first main game pattern fluctuates. It should be noted that, instead of the gaming machine frame LEDs, it may be configured to be recognizable by board surface LEDs or voice.

In this way, if the game machine frame LED or the like is in a special mode, the game clerk can recognize that the setting has not been changed and the change time is long, and change the setting (RAM clear). By doing so, it is possible to pay attention so that the fluctuation can be stopped, or the store can be opened after waiting for the fluctuation to stop.

In normal times, when power is restored while the first main game symbols are fluctuating and the second main game symbols are stopped, the effect display device SG is not notified in a special manner by the gaming machine frame LED or the like. It is preferable to indicate that the first main game symbols are changing (for example, display a message that the decorative symbols change).

(1 of the tenth embodiment)
The gaming machine according to 1 of the tenth embodiment has the following configuration.
・When the power is turned on {setting change (RAM clear)}, initial symbols {main game symbol display area (first main game symbol display area A21g, second main game symbol display area B21g), auxiliary game symbol display area H21g In order to determine the symbols to be displayed}, a pseudo lottery, a stop pattern lottery, and a variation mode lottery are performed, and the initial pattern is displayed based on the lottery results. )}, in order to determine the symbols to be displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g, after the power is turned on {setting change (RAM clear)} Based on the game state of (1), a lottery for win/fail, a lottery for stop symbols, and a lottery for variation mode (fluctuation time) are performed in a pseudo manner. In other words, in order to determine the symbols to be displayed in the first main game symbol display portion A21g, pseudo-win/fail lottery, stop symbol lottery, and variation mode (variation time) lottery are performed, and the second main game symbol display portion B21g is performed. In order to determine the symbols to be displayed in the pseudo game symbol lottery, stop symbol lottery, variation mode (fluctuation time) lottery, and to determine the symbol to be displayed in the auxiliary game symbol display unit H21g, pseudo Then, a lottery for success or failure, a lottery for stop symbols, and a lottery for variation mode (variation time) are performed. Since this is a pseudo lottery for determining the symbols to be displayed, the symbols are not variably displayed according to the determined variation mode, and the variation mode lottery may be omitted.
By configuring in this way, the symbols displayed in the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display portion H21g after the setting change (RAM clearing) can be display ratio of patterns in each pattern display portion).

(Eleventh embodiment)
The gaming machine according to the eleventh embodiment has the following configuration.
・Different RAM clear range according to the state of main game symbols or auxiliary game symbols (probability variation, non-probability variation, etc.) are both cleared, and when the RAM is cleared with the main game symbols in the non-probability variation state, the set value data is cleared and the state data of the main game symbols are not cleared. Further, the auxiliary game symbols may be configured in the same manner as the main game symbols, and furthermore, it may be configured so that the RAM clearing range is varied depending on the combination of the state of the main game symbols and the state of the auxiliary game symbols. good.
By configuring in this way, it is possible to reduce the processing load when clearing the RAM.

(12th embodiment)
In the gaming machine according to the twelfth embodiment, it will be mentioned that a player can determine whether or not a setting change has been made with respect to a gaming machine called a limiter machine. In addition, since the benefit immediately after the opening of the amusement arcade changes depending on whether it is possible to determine whether or not RAM clearing is possible, there is a possibility that a large profit difference will arise for the player.

First, the limiter machine is a game machine in which the probability variation is continued until the number of big wins reaches a predetermined number. For example, in the case of a gaming machine with a limiter of 3 times, the first hit (1st jackpot) → probability fluctuation entry → jackpot (2nd jackpot) → probability fluctuation entry → jackpot (3rd jackpot) → non-probability fluctuation entry → … The game state transitions in the following order: first win (first big win) → probability variable rush → big win (second big win) → probability variable rush → big win (third big win) → non-probability variable rush → . It should be noted that the limiter can be determined not by the big hit but by the number of probability fluctuation rushes or the like.

