JP7107572B2 - game machine - Google Patents

Description

The present invention relates to a game machine such as a pachinko game machine or a reel-type game machine (pachislot game machine).

As an example of a gaming machine, for example, as described in Patent Document 1 below, during execution of a jackpot game, the player is notified of the number of times the symbol variation game has been executed since the previous jackpot. A game machine capable of displaying game history information related to a machine is known.

JP-A-2000-334125

The pachinko gaming machine as described in Patent Document 1 allows a player to play a game while checking the game history information related to the game machine during a limited period of time during the jackpot game. However, it is difficult to say that such a game machine gives a positive gaming motivation to a player in the stage before playing a game or in the stage of making a trial shot to select a game table. Met.

The present invention has been made in view of the above circumstances. That is, the problem is to provide a gaming machine that gives a positive gaming motivation to those who are considering which gaming machine to play games on.

The gaming machine of the present invention is
In a gaming machine equipped with a game control means capable of setting one of a plurality of set values with mutually different jackpot determination probabilities,
game history information display means capable of displaying game history information held in the game machine;
an initialization lottery means for lottery for determining whether or not to initialize the game history information when the power is turned on ;
The gaming machine is characterized in that the game history information is initialized at different ratios when the power is turned on with a setting change operation or reset operation, and when the power is turned on without these operations. .

According to the gaming machine of the present invention, it is possible to provide positive gaming motivation to those who are considering which gaming table to play.

1 is a perspective view of a gaming machine according to an embodiment; FIG. It is a perspective view showing the structure of the gaming machine frame of the gaming machine. It is a front view of the gaming machine. It is a front view of a game board provided in the gaming machine. It is an enlarged view of the A portion shown in FIG. 4, and is a view showing display devices provided in the gaming machine. It is a block diagram showing an electrical configuration related to a game control board and a payout control board of the gaming machine. It is a block diagram showing an electrical configuration related to the effect control board of the game machine. It is a perspective view showing the back side of the gaming machine. (A) is a perspective view showing the game control board and the game control board case, and (B) is a front view showing the game control board and the game control board case. It is an explanatory diagram showing a 7-segment display provided on the game control board. It is an explanatory diagram for explaining the wiring relationship of the game control board, the external terminal board, the data display, and the hall computer of the gaming machine. It is a hit classification determination table. Various random number tables acquired by the game control microcomputer. (A) is the jackpot determination table used when the set value is "1", (B) is the jackpot determination table used when the set value is "2", and (C) is the jackpot determination table used when the set value is "3" , (D) is a jackpot determination table used when the set value is "4", (E) is a jackpot determination table used when the set value is "5", and (F) is a jackpot determination table used when the set value is "6" is a table. (A) is a reach determination table, (B) is a normal symbol hit determination table, and (C) is a normal symbol variation pattern selection table. It is a special figure variation pattern determination table. It is an electric chew opening pattern determination table. It is explanatory drawing which showed the procedure of operation regarding setting change mode, and the change of the production|presentation mode. It is explanatory drawing which showed the procedure of operation regarding setting confirmation mode, and the change of the production|presentation mode. (A) is an explanatory diagram showing a case where an error display is performed on a 7-segment display. (B) is an explanatory diagram showing an operation suggestion image on a display screen, an error sound output from a speaker, and an error light emission mode of a frame lamp and a board lamp. 4 is a flowchart of main control main processing; 4 is a flowchart of power-on processing; 9 is a flowchart of setting change mode processing; 9 is a flowchart of setting value confirmation mode processing; It is a flowchart of a process at the time of power failure recovery. 4 is a flowchart of error mode processing; 10 is a flowchart of main-side timer interrupt processing; 7 is a flowchart of power-off monitoring processing; 9 is a flowchart of sub-control main processing; 4 is a flowchart of reception interrupt processing; 10 is a flowchart of 1 ms timer interrupt processing; 10 is a flowchart of 10 ms timer interrupt processing; It is the first part of the flowchart of the received command analysis process. FIG. 11 is the second part of the flow chart of the received command analysis process; FIG. 3 is the third part of the flowchart of the received command analysis process; 10 is a flow chart of power-on variable game number reset processing 1. FIG. It is a flowchart of a first reset lottery process. It is a flowchart of a second reset lottery process. (A) is the first reset table used when the set value is "1", (B) is the second reset table used when the set value is "2", and (C) is the second reset table used when the set value is "3". 3 reset table, (D) is the fourth reset table used when the set value is "4", (E) is the fifth reset table used when the set value is "5", (F) is the set value "6" This is a sixth reset table that is sometimes used. (G) is the seventh reset table used when the set value is "1", (H) is the eighth reset table used when the set value is "2", and (I) is the 7th reset table used when the set value is "3". 9 reset table, (J) is the 10th reset table used when the set value is "4", (K) is the 11th reset table used when the set value is "5", (L) is the set value "6" This is a twelfth reset table that is sometimes used. (A) is the first reset display mode lottery table used when the set value is "1, 2", (B) is the second reset display mode lottery table used when the set value is "3, 4", (C) is the set value This is a third reset display mode lottery table used when "5, 6". 10 is a flowchart of a mini character effect process 1 at power-on; 10 is a flowchart of mini character reset lottery processing. (A) is the first mini character determination table used when the set value is "1", (B) is the second mini character determination table used when the set value is "2", and (C) is used when the set value is "3". (D) is the fourth mini character determination table used when the set value is "4"; (E) is the fifth mini character determination table used when the set value is "5"; (F) is the setting This is the sixth mini character determination table used when the value is "6". It is a flow chart of the fluctuation effect start processing. It is a flow chart of an auxiliary effect start process. (A) is the first mini character determination table used when the set value is "1 to 3", (B) is the second mini character determination table used when the set value is "4 to 6", (C) is the set value "1" 1 to 3", (D) is the second mini character dialogue determination table to be used when the setting value is "4 to 6", (E) is when the setting value is "1 to 3" First operation pattern determination table to be used, (F) is the second operation pattern determination table used when the setting value is "4 to 6", (G) is the first status information update used when the setting value is "1 to 5" Table, (H) is the second status information update table used when the set value is "6". 10 is a flowchart of change number display update processing. (A) is a diagram showing a first mini-character image MK1 and a first frame region YR1 (white frame, frame image at reset) in the reset display of mini-character information. (B) is a diagram showing the second mini-character image MK2 and the second frame region YR2 (blue frame, normal frame image) in the continuous display of the previous information. (C) is a diagram showing a case where the third mini-character image MK3 and the character announcement effect MS1 are executed. (D) is a diagram showing a case where the third mini-character image MK3 and the character announcement effect MS2 are executed. (A) is a diagram showing a reset display mode when winning in the normal display mode (white). (B) is a diagram showing a reset display mode when winning the first special display mode (blue). (C) is a diagram showing a reset display mode when winning the second special display mode (red). (A) is a diagram showing a reset display mode when winning a special display mode (gold). (B) is a diagram showing a case where the last time variable display number information is inherited when the previous display content was the first special display mode (blue). (C) is a diagram showing a case where the last time variable display number information is inherited when the previous display content was the special display mode (gold). 10 is a flowchart of a mini character presentation process 2 at power-on; (A) is a mini character reset table when the first setting is changed, and (B) is a mini character reset table when the first setting is not changed. (C) is a mini character reset table when the second setting is changed, and (D) is a mini character reset table when the second setting is not changed. This is a mini-character reset determination table at power-on. FIG. 11 is a flow chart of power-on variable game number reset processing 2. FIG.

1. Structure of Game Machine A pachinko game machine PY1, which is an embodiment of the present invention (hereinafter referred to as "this embodiment (first embodiment)"), will be described with reference to the drawings. In the following description, the left-right direction of each part of the pachinko gaming machine PY1 will be described as being the same as the left-right direction for the player facing the pachinko gaming machine PY1. Also, the front direction of each part of the pachinko gaming machine PY1 is defined as the direction toward the player facing the pachinko gaming machine PY1, and the rear direction of each part of the pachinko gaming machine PY1 is defined as the direction away from the player facing the pachinko gaming machine PY1. do.

As shown in FIG. 1, the pachinko game machine PY1 of this embodiment has a game machine frame 2. As shown in FIG. As shown in FIG. 2, the game machine frame 2 constitutes the outer shell of the pachinko game machine PY1, and includes an outer frame 22, an inner frame 21 and a front door 23 (front frame). The outer frame 22 is a vertically rectangular frame that forms the outer shell of the pachinko game machine PY1. The inner frame 21 is arranged inside the outer frame 22, and is a vertically rectangular frame on which the later-described game board 1 is attached. The front door 23 is arranged on the front side of the outer frame 22 and the inner frame 21 and has a vertical rectangular shape to protect the game board 1 . The front door 23 is a portion facing the player, and is decorated with various decorations.