In such a limiter machine, when a non-probability variation occurs after a big win, it is possible to determine whether or not the setting has been changed (RAM clear) by referring to the number of big wins in the game day. Specifically, when the setting change (RAM clearing) is performed, the first hit on the game day (first big win) → probability change rush → big win (second big win) → probability change rush → big win (third big win) → It will be a non-probability fluctuation entry, but if the first hit on the game day (first jackpot) → non-probability fluctuation entry, the setting change (RAM clear) has not been performed, and the first hit (jackpot) 1st time)→probability variation→big win (second big win)→probability variation, the game is finished. That is, if the setting change (RAM clear) is performed, the game is started from the non-probability change state, and if the setting change (RAM clear) is not performed, the game can be started from the probability change state. It is possible. In addition, in a game machine that performs an effect indicating that the limiter is reached and the non-probability fluctuation state is reached when the limiter is reached or the non-probability variation pattern is hit, it is possible to grasp when the limiter is reached more clearly than to judge the game state. It is possible.

Thus, in the limiter machine, it is possible for the player to determine whether or not the setting has been changed by winning the jackpot. Since there is a possibility that a large profit difference will occur, if it is a game store that does not want to distinguish that the setting change (RAM clear) has been performed, a configuration that makes it difficult to distinguish the above setting change (RAM clear) is used. Since it is preferable to change the settings (RAM clear) at the time of power-on in the game machine, it is preferable to apply a method that makes it difficult to determine whether the RAM has been cleared in the limiter machine.

(13th embodiment)
In this embodiment, the CPUMC of the main control board M is configured not to transmit the setting value to the CPUSC of the sub control board S, but the CPUMC of the main control board M is set to the CPUSC of the sub control board S. It is also possible to have a configuration in which a value is sent. In this case, it is preferable to transmit the set value at one or more of the following three timings.
(1) After recovery from power failure {recovery from power failure without changing settings (RAM clearing)}, the CPUMC of the main control board M transmits a set value command to the CPUSC of the sub control board S at the timing at which the game becomes possible (2 ) At the fluctuation start timing or fluctuation stop timing, the CPUMC of the main control board M transmits a set value command to the CPUSC of the sub control board S. (3) At the timing of entering the starting port, the sub Send a set value command to the CPUSC of the control board S

In particular, by transmitting a setting value command from the CPUMC of the main control board M to the CPUSC of the sub control board S at the fluctuation start timing or the fluctuation stop timing, the CPUSC of the sub control board S can be set based on the correct setting value for each fluctuation. By transmitting a set value command from the CPUMC of the main control board M to the CPUSC of the sub control board S at the start entrance ball timing, the CPUSC of the sub control board S can start It is possible to perform a performance lottery for a look-ahead performance based on a correct set value at the timing of entering the ball.

(14th embodiment)
In the above embodiment, the configuration of the gaming machine that makes it difficult for the player to determine whether the gaming arcade has changed the settings has been mainly described. A description will be given of the configuration of the gaming machine that allows the user to guess the value.

(1 of the 14th embodiment)
The gaming machine according to 1 of the fourteenth embodiment has a configuration in which the CPUMC of the main control board M can suggest the set value.
・When the power is turned on {setting change (RAM clearing)}, the CPUMC of the main control board M displays the first main game symbol display portion A21g, the second main game symbol display portion B21g, and the auxiliary game symbol display based on the set values. A lottery for initial symbols to be displayed in part H21g is performed. For example, an initial symbol that is likely to be displayed when the set value is good and an initial symbol that is likely to be displayed when the set value is bad are provided, and the initial symbol is drawn with a probability based on the set value. configured to do so. In the case of power failure recovery (power failure recovery without setting change (RAM clearing))}, the initial pattern is randomly selected regardless of the set value.

(2 of the 14th embodiment)
The gaming machine according to the 14th embodiment 2 has a configuration capable of suggesting settings by means of decorative symbols.
・Decorative pattern (combination of decorative patterns) displayed when power is turned on {setting change (RAM clear) / power failure recovery without setting change} or/and decorative pattern displayed at power failure recovery without setting change (decorative pattern combination) ) is determined by lottery based on the set values. ) is likely to be displayed, and if the setting value is bad, the bad setting values ``1'', ``2'' and ``3'' (if ``1'', ``2'' and ``3'' are bad setting values) are displayed. In addition, if there is a high possibility that the setting has been changed or the setting value is good, a pun {for example, 114 (okay)} or a deviation by one (for example, 112) or consecutive numbers (eg, 123) are more likely to be displayed.

Moreover, since it is possible to suggest a combination of lost symbols (decorative symbols) of symbol fluctuations at a specific time using RTC, the following configuration may be used.
・Determine the winning combination of decorative patterns in a specific period by lottery based on the set value. combination is displayed.