The game machine frame 2 is configured with a hinge portion 24 on the left end side. The front door 23 is rotatable with respect to the outer frame 22 and the inner frame 21 by the hinge portion 24, and the inner frame 21 is rotatable with respect to the outer frame 22 and the front door 23. It's becoming An opening 23a is formed in the center of the front door 23, and a transparent plate 23t is attached to the opening 23a so that the player can visually recognize a game area 6, which will be described later. Although the transparent plate 23t is a glass plate in this embodiment, it may be a transparent synthetic resin plate. That is, the transparent plate 23t may be one that allows the game area 6 to be visually recognized from the front.

In the game machine frame 2, if the outer frame 22 is regarded as corresponding to the "base frame", the inner frame 21 and the front door 23 can be regarded as corresponding to the "front frame". Further, in the game machine frame 2, if the outer frame 22 and the inner frame 21 are regarded as equivalent to the "base frame", the front door 23 can be regarded as equivalent to the "front frame".

As shown in FIGS. 1 to 3, the front door 23 has a handle 72k (game ball hitting means) for shooting game balls with a shooting intensity corresponding to the rotation angle, and a hitting ball supply tray (for storing game balls). An upper tray) 34 and a surplus ball receiving tray (lower tray) 35 for storing game balls that cannot be accommodated in the batted ball supply tray 34 are provided. Further, the front door 23 is provided with an effect button (input unit) 40k and a select button 42k that can be operated by the player at the time of an effect executed as the game progresses. The select button (cross key) 42k is composed of an up button, a down button, a left button, and a right button. Further, the front door 23 is provided with a decorative frame lamp 212 and a speaker (not shown in FIG. 1) for outputting sound.

A game board 1 shown in FIG. 4 is attached to the game machine frame 2 . As shown in FIG. 4, the game board 1 is formed with a game area 6 surrounded by a rail member 62 in which a game ball shot by operating the handle 72k flows down. Also, the game board 1 is provided with a large number of board lamps 54 for decoration. In the game area 6, a plurality of game pegs for guiding game balls are projected. The game board 1 is formed by integrating a plate-shaped member arranged on the front side and a back unit arranged on the rear side (a unit for attaching various control boards, an image display device 50, a harness, etc., which will be described later). It is.

An image display device 50 (effect display means, image display means), which is a liquid crystal display device, is provided near the center of the game area 6 . Note that the image display device may be another image display device such as an organic EL display device. The display screen 50a (display unit) of the image display device 50 has a production design display area for performing variable display of production design EZ (decorative design) synchronized with variable display of the first special design and the second special design described later. . The effect of displaying the effect symbol EZ is called the effect symbol variation effect. The production design fluctuation production is sometimes called "decorative design fluctuation production" or simply "variation production". The effect symbol display area is composed of three effect symbol display areas, for example, "left", "middle" and "right". A left performance symbol EZ1 is displayed in the left performance symbol display area, a middle performance symbol EZ2 is displayed in the medium performance symbol display area, and a right performance symbol EZ3 is displayed in the right performance symbol display area.

Each of the effect symbols EZ consists of a plurality of symbols representing numbers "1" to "9", for example. The image display device 50 is a first special symbol displayed by a first special symbol indicator 81a and a second special symbol indicator 81b, which will be described later, by a combination of the left performance symbol EZ1, the middle performance symbol EZ2, and the right performance symbol EZ3. And the result of the variable display of the second special symbol (that is, the result of the jackpot lottery) is displayed in an easy-to-understand manner.

For example, when a jackpot is won, the performance symbol EZ is stopped and displayed with double numbers such as "777". In addition, when it is a miss, the performance symbol EZ is stopped and displayed with a loose pattern such as "637". This makes it easier for the player to grasp the progress of the game. That is, the player generally grasps the result of the jackpot lottery by the image display device 50 rather than by the first special figure display device 81a or the second special figure display device 81b. In addition, the position of the effect symbol display area may not be fixed. Further, as a mode of variable display of the effect symbols EZ, for example, there is a mode of scrolling in the vertical direction.

The image display device 50, in addition to the effect symbol variation effect using the effect symbol EZ as described above, the jackpot effect that is performed in parallel with the jackpot game, the demo effect for waiting for customers (customer waiting effect), the variation described later The display screen 50a displays the number-of-games information display effect, an auxiliary effect (mini character effect), and the like. In addition, in the effect symbol variation effect, effect images other than the effect symbol EZ such as a background image and a character image are displayed in addition to the effect symbol EZ such as numbers.

Further, the display screen 50a of the image display device 50 has a pending icon display area for displaying a pending icon HA (effect pending image) according to the number of stored first special figure pending and second special figure pending, which will be described later. By the display of the pending icon HA, the storage number of the first special figure pending displayed in the first special figure pending display 83a described later, the second special shown in the second special pending display 83b described later It is possible to clearly indicate to the player the number of stored figures that are reserved.

In the display screen 50a of the image display device 50, a variable game number display area HR is provided in the upper right area of the display screen 50a. By doing so, it is possible to notify the player. In addition, an auxiliary effect display area MH (mini character effect display area) is provided in the lower right area of the display screen 50a of the image display device 50, so that an auxiliary effect (mini character effect) can be executed. Details of the variable game number display area HR and the auxiliary effect display area MH will be described later.

A center frame 61 (inner wall portion) is arranged near the center of the game area 6 and in front of the image display device 50 . At the bottom of the center frame 61, a stage 61s capable of guiding a game ball rolling on the upper surface to the first starting port 11 described later is formed. A warp 61w is provided on the left side of the center frame 61 to allow game balls to flow in from the entrance and flow out to the stage 61s from the exit. A plate movable body 55k that can move up and down is provided on the upper portion of the center frame 61. As shown in FIG. The board movable body 55k is movable from an origin position above the display screen 50a to an effect position overlapping the center of the display screen 50a in the front-rear direction.

Below the image display device 50 in the game area 6, there is provided a first starting winning device 11D having a first starting opening 11 (ball entry opening) in which the ease with which a game ball enters is always the same. The first starting port 11 is also referred to as a first ball-in port, a fixed ball-in port, a first starting prize-winning port, or a first starting area. Further, the first start winning device 11D is also called first ball entry means, fixed ball entry means, or first start prize winning device. Winning of the game ball to the first starting port 11 triggers lottery for the first special symbol (big hit lottery, ie, acquisition and determination of big hit random numbers, etc.).

Also, below the first starting port 11 in the game area 6, a normal variable winning device (normal electric accessory, so-called electric chew) 12D having a second starting port 12 (ball entrance) is provided. The second starting hole 12 is also referred to as a second ball entry hole, a variable ball entry hole, a second starting winning hole, or a second starting region. The electric chew 12D is also referred to as a second ball entry means, a variable ball entry means, or a second starting winning device. Winning of the game ball to the second starting port 12 triggers a second special symbol lottery (jackpot lottery).

The electric chew 12D has an electric chew opening/closing member 12k (ball opening opening/closing member) that takes an open state and a closed state, and opens and closes the second starting port 12 by operating the electric chew opening/closing member 12k. The electric tuning opening/closing member 12k is driven by an electric tuning solenoid 12s, which will be described later. When the electric chew opening/closing member 12k is in an open state, it is possible to enter a game ball into the second starting port 12, and when it is in a closed state, it is impossible to enter a game ball into the second starting port 12.例文帳に追加Become. That is, the second starting hole 12 is a starting hole in which the ease with which a game ball enters can be changed. In addition, if the electric chew makes it easier for the ball to enter the second starting port 12 when the electric chew opening/closing member is in the open state than when it is in the closed state, It does not have to be the one that makes it impossible to enter the second starting port 12 .

Also, on the right side of the first starting port 11 in the game area 6, a big winning device (special electric accessory) 14D having a big winning port 14 is provided. The big winning opening 14 is also called a special winning opening (special winning section). The big winning device 14D is also called an attacker (AT), a special winning means, or a special variable winning device. The big prize winning device 14D has an AT opening/closing member 14k (special prize opening/closing member) that takes an open state (first state) and a closed state (second state). It opens and closes. The AT opening/closing member 14k is driven by an AT solenoid 14s, which will be described later. A game ball can enter the big winning opening 14 only when the AT opening/closing member 14k is in an open state.

A gate 13 through which game balls can pass is provided on the right side of the center frame 61 . The gate 13 is also called a passage opening or a passage area. Passage of the game ball to the gate 13 is a trigger for execution of a normal symbol lottery (that is, normal symbol random number (hit random number) acquisition and determination) that determines whether or not to open the electric chew 12D. Furthermore, a plurality of general prize winning openings 10 are provided in the lower portion of the game area 6 . Also, at the bottom of the game area 6, an out port 19 is provided for discharging out of the game area 6 game balls that have been hit into the game area 6 but have not won in any of the winning openings.

In the game area 6 in which various winning openings are arranged, there are a left game area 6L (first game area) on the left side of the center in the horizontal direction (first game area) and a right game area 6R (second game area) on the right side. There is. A hitting method of shooting a game ball so that the game ball flows down the left game area 6L is called left hitting. On the other hand, a hitting method of shooting a game ball so that the game ball flows down the right game area 6R is called right hitting. In the pachinko machine PY1 of this embodiment, the flow path through which the game balls flow down when the game is played with the left hand is called the first flow path R1, and the flow path through which the game balls flow down when the game is played with the right hand. , the second flow path R2.

A first starting port 11, a general prize winning port 10, an electric tube 12D, and an out port 19 are provided on the first flow path R1. A player can aim to win a prize to the first starting opening 11 or the general winning opening 10 by hitting a game ball so as to flow down the first flow path R1. In addition, since the gate 13 is not arranged on the first flow path R1, the electric tube 12D is not opened when the ball is hit to the left.

On the other hand, a gate 13, a general prize winning port 10, a big prize winning device 14D, an electric tube 12D, and an out port 19 are provided on the second flow path R2. By hitting the game ball so as to flow down the second flow path R2, the player can aim to pass through the gate 13, or win a prize in the general winning opening 10, the second starting opening 12, and the big winning opening 14. can.

Also, as shown in FIG. As shown in FIG. 5, the display devices 8 include a first special symbol display device 81a that variably displays the first special symbol, a second special symbol display device 81b that variably displays the second special symbol, and a normal symbol. A normal map display 82 for variably displaying (normal map) is included. The first special symbol is also referred to as the first special symbol or special symbol 1, and the second special symbol is also referred to as the second special symbol or special symbol 2. In addition, the normal pattern is also called a general pattern.

In addition, in the display device 8, the first special figure suspension display 83a that displays the number of storage of the operation suspension (first special figure suspension) of the first special figure display 81a, the operation suspension of the second special figure display 81b (Second special figure suspension) 2nd special figure suspension display 83b for displaying the number of memories, and normal figure suspension display 84 for displaying the number of operation suspension (normal figure suspension) of the normal figure display 82 is

The variable display of the first special symbol is performed with the winning of the game ball to the first starting port 11 as a trigger. The variable display of the second special symbol is performed with the winning of the game ball to the second starting port 12 as a trigger. In the following description, the first special symbol and the second special symbol may be collectively referred to as a special symbol (special symbol). Moreover, the 1st special figure indicator 81a and the 2nd special figure indicator 81b may be generically called the special figure indicator 81. As shown in FIG. Also, the first special figure reservation display 83a and the second special figure reservation display 83b may be collectively referred to as the special figure reservation display 83. In addition, the first special figure reservation and the second special figure reservation may be collectively referred to as special figure reservation.

In the special figure display device 81, the special symbol (identification symbol) is variably displayed (variable display) and then stopped, so that a lottery (special symbol lottery, The result of the jackpot lottery) is notified. A special symbol to be stopped and displayed (a stop symbol, a special symbol derived and displayed as a display result of variable display) is one special symbol selected from a plurality of types of special symbols by a special symbol lottery. When the stop pattern is a predetermined specific special pattern (a special pattern of a specific stop mode, i.e., a jackpot pattern), an opening pattern corresponding to the type of the stopped and displayed specific special pattern (that is, the type of the jackpot won) is selected. A jackpot game (an example of a special game) is performed to open the big winning hole 14.例文帳に追加In addition, the opening pattern of the big winning opening in the special game will be described later.

Specifically, the special symbol indicator 81 is composed of, for example, eight LEDs (Light Emitting Diodes) arranged side by side, and displays a special symbol corresponding to the result of the jackpot lottery according to its lighting mode. be. For example, if you win a jackpot (one of the multiple types of jackpots described later), ``○○●●○○●●'' (○: lights up, ●: lights out) 1, 2, from the left A jackpot pattern in which the fifth and sixth LEDs are lit is displayed. In addition, if the game is lost, a lost pattern is displayed in which only the rightmost LED lights up, such as "●●●●●●●○". A mode in which all the LEDs are extinguished may be adopted as the lost pattern. In addition, the lost design is not a specific special design. In addition, before the special symbols are stopped and displayed, the special symbols are variably displayed for a predetermined variable time. It is a mode. It should be noted that the variable display mode may be anything, such as blinking all the LEDs all at once, unless each LED is stopped (lighted up in a specific mode).

In this pachinko game machine PY1, when there is a winning (entering a ball) of a game ball into the first start port 11 or the second start port 12, the value of various random numbers such as jackpot random numbers (numerical information , determination information) is temporarily stored in the special figure reservation storage unit 105 described later. Specifically, if the winning to the first start port 11 is stored as the first special figure reservation, it is stored in the first special figure reservation storage unit 105a described later, and if the winning to the second start opening 12 is the second special It is stored in the later-described second special figure suspension storage unit 105b as figure suspension. There is an upper limit to the number of special figure reservations that can be stored in each special figure reservation storage unit 105, and the upper limit value in this embodiment is "4".

The special figure reservation stored in the special figure reservation storage unit 105 is terminated when the variable display of the special symbol based on the special figure reservation becomes possible. Digestion of the special figure reservation means to determine the jackpot random number or the like corresponding to the special figure reservation, and to execute the variable display of the special symbol for showing the determination result. Therefore, in the pachinko game machine PY1, when the variable display of the special symbols based on the winning of the game ball to the first start port 11 or the second start port 12 cannot be performed immediately after the winning, that is, the execution of the variable display of the special symbols. Even if a prize is won during execution of a special game, the right of a jackpot lottery for the prize can be reserved up to a predetermined number.

And the number of such special figure reservations is displayed on the special figure reservation indicator 83. Specifically, each special figure reservation indicator 83 is composed of, for example, four LEDs, and displays the number of special figure reservations by lighting the LEDs by the number of special figure reservations.

The variable display of normal symbols is performed with the passage of the game ball to the gate 13 as a trigger. The normal symbol display device 82 notifies the result of the normal symbol lottery based on the passage of the game ball to the gate 13 by displaying the normal symbol variably (variably displaying) and then stop-displaying it. A normal pattern to be stopped and displayed (a normal pattern stop pattern, a normal pattern derived and displayed as a display result of variable display) is one normal pattern selected from a plurality of types of normal patterns by a normal pattern lottery. When the stop-displayed normal symbol is a predetermined specific normal symbol (a normal symbol in a predetermined stop mode, that is, a normal winning symbol), the second starting port 12 is opened in an opening pattern according to the current game state. Auxiliary game is played to make it possible. The opening pattern of the second starting port 12 will be described later.

Specifically, the normal symbol display device 82 is composed of, for example, two LEDs (see FIG. 5), and displays normal symbols corresponding to the result of the normal symbol lottery according to the lighting mode thereof. For example, if the lottery result is a win, a normal win pattern with both LEDs lit up is displayed, such as "○○" (○: lit, ●: unlit). When the lottery result is a loss, a normal losing pattern is displayed, such as "●○", in which only the right LED lights up. A mode in which all the LEDs are extinguished may be employed as a normal losing pattern. It should be noted that the normal losing design is not a specific normal design. Before the normal symbols are stopped and displayed, the normal symbols are variably displayed for a predetermined variable time. It should be noted that the variable display mode may be anything, such as blinking all the LEDs all at once, unless each LED is stopped (lighted up in a specific mode).

In the pachinko game machine PY1, when a game ball passes through the gate 13, the value of the normal symbol random number (hit random number) acquired for the passage is stored in the normal pattern reservation storage unit 106 described later as normal pattern reservation. memorized once. There is an upper limit to the number of normal pattern reservations that can be stored in the general pattern reservation storage unit 106, and the upper limit value in this embodiment is "4".

The normal pattern reservation stored in the normal pattern reservation storage unit 106 is terminated when the variable display of the normal pattern based on the normal pattern reservation becomes possible. The digestion of the normal pattern reservation means that the normal design random number (hit random number) corresponding to the normal pattern reservation is determined, and the normal design variable display is performed to show the determination result. Therefore, in this pachinko game machine PY1, when the variable display of the normal symbols based on the passage of the game ball through the gate 13 cannot be performed immediately after the passage, that is, during the execution of the variable display of the normal symbols or during the execution of the auxiliary game, a prize is won. Even if there is, with a predetermined number as the upper limit, it is possible to reserve the right of the normal symbol lottery for the passage.