By configuring in this way, it is possible to suggest a set value by a decorative pattern (combination of decorative patterns), and it is possible to provide a highly entertaining gaming machine that makes a player guess the set value.

(3 of the 14th embodiment)
In the gaming machine according to 3 of the 14th embodiment, the CPUSC of the sub control board S is configured to determine the timing of setting value suggestion based on the command from the CPUMC of the main control board M. FIG.
(1) The CPUMC of the main control board M transmits a setting suggestion command for displaying a setting suggestion suggesting a setting value to the CPUSC of the sub control board S. (2) The CPUSC of the sub control board S is the main control board. When a setting suggestion command is received from the CPUMC of M, a setting suggestion display is performed based on the set value. The CPUMC of the control board M transmits a setting suggestion command to the CPUSC of the sub control board S. When the CPUSC of the sub-control board S receives the setting suggestion command, it suggests the current set value by means of the effect display device SG, the speaker D24, the effect light emitters (frame light emitters, etc.) and the like. In addition, as the timing at which the CPUMC of the main control board M transmits the setting suggestion command, when the game ball enters the winning hole under a specific situation (when 4 holds, when the hold changes, during a big hit, etc.), a predetermined condition ( 10 consecutive wins, etc.) may be satisfied. Note that the condition (timing) for transmitting the setting suggestion command may be one, a case where any one of two or more conditions is satisfied, or a case where two or more conditions are satisfied.

<<Summary of problems and effects in this example>>
Here, the problems and effects of each embodiment described above will be described in detail below.

<Problem in this embodiment>
In a game machine having a small hit, there is a demand for creation of a game with a higher level of interest.

<Effects of this embodiment>
As pattern A, a new hold does not occur from the occurrence of the hold related to the small hit to the start of the pattern change related to the small win (when the number of holds is 2 or more, the pattern change is difficult to start = The time from when the suspension related to the small win occurs until the opening of the upper shielding member C24 is started tends to be long), and as Pattern B, the suspension related to the small win occurs after the suspension related to the small win A new hold occurs before the pattern fluctuation starts (the pattern fluctuation is likely to start while the number of holds is always maintained at 2 or more = the upper shielding member after the hold related to the small hit occurs The opening timing of the upper shielding member C24 may change in the case where the time until the opening of C24 is started tends to be shortened. Furthermore, it is possible to change whether or not the opening timing of the upper shielding member C24 matches the opening timing of the lower shielding member C25 according to such a change in the opening timing of the upper shielding member C24. It is possible to provide a game machine with high interest such that attention is paid to whether or not the ball enters the V winning hole C22 when winning a small prize.
<Problem in Second Embodiment>
There has been a demand for a gaming machine capable of arousing a player's sense of expectation in terms of whether or not a transition to a probability variable gaming state is made according to the jackpot symbols.

<Effects of Second Embodiment>
Depending on whether or not the game ball enters the specific area during the special game, it is determined whether or not to shift to the probability fluctuation game state after executing the special game (If there is a ball entered in the specific area, the probability fluctuation game state , does not shift to the probability variable gaming state without entering a ball) game machine (so-called ball probability type gaming machine), fluctuation during the non-probability variable gaming state and time reduction gaming state when the probability variable gaming state does not occur By making the mode (and effect) different from the variation mode (and effect) during the probability variable game state, it is possible to execute an appropriate effect according to the profit mode of the player. Although not particularly shown in this example, when executing a sorting game, special effects (effects to incite whether the second big winning opening C20 will be long open, entry to the specific area C22 Effect of inciting whether or not the ball will be played, effect of notifying that the ball has been entered into the specific area C22, etc.) may be configured to be executed (the execution mode is not particularly limited, but for example , In the case of an effect to notify that the ball has entered the specific area C22, the effect display device SG or the effect display device SG is displayed at the timing (preferably immediately after) when the ball is entered. It can be exemplified that the effect device (for example, a so-called movable body accessory for performance, a light guide plate, etc.) provided on the front side is configured to execute the notification (for example, on the effect display device SG An image is displayed on the light guide plate by displaying an image drawn with "V", by displacing the movable body accessory for production from the initial position to a position where production is possible, or by irradiating the light guide plate with light. float, etc.)}. It should be noted that when executing the effect to notify that the ball has been entered into the specific area C22, when a special game is won in a specific game state (for example, probability variable game state) or a specific special pattern (jackpot pattern) ) is won, in a special game in which an open pattern designed to make it almost certain that the ball enters the specific area C22 is executed, an image drawn with "V" is displayed sparingly (for example, , small display), etc., in a situation where there is a possibility that a special game will not be performed that is designed to make the ball entering the specific area C22 almost certain (e.g., entering the specific area C22 in the special game In a situation where the ball easiness is unknown), after that, when an open pattern designed to make the ball entering the specific area C22 almost certain is executed, the ball was entered into the specific area C22 It is also preferable to execute an effect different from the effect of notifying that effect, and thereby the effect can be executed with a priority according to need.