And the number of such normal map reservations is displayed on the normal map reservation display 84 . Specifically, the normal map hold indicator 84 is composed of, for example, four LEDs, and displays the number of normal map reserves by lighting the LEDs by the number of normal map reserves.

2. Electrical Configuration of Gaming Machine Next, the electrical configuration of the pachinko gaming machine PY1 will be described with reference to FIGS. 6 and 7. FIG. As shown in FIGS. 6 and 7, the pachinko game machine PY1 includes a game control board 100 (main control board) for controlling game profits such as jackpot lottery and game state transitions, and effects executed as the game progresses. Effect control board 120 (sub-control board) for controlling related, payout control board 170 and the like for controlling payout of game balls. The game control board 100 constitutes a main control section together with the payout control board 170, and the effect control board 120 constitutes a sub-control section together with an image control board 140 and a sub-drive board 162 which will be described later.

In addition, the sub-control unit includes at least the effect control board 120, and can control the game effect using the effect means (image display device 50, speaker 149, board lamp 54, board movable body 55k, frame lamp 212, etc.) Just do it.

As shown in FIG. 6, the game control board 100 is mounted with a game control one-chip microcomputer (hereinafter referred to as "game control microcomputer") 101 for controlling the progress of the game of the pachinko game machine PY1 according to a program. The game control microcomputer 101 (game control means) includes a game ROM (Read Only Memory) 103 storing a program for controlling the progress of the game, a game RAM 104 used as a work memory, and a game ROM 103. It includes a game CPU (Central Processing Unit) 102 for executing stored programs, and a game I/O (Input/Output) port 118 for inputting and outputting data and signals. In the game RAM 104, in addition to the above-described special figure reservation storage unit 105 (first special figure reservation storage unit 105a and second special figure reservation storage unit 105b) and general figure reservation storage unit 106, set value information storage unit described later 107 and a base information storage unit 108 are provided. The game control board 100 is also provided with a 7-segment display 300 and a setting key cylinder 180, which will be described later.

In addition, various sensors and solenoids are connected to the game control board 100 via the relay board 110 . Therefore, a signal is input from each sensor to the game control board 100, and a signal is output from the game control board 100 to each solenoid. Specifically, as sensors, a first start sensor 11a, a second start sensor 12a, a gate sensor 13a, a big winning sensor 14a, a general winning sensor 10a, and a discharge sensor 18a are connected. In addition, the front door opening sensor TS1 and the inner frame opening sensor TS2 are electrically connected to the game control microcomputer 101 (game control means) of the game control board 100 in this embodiment via connectors and wires. Therefore, the game control microcomputer 101 is configured to be able to grasp the open state of the inner frame 21 and the front door 23 of the game machine.

The first starting hole sensor 11 a is provided in the first starting hole 11 and detects a game ball that has entered the first starting hole 11 . The second starting hole sensor 12a is provided in the second starting hole 12 and detects a game ball that has entered the second starting hole 12 . The gate sensor 13 a is provided inside the gate 13 and detects a game ball that has passed through the gate 13 . The big winning hole sensor 14 a is provided in the big winning hole 14 and detects a game ball that has entered the big winning hole 14 . The general winning hole sensor 10 a is provided in the general winning hole 10 and detects a game ball that has entered the general winning hole 10 .

The discharge port sensor 18a is provided in a discharge port (not shown) for discharging game balls to the outside of the pachinko gaming machine PY1, and detects game balls that have passed through the discharge port. The discharge port is provided at the lower end of the inner frame 21, and the game ball driven into the game area 6 is discharged from the first start port 11, the second start port 12, the big winning port 14, the general winning port 10, the out After entering one of the openings 19, the ball finally passes through the ejection opening. Therefore, it is possible to detect all the game balls hit into the game area 6 by detecting the game balls that have passed through the discharge port with the discharge port sensor 18a. The number of all game balls hit into the game area 6 can be called the total number of shot balls. Also, since the total number of shots is the same as the number of all game balls ejected outside the pachinko gaming machine PY1, it can also be called the number of ejected balls, the total number of ejected balls, or the number of out balls.

As solenoids, an electric tuning solenoid 12s and an AT solenoid 14s are connected. The electric chew solenoid 12s drives the electric chew opening/closing member 12k of the electric chew 12D. The AT solenoid 14s drives the AT opening/closing member 14k of the big winning device 14D.

Furthermore, the game control board 100 includes a special figure indicator 81 (first special figure indicator 81a and second special figure indicator 81b), a general figure indicator 82, a special figure reservation indicator 83 (first special figure reservation display Device 83a and second special figure reservation indicator 83b), and general figure reservation indicator 84 are connected. That is, display control of these display devices 8 is performed by the game control microcomputer 101 .

The game control board 100 also transmits various commands and signals to the payout control board 170 and receives signals from the payout control board 170 for payout monitoring. The payout control board 170 includes a card unit CU (which is installed adjacent to the pachinko game machine PY1 and enables ball lending based on information such as an inserted prepaid card) and a prize ball payout device 73. , and a launcher 72 is connected via a launch control circuit 175 . Launcher 72 includes a handle 72k (see FIG. 1).

The game control board 100 is also provided with a connector for connecting to an external terminal board 150 (see FIG. 11) and outputting various signals from the game machine in one direction. By connecting each connector of the external terminal board 150 with wiring (various signal lines), each information can be output to the data display 500 and hall computer 600 . Details of the external terminal board 150 will be described later.

As shown in FIG. 6, the payout control board 170 (first control board) is a payout control one-chip microcomputer (hereinafter referred to as "payout control microcomputer") capable of executing control processing related to the payout of game balls according to a program. 171 is implemented. The payout control microcomputer 171 (payout control means) includes a payout ROM 173 storing a program for controlling payout, a payout RAM 174 used as a work memory, and a payout ROM 173 for executing the program stored in the payout ROM 173. It includes a CPU 172 and a payout I/O port section (input/output circuit) 178 for inputting/outputting data and signals. Note that the payout ROM 173 may be attached externally.

The payout control board 170 drives the prize ball motor 73m of the prize ball payout device 73 based on the signal from the game control microcomputer 101 and the signal from the card unit CU connected to the pachinko game machine PY1 to release the prize balls. or pay out rental balls. For example, when a game ball enters (wins) the first start hole 11, a detection signal from the first start hole sensor 11a is input to the game control microcomputer 101. FIG. As a result, the game control microcomputer 101 outputs a prize ball signal indicating that the game ball has entered the first start port 11 to the payout control board 170, and sends a main prize ball signal to the external terminal plate 150. Output. In this case, the payout control microcomputer 171 that has received the prize ball signal drives the launch solenoid 72s through the launch control circuit 175 based on the number of prize balls information stored in the payout ROM 173, thereby performing the first start. Prize balls (for example, three) are paid out based on the ball entering the mouth 11. - 特許庁At this time, the game balls to be paid out are detected by the prize ball sensor 73 a for counting, and a detection signal by the prize ball sensor 73 a is output to the payout control board 170 . A prize ball signal is output from the payout control board 170 to the external terminal board 150 when the detection by the prize ball sensor 73a is accumulated for 10 balls. The main award signal output from the game control board 100 to the external terminal board 150 and the award signal output from the payout control board 170 to the external terminal board 150 will be described later.

A call switch YS is connected to the payout control board 170 of the present embodiment, and the call switch YS includes a call sensor YS1 capable of detecting the operation of the call switch by the player and the detection state of the call sensor YS1. A calling LED (YS2) is provided which lights up when the is on. The call switch YS and the call signal output from the payout control board 170 will be described later.

Next, as shown in FIG. 6, when the player operates the handle 72k (see FIG. 1) of the shooting device 72, the touch switch 72a detects contact with the handle 72k, and the shooting volume 72b changes to the handle. A rotation amount of 72k is detected. Then, the shooting solenoid 72s is driven so that the game ball is shot with an intensity corresponding to the magnitude of the detection signal of the shooting volume 72b. In this pachinko game machine PY1, one game ball is shot in about 0.6 seconds.

The game control board 100 also transmits various commands to the effect control board 120 . The connection between the game control board 100 and the effect control board 120 is a unidirectional communication connection that allows only transmission of signals from the game control board 100 to the effect control board 120 . That is, between the game control board 100 and the effect control board 120, a unidirectional circuit (for example, a circuit using a diode) is interposed as communication direction control means (not shown).

As shown in FIG. 7, the effect control board 120 is mounted with a one-chip microcomputer for effect control (hereinafter "effect control microcomputer") 121 for controlling the effect of the pachinko game machine PY1 according to a program. The performance control microcomputer 121 includes a performance ROM 123 storing a program for controlling performance as the game progresses, a performance RAM 124 used as a work memory, and a program stored in the performance ROM 123. A performance CPU 122 and a performance I/O port unit 138 for inputting and outputting data and signals are included. The effect RAM 124 is provided with a storage area capable of storing information related to various games, including a set value flag 126, which will be described later. Note that the performance ROM 123 may be externally attached. As described above, the effect control board 120 is supplied with power (for example, power such as DC 5V) from the power supply board 190 via the payout control board 170 .

Further, as shown in FIG. 7, the effect control board 120 is connected to the image control board 140 and also to the sub-drive board 162 (sub-drive circuit). The effect control microcomputer 121 of the effect control board 120 causes the image CPU 141 of the image control board 140 to perform display control of the image display device 50 based on the command received from the game control board 100 . The effect control microcomputer 121 transmits control signals via the image input circuit 145 of the image control board 140 . The image CPU 141 then transmits a control signal to the image display device 50 via the image output circuit 146 of the image control board 140 .

The image RAM 143 of the image control board 140 is a memory for developing image data. The image ROM 142 of the image control board 140 stores still image data and moving image data to be displayed on the image display device 50, specifically, characters, items, graphics, characters, numbers, symbols (including decorative patterns), and background data. Image data such as images are stored. The image CPU 141 of the image control board 140 reads out image data from the image ROM 142 based on a command from the effect control microcomputer 121 . Then, display control is executed based on the read image data.

A speaker 149 (sound output means) is connected to the image control board 140 . The effect control microcomputer 121 outputs sounds, music, sound effects, etc. from the speaker 149 via the sound CPU 147 of the image control board 140 based on the command received from the game control board 100 . The audio CPU 147 performs audio control of the speaker 149 via the audio control circuit 148 based on a command from the image CPU 141 . Acoustic data such as voice output from the speaker 149 is stored in the performance ROM 123 of the performance control board 120 . However, the sound data may be stored in the image ROM 142 of the image control board 140 .

Although the image control board 140 controls the sound of the speaker 149, an audio control board may be provided separately from the image control board 140, and the sound control of the speaker 149 may be controlled by this sound control board. In this case, the sound control board may be connected to the effect control board 120 or may be connected to the effect control board 120 via the image control board 140 . Also, a CPU may be mounted on the audio control board, and in that case, the CPU may be caused to execute the audio control. Furthermore, in this case, a ROM may be mounted on the audio control board, and acoustic data may be stored in the ROM.

Also, as shown in FIG. 7, the effect control microcomputer 121 controls lighting of lamps such as the frame lamp 212 and the board lamp 54 via the sub-drive board 162 based on the command received from the game control board 100. . Specifically, the production control microcomputer 121 creates light emission pattern data (data for deciding on/off, light emission color, etc., also called lamp data) that determines the light emission mode of each lamp, and controls the light emission of each lamp according to the light emission pattern data. Control. In addition, the data stored in ROM123 for production|presentation of the production|presentation control board 120 is used for preparation of light emission pattern data.

Furthermore, the production control microcomputer 121 performs drive control of the board movable body 55k via the sub-drive board 162 based on the command received from the game control board 100. FIG. Specifically, the effect control microcomputer 121 creates operation pattern data (also referred to as drive data) that determines the operation mode of the board movable body 55k, and according to the operation pattern data, drives and controls the motor for driving the board movable body 55k. I do. Data stored in the performance ROM 123 of the performance control board 120 is used to create the operation pattern data.

A CPU may be mounted on the sub-drive board 162, and in that case, the CPU may control the lighting of the lamps and the drive control of the board movable body 55k. Furthermore, in this case, a ROM may be mounted on the sub-drive board 162, and data relating to light emission patterns and operation patterns may be stored in the ROM.

Also, the effect control board 120 is connected with an input section detection sensor (effect button detection sensor) 40a and a select button detection sensor 42a. The input unit detection sensor 40a detects that the input unit 40k (see FIG. 1) is pressed. When the input section 40k is pressed down, a detection signal is output to the effect control board 120 from the input section detection sensor 40a. The select button detection sensor 42a detects that the select button 42k (see FIG. 1) has been pressed. When the select button 42k is pressed down, a detection signal is output to the effect control board 120 from the select button detection sensor 42a.

6 and 7 are functional block diagrams for explaining the electrical configuration of the pachinko game machine PY1, and the boards shown in FIGS. 6 and 7 are not the only ones provided. Except for the game control board 100, any plurality of boards shown in FIGS. 6 and 7 may be configured as one board, and one board shown in FIGS. 6 and 7 may be configured as a plurality of boards. good.

As shown in FIG. 8, the pachinko game machine PY1 has a power board 190 (power supply unit). The power board 190 supplies power to the game control board 100, the performance control board 120, and the payout control board 170, and supplies necessary power to other devices through these boards. A backup power supply circuit 191 is provided on the power supply board 190 . The backup power supply circuit 191 supplies power to the game RAM 104 of the game control board 100 and the effect RAM 124 of the effect control board 120, which will be described later, when power is not supplied to the pachinko game machine PY1. Therefore, the information stored in the game RAM 104 of the game control board 100 and the performance RAM 124 of the performance control board 120 is retained even when the pachinko game machine PY1 is powered off. A power switch 195 is connected to the power board 190 . ON/OFF operation of the power switch 195 switches on/off of the power supply. In addition, a backup power supply circuit for the game RAM 104 of the game control board 100 may be provided in the game control board 100 or a backup power supply circuit for the effect RAM 124 of the effect control board 120 may be provided in the effect control board 120 .

The power supply board 190 (power supply unit) inputs AC24V power from the outside of the pachinko game machine PY1, and supplies various voltages (DC5V, DC12V, DC18V, DC24V) necessary for the operation of the pachinko game machine PY1 based on the AC24V power supply. , DC 37V). Note that DC 5V power is mainly used as a power supply for various integrated circuits (ICs). DC 12V power is mainly used as a power source for various sensors and solenoids. In addition, DC18V power is mainly used as a power supply for various LEDs. The 24V DC power and the 37V DC power are mainly used as power sources for motors (driving means) for presentation.

The power supply board 190 also has a RAM clear switch (RAM clear operation means) 192 for causing the game CPU 102 to clear information stored in a game RAM (Random Access Memory) 104 of the game control microcomputer 101, which will be described later. is provided. The RAM clear switch 192 is provided on a power board 190 arranged on the back side of the pachinko game machine PY1. Therefore, the RAM clear switch 192 cannot be operated unless it is an employee of the game arcade who can open the game machine frame 2 . That is, the RAM clear switch 192 can be said to be an operating means that is substantially impossible for the player to operate. When the RAM clear switch 192 is pressed, a detection signal indicating that the RAM clear switch 192 is ON is input to the game control microcomputer 101 .

As shown in FIGS. 9A and 9B, the game control board 100 is provided with a game control microcomputer 101 (game control means), a 7-segment display 300, and a setting key cylinder 180. there is And, the setting key cylinder 180 (transition operation means) is provided on the game control board 100 as shown in FIGS. A "key" owned only by the clerk can be inserted. By rotating the inserted setting key, the setting key cylinder 180 moves between the standby position (initial position) shown in FIG. can be moved (rotated) with It should be noted that the setting key cylinder 180 is initially at the standby position and is constructed so that it cannot be moved to the rotating position unless a dedicated setting key is used.

As shown in FIG. 9(A), the setting key cylinder 180 includes a substantially cubic base portion 180b directly assembled to the game control board 100, and a columnar portion 180c extending backward from the base portion 180b. It has The base portion 180b and the cylindrical portion 180c are made of black synthetic resin, and the cylindrical portion 180c is formed with an insertion hole through which a setting key can be inserted.

Here, an exposed portion 100C is formed corresponding to the position of the setting key cylinder 180 on the rear surface portion 100B of the game control board case 100A. The exposed portion 100C is formed in a circular shape having approximately the same size as the rear surface 180d of the cylindrical portion 180c of the setting key cylinder 180. As shown in FIG. Therefore, when the game control board 100 is accommodated in the game control board case 100A, only the rear surface 180d of the cylindrical portion 180c of the setting key cylinder 180 is exposed from the exposed portion 100C.