M Main control board A 1st main game peripheral device, A10 1st main game start port A11s 1st main game start port entrance detection device, A20 1st main game symbol display device A21g 1st main game symbol display unit, A21h 1 main game symbol holding display portion B 2nd main game peripheral device, B10 2nd main game start opening B11s 2nd main game start opening ball detection device, B11d 2nd main game start opening electric accessory B20 2nd main game symbol Display device, B21g 2nd main game symbol display unit B21h 2nd main game symbol reservation display unit C 1st and 2nd main game shared peripheral device, C10 1st big winning port C11s 1 large winning opening electric accessory C20 2nd large winning opening, C21s 2nd large winning opening winning detection device C21d 2nd large winning opening electric accessory, D30 game area D44 launch handle D32 outer rail, D34 inner rail H auxiliary game peripheral Equipment, H10 Auxiliary game start port H11s Auxiliary game start port entrance detection device, H20 Auxiliary game design display device H21g Auxiliary game design display unit, H21h Auxiliary game design reservation display unit S Sub control board, SM Production display control means (sub main control board)
SG Performance display device SG10 Display area SG11 Decorative pattern display area SG12 First reservation display part SG13 Second reservation display part KH Prize ball payout control board KE Prize ball payout device KE10 Payout unit D16 Transparent plate KR Prize ball rail KT Prize ball tank, KH prize ball payout control board Ea power switch, D42 launcher E power supply unit, D40 launch control board C22 specific area (V prize opening),
C23 2nd large prize winning outlet discharge port, C23s 2nd large prize winning outlet discharge detection device C24 Upper shielding member, C25 Lower shielding member C22s V winning prize inlet ball detection device SB Sub-input button, Sub-input button input detection device KH Prize ball payout Control board, KE Prize ball payout device 3100 Transmission/reception control means 3110 Reception control means 3111 Main side reception information temporary storage means 3300 Payout control means 3310 Payout processing related information temporary storage means 42 Launcher EU ECO unit 50 Operation unit device

Claims (1)

a first control board for controlling the progress of a game;
a second control board for controlling the giving of game balls based on information from the first control board;
a power supply board that supplies power;
a plurality of winning holes into which game balls fired toward the game area can enter;
a circulation mechanism that makes it possible to shoot again the game balls that have been shot toward the game area;
Equipped with a front unit having at least a display unit for the number of held balls composed of at least a plurality of 7-segment LEDs , a first display unit, a second display unit, and an operation unit that can be operated by the player,
The first control board has a first storage means capable of storing data used in the first control board,
The second control board has a second storage means capable of storing data used in the second control board,
Power supply to the second control board is configured to be performed directly from the power supply board,
Power is supplied to the first control board from the power supply board via the second control board,
The second control board has a capacitor capable of supplying power to the second storage means,
Even when power is not supplied from the power supply board to the second control board, data in the second storage means can be retained by power supply from the capacitor of the second control board,
Even if power is not supplied to the first control board because the power supply board does not supply power to the second control board, the data in the first storage means is stored by power supply from the capacitor of the second control board. configured to hold,
The first display unit is configured to display first information corresponding to a predetermined error related to the second control board,
The second display unit is configured to display second information different from the first information,
The display area of the first display section is configured to be smaller than the display area of the number-of-balls display section,
The display area of the second display section is configured to be smaller than the display area of the number-of-balls display section,
The first display section, the second display section, and the number-of-balls display section are arranged at predetermined positions on the front unit that are identifiable by the player ,
The first display unit is arranged closer to the player than the number-of-balls display unit,
The second display section is arranged on the right side of the first display section,
The distance between the first display section and the second display section is configured to be longer than the horizontal width of at least one 7-segment LED.
A pachinko machine characterized by:

Images