Furthermore, the rear surface 180d of the cylindrical portion 180c of the setting key cylinder 180 forms substantially the same plane as the rear surface portion 100B of the game control board case 100A. In other words, the rear surface 180d does not protrude or recede with respect to the rear surface portion 100B of the game control board case 100A. Thus, by preventing the rear surface 180d of the cylindrical portion 180c from protruding from the rear surface portion 100B of the game control board case 100A, it is possible to prevent the corner portion of the rear surface 180d from being easily damaged. By making the rear surface 180d flush with the rear surface portion 100B of the game control board case 100A, the gap between the exposed portion 100C and the rear surface 180d is almost eliminated so that foreign matter does not enter the game control board case 100A. It is possible to As a result, it is possible to prevent fraudulent use of the setting key cylinder 180 and malfunction of the game control board 100 .

In addition, a peripheral wall portion 100D extending rearward is formed at a position corresponding to the setting key cylinder 180 in the rear surface portion 100B of the game control board case 100A. The peripheral wall portion 100D is a rectangular peripheral wall surrounding the rear end portions of the cylindrical portion 180c and the base portion 180b of the setting key cylinder 180. As shown in FIG. This peripheral wall portion 100D can prevent, for example, a wire or the like from entering the inside of the game control board case 100A and illegally contacting the periphery of the cylindrical portion 180c. In addition, it is possible to prevent a situation in which the state of a setting key cylinder switch 180a provided inside the setting key cylinder 180, which will be described later, is switched due to the influence of illegal magnetism.

The game control microcomputer 101 (game control means) provided on the game control board 100 in this embodiment and the setting key cylinder 180 are arranged on the surface of the same board. Further, the setting key cylinder 180 has a structure in which the setting key cylinder 180 can be switched between an ON state (operating state) and an OFF state (non-operating state) by inserting a setting key. A setting key cylinder switch 180a (operating position detecting means) is provided inside the setting key cylinder 180 so as to detect whether it is in the ON state (operating state) or the OFF state (non-operating state). there is Since the setting key cylinder switch 180a (operation position detection means) and the game control microcomputer 101 (game control means) are electrically connected, the game control microcomputer 101 can operate the setting key cylinder 180. It is configured so that the state can be grasped.

Here, as shown in FIGS. 9A and 9B, the game control board 100 is provided with a 7-segment display 300 (display means) capable of displaying set values. The display control of the 7-segment display 300 is executed by the game control microcomputer 101 . The reason why the 7-segment display 300 is provided on the game control board 100 instead of, for example, the performance control board 120 is based on the following reasons. That is, the game control board 100 (game control microcomputer 101) is an inspection object of a test for confirming proper operation, and if the display of the set values is controlled by the game control board 100, the display of the set values is changed. This is because reliability can be guaranteed.

As shown in FIG. 10, the 7-segment display 300 is a so-called 4-segment 7-segment display, and has a total of 32 lighting (emitting) portions. Specifically, the 7-segment display 300 has a first display area 310, a second display area 320, a third display area 330, and a fourth display area 340 in order from left to right. The four display areas 310, 320, 330, and 340 are composed of eight lighting portions (LED elements) LB1 to LB8, LB9 to LB16, LB1 to LB8, LB9 to LB16, so as to represent numbers "0" to "9", respectively. It has LB17 to LB24 and LB25 to LB32. Since the 4-segment 7-segment display is widely distributed in the market, the use of the 4-segment 7-segment display (the 7-segment display device 300) makes it possible to construct the display means at low cost.

In this embodiment, any set value from "1" to "6" is displayed in the fourth display area 340 of the 7-segment display 300. FIG. Also, when the setting value is displayed, the lighting portions LB25 to LB32 of the fourth display area 340 emit light in a lighting mode (light emission mode that continues to emit light) so as to represent the number of the setting value. Note that when the set value is displayed in the fourth display area 340, nothing is displayed in the first display area 310, the second display area 320, and the third display area 330. FIG.

3. Description of signals related to the external terminal board 150 Details of signals exchanged between the external terminal board 150, the game control board 100 and the payout control board 170 in this embodiment will be explained based on FIGS. 6, 8 and 11. do.

As shown in FIG. 8, an external terminal board 150 is arranged above the back of the pachinko game machine PY1. In this way, the external terminal board 150 is arranged in consideration of the convenience of handling wiring when connecting the wiring from the pachinko game machine PY1 to the data display 500 or the hall computer 600, which is equipment on the hall side. ing.

The external terminal board 150 relays the signal output from the game control microcomputer 101, and the data display device 500 and the hall computer 600, which are arranged outside the pachinko game machine PY1, are connected to the game machine. It is for outputting the signal output from. Specifically, the external terminal plate 150 is provided with a plurality of channels (CN) for external output. Each channel (CN) is provided with its own connector section (CN1 to CN11). Then, for this connector portion, while connecting various wiring (various signal lines) from the game control board 100 and payout control board 170 to the connector portion corresponding to each channel (CN), data display 500 and By connecting various wiring (various signal lines) on the side of the hall computer 600 to each channel (CN), information output from the game machine can be transmitted to externally connected devices. As for the signals output from the gaming machine side, one type of signal is output to the externally connected device.

As shown in FIG. 11, the external terminal board 150, the game control board 100 and the payout control board 170 in this embodiment connect various wirings (various signal lines) to connector portions (not shown) provided on each board. It is electrically connected by Now, the connector portion of the external terminal board 150 will be described. The external terminal board 150 is provided with a total of eleven connector portions CN1 to CN11. Various wirings (various signal lines) from the game control board 100 and the payout control board 170 and various wirings (various signal lines) from the payout control board 170 are connected to each connector portion. Further, each connector portion of the external terminal plate 150 can be connected to various wirings (various signal lines) for connecting the data display 500 or the hall computer 600 installed in the hall. Thereby, the game control board 100 and the payout control board 170 are connected to the data display 500 or the hall computer 600 via the external terminal board 150 .

The role of each connector part provided on the external terminal board 150 connected from the game control board 100 is nine kinds of signals (CN2: door opening signal, CN3: pattern confirmation signal, CN4: starting port signal, CN5: jackpot signal , CN6: time-saving signal, CN7: high probability signal, CN8: main prize ball signal, CN9: security signal, CN10: setting change signal) are assigned. Two kinds of signals (CN1: winning ball signal, CN11: calling signal) are assigned to the respective connectors provided on the external terminal board 150 from the payout control board 170 as well. The output state and output timing of signals in these various wirings will be described later.

A data display device 500 installed in the hall can display data according to the type of information output from the gaming machine, notify an error occurring in the gaming machine, notify a call from a player, and the like. Similarly, on the side of the hall computer 600 installed in the hall, data management and security can be handled by combining various information output from the gaming machine. The type of these signals and the wiring connection method (how to connect the wiring and the connector, or when the wiring is not connected) will depend on the specifications of the game machine or the type of information that the pachinko hall wants to grasp. It can be changed as appropriate, and this embodiment is merely an example for explanation.

4. Explanation of Big Wins, etc. In the pachinko game machine PY1 of this embodiment, there are "big wins" and "losses" as a result of the big win lottery (special symbol lottery). At the time of the "big win", the special figure display 81 stops displaying the "big win pattern". At the time of "missing", the special symbol display 81 stops displaying the "losing symbol". When a big win is won, a "jackpot game" for opening the big prize opening 14 is executed in an opening pattern corresponding to the type of the stopped special symbol (type of the big win). A jackpot game is also called a special game.

In this form, the jackpot game includes multiple round games (unit games), the opening (also referred to as OP) before the first round game starts, and the ending after the final round game ends ( ED). Each round game starts with the end of the OP or the end of the previous round game and ends with the start of the next round game or the start of the ED. The closing time (interval time) of the big winning hole between round games is included in the open round game before closing.

There are multiple types of jackpots. The types of jackpots are as shown in FIG. As shown in FIG. 12, there are roughly two types in this embodiment. There is a variable jackpot and a normal jackpot. The variable probability jackpot is a jackpot that controls the game state after the jackpot game to a high probability state, which will be described later. The normal jackpot is a jackpot in which the game state after the jackpot game is controlled to a normal probability state (low probability state) described later.

More specifically, the probability variable jackpot and normal jackpot that can be won in the special drawing 1 lottery (first special pattern lottery) are 1R to 8R, the large winning mouth 14 is opened for a maximum of 29.5 seconds per 1R (predetermined period), and from 9R to 16R, the big winning opening 14 is opened for a maximum of 0.1 seconds per 1R (predetermined period). In other words, although the total number of rounds for these jackpots is 16R, the actual number of rounds is 8R. The substantial number of rounds is the number of rounds in which game balls can win up to the maximum number of winning prizes per round (eight in this embodiment). In these jackpots, from 9R to 16R, the opening time of the big prize hole 14 is extremely short, and the rounds are such that prize balls cannot be expected. It should be noted that, when the "probability variable jackpot" is won by the lottery of the special figure 1, the "special figure 1_probability variation pattern" is stopped and displayed on the first special figure display device 81a, and when the "normal jackpot" is won, "Special figure 1_normal symbol" is stop-displayed on the first special figure indicator 81a.

In addition, the probability variable jackpot and normal jackpot that can be won in the lottery of special figure 2 (lottery of the second special pattern) open the big prize opening 14 for a maximum of 29.5 seconds (predetermined period) per 1R from 1R to 16R. It's a big hit. In other words, these jackpots have a substantial number of rounds of 16R. When the "probability variable jackpot" is won by the lottery of the special figure 2, the "special figure 2_probability variation pattern" is stopped and displayed on the second special figure display device 81b, and when the "normal jackpot" is won, the second "Special figure 2_normal symbol" is stopped and displayed on the special figure indicator 81b.

Even if any jackpot is won, after the jackpot game, it is controlled to an electric support control state (high base state), which will be described later. The electric support control state continues until the next jackpot winning when controlled in accordance with the high probability state. On the other hand, when it is controlled in accordance with the normal probability state (low probability state), the number of times of electric support (time saving number of times) is set to 100 times. The number of times of electric support means the upper limit execution number of times of variable display of special symbols in the electric support control state.

In addition, as shown in FIG. 12, the distribution rate of the jackpot in the lottery of the special figure 1 and the lottery of the special figure 2 is 65% for the probability variable jackpot and 35% for the normal jackpot. However, if a jackpot is won based on the lottery of special figure 1, a jackpot game with a substantial number of rounds of 8 rounds will be executed, and if a jackpot is won based on the lottery of special figure 2 The lottery of the special figure 2 is set to be more advantageous for the player than the lottery of the special figure 1 in that the jackpot game with the typical number of rounds of 16 rounds is executed.

Here, in the pachinko game machine PY1, the lottery for whether or not a big win is made is performed based on the ``random number for the jackpot'', and the lottery for the type of the winning jackpot is performed based on the ``random number for the winning type''. As shown in FIG. 13A, the jackpot random number takes a value in the range of 0-65535. The winning type random number takes a value in the range of 0-99. In addition to the jackpot random number and the winning type random number, the random numbers obtained based on the winning of the first start port 11 or the second start port 12 include "reach random numbers" and "fluctuation pattern random numbers".

The ready-to-win random number is a random number that determines whether or not to generate a ready-to-win in the effect symbol variation effect indicating the result when the result of the big hit determination is a loss. The ready-to-win state is a state in which only one performance symbol EZ that is variably displayed among a plurality of performance symbols EZ remains, and it depends on which symbol the variably displayed performance symbol EZ is stopped and displayed. It is a state (for example, the state of "7↓7") which is a combination of the performance symbols EZ indicating the jackpot winning. The effect symbol EZ that is stopped and displayed in the ready-to-win state may be displayed as if it is slightly swaying within the display screen 50a, or may be displayed so as to repeat enlargement and reduction. This reach random number takes a value in the range of 0-255.

Also, the fluctuation pattern random number is a random number for determining a fluctuation pattern including fluctuation time. The fluctuation pattern random number takes a value in the range of 0-99. Random numbers acquired based on passing through the gate 13 include normal symbol random numbers (hit random numbers) shown in FIG. 13(B). The normal symbol random number is a random number for a lottery (normal symbol lottery) for determining whether or not to perform an auxiliary game for opening the electric chew 12D. The normal symbol random number takes a value in the range from 0 to 65535.

Here, in the pachinko gaming machine PY1 of the present embodiment, it is possible to determine whether or not the jackpot has been hit (whether or not a jackpot game is to be executed) using the jackpot determination table. As shown in FIGS. 14(A) to 14(F), the big hit determination table is provided corresponding to each set value. In this embodiment, six types of set values are provided: "1", "2", "3", "4", "5", and "6".

The set value is a parameter that determines the probability of being judged as a big hit in the big-hit judgment process (referred to as "big-hit judgment probability" as appropriate). The set value is set by an employee of the game arcade or the like, as will be described later. As shown in FIGS. 14(A) to 14(F), each of the jackpot determination tables corresponding to each set value includes a jackpot determination table used in a normal probability state and a jackpot determination table used in a high probability state. There is a table. The types of setting values and the types of big hit determination tables are not limited to six types, and can be changed as appropriate.

As shown in FIGS. 14(A) to 14(F), each of the big win determination tables corresponding to each setting value is assigned with a big win random number determined as a big win or a loss. This pachinko game machine PY1 determines whether it is a big win or a loss using a big win determination table corresponding to the set value. In addition, in this form, it is set so as not to win a small hit, but it may be set so that a small win may be won. Also, the probability of being determined as a big win and the method of distributing the random numbers determined as a big win are not limited to those shown in FIGS.

5. Explanation of Game State Next, the game state of the pachinko game machine PY1 of this embodiment will be explained. The special figure indicator 81 and the normal figure indicator 82 of the pachinko game machine PY1 respectively have a probability variation function and a variation time shortening function. The state in which the probability variation function of the special figure indicator 81 is operating is called "high probability state", and the state in which it is not operating is called "normal probability state (non-high probability state)". In the high probability state, the jackpot probability is higher than in the normal probability state.

In this embodiment, as shown in FIGS. 14(A) to 14(F), for each set value, the jackpot determination table used in the high probability state is more than the jackpot determination table used in the normal probability state. It is set so that it can be easily determined as a big hit. Furthermore, in the game state of the normal probability state or the high probability state, if the game state is the same, the higher the set value is set, the more likely it is to be determined as a big win.

Moreover, the state in which the variable time reduction function of the special figure indicator 81 is operating is called "time saving state", and the state in which it is not operating is called "non-working time saving state". In the time saving state, the fluctuation time of the special symbol (the time from the start of the fluctuation display to the time of derivation display of the display result) is shorter than in the non-working time saving state. Also, as shown in FIG. 15(A), the rate at which the reach (effect set to a specific fluctuation time or more) effect is selected is more likely to be selected in the non-time-saving state than in the time-saving state. Also, as shown in FIG. 16, even when any of the production of the loss without reach and the loss with reach is selected, the production pattern with shorter fluctuation time is more likely to be selected overall in the time saving state than in the non-time saving state. The fluctuation pattern is determined using the fluctuation pattern table defined as follows. That is, when the variable time shortening function of the special figure display 81 operates, it becomes easy to select a short variable time as the variable display of the special symbol compared to when it is not operating. As a result, in the time-saving state, the pace of digestion of the special figure reservation becomes faster, and the effective winning to the starting opening (the winning that can be stored as the special figure reservation) is likely to occur. Therefore, it is possible to aim for a big hit under the smooth progress of the game.

The probability variation function and the variation time reduction function of the special figure indicator 81 may operate simultaneously, or only one of them may operate. Then, the probability variation function and the variation time shortening function of the normal figure indicator 82 are designed to operate in synchronization with the variation time shortening function of the special figure indicator 81 . That is, the probability fluctuation function and the fluctuation time reduction function of the normal figure display 82 operate|moves in a time saving state, and do not operate|move in a non-time saving state. Therefore, in the time-saving state, the winning probability in the normal symbol lottery is higher than in the non-time-saving state. That is, the value of the normal design random number (hit random number) determined to be a hit is determined using a normal design hit determination table that is larger than the normal design hit determination table used in the non-time saving state, and the hit determination (normal design determination) is performed ( See FIG. 15(B)). In other words, when the probability variation function of the normal pattern indicator 82 is activated, the probability that the display result of the variable display of the normal symbol by the normal symbol indicator 82 becomes a normal winning symbol is higher than when it is not activated. .

In addition, in the time saving state, the fluctuation time of the normal pattern is shorter than in the non-working time saving state. In the present embodiment, the variation time of normal symbols is 7 seconds in the non-time saving state, but is 1 second in the time saving state (see FIG. 15(C)). Furthermore, in the time saving state, the opening time of the electric chew 12D in the auxiliary game is longer than the non-time saving state (see FIG. 17). That is, the opening time extension function of the electric chew 12D is operating. In addition, in the time-saving state, the number of times the electric chew 12D is opened in the auxiliary game is greater than in the non-time-saving state (see FIG. 17). That is, the function of increasing the number of openings of the electric chew 12D is activated.

When the probability variation function and variation time reduction function of the normal map display 82 and the opening time extension function and opening frequency increase function of the electric chew 12D are operating, compared to when these functions are not operating As a result, the electric chew 12D is frequently opened, and game balls enter the second starting port 12 frequently. As a result, the base, which is the ratio of the number of balls awarded to the number of balls fired, increases. Accordingly, the state in which these functions are activated is referred to as the "high base state" and the state in which they are not activated is referred to as the "low base state." In the high base state, you can aim for a big hit without greatly reducing the number of game balls you have. Note that the high base state is a state in which so-called electric support control (control for supporting winning to the second starting port 12 by the electric chew 12D) is being performed. Therefore, the high base state is also called an electric sapo control state or an easy ball entry state. On the other hand, the low base state is also referred to as a non-electric support control state or a non-entering easy state.

A high base state may not be one in which all of the above functions are active. That is, operation of one or more of the probability variation function of the normal map display 82, the variation time shortening function of the normal map display 82, the opening time extension function of the electric chew 12D, and the opening frequency increasing function of the electric chew 12D. Therefore, it is sufficient that the electric tube 12D can be opened more easily than when the function is not activated. Also, the high base state may be controlled independently without accompanying the time saving state.

In addition, a time saving signal is output from the game control board 100 through the wiring connected to CN6 of the external terminal board 150 in conjunction with these game states. Similarly, through the wiring connected to CN7 of the external terminal plate 150 from the game control board 100, a high probability signal is output. This time-saving signal is output during the time-saving state in which the variable time reduction function of the special symbol (special figure display device 81) is in the operating state, and the variation time reduction of the special symbol (special figure display device 81). As soon as the function ends and the non-time-saving state is entered, the output of the time-saving signal is immediately stopped. Similarly, the high probability signal is output during the high probability state that the probability variation function of the special symbol (special symbol display device 81) is in the operating state, and the high probability state ends and the normal probability state ( (non-high-probability state), the output of the high-probability signal is immediately stopped. The data display 500 and the hall computer 600 can know the state of the game machine from the output state of the signal from the external terminal board 150, and can make a notification according to the state of the game machine. These various signals will be described later.

In the pachinko game machine PY1 of this embodiment, the game state after the jackpot game by winning the probability variable jackpot is a high probability state, a time saving state and a high base state. This game state is particularly referred to as a "high accuracy high base state". The high-probability-high base state ends when the variable display of the special symbols is executed a predetermined number of times (10000 times in this embodiment), or when a big win is won and the big win game is executed. That is, in this form, the high-probability-high base state substantially continues until the next jackpot election. It should be noted that the end condition of the high-probability-high base state may be only that the jackpot is won and the jackpot game is executed.

In addition, the game state after the jackpot game by winning the normal jackpot is a normal probability state (non-high probability state, ie, low probability state), time saving state and high base state. This game state is particularly referred to as "low certainty high base state". The low-probability-high base state ends when the variable display of the special symbols is executed a predetermined number of times (100 times in this embodiment), or when a big win is won and the big win game is executed.

When the pachinko game machine PY1 is played for the first time, the game state after the power is turned on is the normal probability state, the non-time saving state, and the low base state. This game state is particularly referred to as a "low probability low base state". The low probability low base state is referred to as "normal game state". Also, the state during execution of the special game (jackpot game) is referred to as "special game state (jackpot game state)". Further, a state in which at least one of the high probability state and the high base state is controlled will be referred to as a "privilege game state".

In a high base state such as a high probability high base state or a low probability high base state, it is possible to advance the game more advantageously by entering the game ball into the right game area 6R (see FIG. 4) by hitting to the right. This is because it is easier to open the electric chew 12D than in the low base state due to the electric sapo control, and it is easier to win the second start opening 12 than to win the first start opening 11. . Therefore, the game ball is passed to the gate 13 which triggers the normal symbol lottery, and the game ball is hit to the right to win the game ball to the second starting port 12.例文帳に追加As a result, it is possible to obtain a larger number of starting prizes (winning at the starting opening) than when hitting left. In addition, in this pachinko game machine PY1, the game is played by hitting to the right even during the jackpot game.

On the other hand, in the low base state, the game can be played more advantageously by entering the game ball into the left game area 6L (see FIG. 4) by hitting to the left. Since the electric sapo control is not executed, it is difficult to open the electric chew 12D compared to the high base state, and it is easier to win the first starting port 11 than winning the second starting port 12. It is because Therefore, left-handed hitting is performed in order to make the game ball enter the first starting port 11.例文帳に追加This allows you to get more starting prizes than hitting right.

6. Method of Changing and Determining Set Values A method of changing set values will be described with reference to FIG. In this embodiment, in order to change the setting value, it is necessary to shift to the setting change mode as shown in FIG. Three conditions are required to shift to the setting change mode. The first condition is that the RAM clear switch 192 is operated (turned on). The second condition is that the setting key cylinder 180 is in the rotating position. The third condition is that the power switch 195 is switched from the OFF operation to the ON operation, thereby switching from the cut-off state to the on state. By performing these three operations at the same time when the power is turned on, it is possible to shift to the setting change mode.

The display mode of the 7-segment display 300 and the presentation mode of the rendering means (the image display device 50, the speaker 149, the frame lamp 212 and the board lamp 54) when changing the set value will be described. (See FIG. 18) In this embodiment, in order to change the setting value as described above, it is necessary to satisfy three conditions (based on the establishment of a predetermined transition condition) and shift to the setting change mode. Specifically, the setting key cylinder 180 is rotated 90 degrees from the standby position using the setting key, and the power switch 195 is turned on while the RAM clear switch 192 is depressed. switch. An operation that satisfies these three conditions is hereinafter referred to as a "setting change mode transition operation". The setting change mode transition operation is generally performed by a game arcade employee, and cannot be performed by a player who cannot see the back side of the pachinko game machine PY1 (see FIG. 8).

As shown in FIG. 18(A), when the setting change mode transition operation is performed to shift to the setting change mode, as shown in FIG. 18(B), the fourth display area 340 of the 7 segment display 300 shows: The set value (for example, "1") that was set before the power was turned on is displayed. That is, the setting value information set during the previous game (hereinafter referred to as "setting value information") is not erased even if the cut-off state is established. Therefore, when the setting change mode transition operation is performed when the power is turned on, the setting values set during the previous game are displayed on the 7-segment display 300 based on the stored setting value information.

Further, when the mode is shifted to the setting change mode, as shown in FIG. 18B, the display screen 50a of the image display device 50 displays a setting changing image SH showing characters "setting changing". By starting the display of the setting changing image SH, it is possible for the employee of the game parlor who changes the setting values (hereinafter referred to as the "setting changer") to understand that the setting change mode has been correctly entered. is. In addition, the setting changing image SH continues to be displayed on the display screen 50a until the setting change mode ends. Therefore, the setting changer can grasp the situation in which the setting value can be changed by looking at the setting changing image SH.

Also, when the setting change mode is entered, a voice saying "The setting can be changed" is output from the speaker 149, as shown in FIG. 18(B). By starting the voice saying "The setting can be changed", it is possible for the setting changer to audibly understand that the setting change mode has been correctly entered. Also, the voice saying "The setting can be changed" is repeatedly output until the setting change mode ends, except for the timing when the setting value is changed. Therefore, as long as the person who changes the settings continues to hear the voice saying "Settings can be changed", it is possible to grasp the situation in which the setting values can be changed.

When the setting change mode is entered, the frame lamp 212 and the board lamp 54 emit light in a special first light emission mode, as shown in FIG. 18(B). By starting light emission in the first light emission mode, it is possible for the setting changer to understand that the setting change mode has been properly changed. Further, the frame lamp 212 and the board lamp 54 continue to emit light in the first light emission mode until the setting change mode ends, except for the timing at which the set value is changed. Therefore, as long as the person who changes the setting continues to see the light emission in the first light emission mode, it is possible to grasp the situation in which the setting value can be changed.

Here, in this embodiment, when the RAM clear switch 192 is pressed in the setting change mode, the setting value can be changed. Specifically, each time the RAM clear switch 192 is pressed, the set value is increased by one in the order of "1" ⇒ "2" ⇒ "3" ⇒ "4" ⇒ "5" ⇒ "6". It is possible to When the RAM clear switch 192 is pressed when the set value is "6", the set value is returned to "1".

In this way, the existing RAM clear switch 192 is used as an operating means for switching the set values, and a new dedicated operating means is not provided. Conventionally, the RAM clear switch 192 was used only for erasing the information stored in the game RAM 104 and the payout RAM 174 when the power was turned on, and was not used except when the power was turned on. Therefore, as in the present embodiment, the RAM clear switch 192 is used both as an operation means for switching set values and as an operation means for erasing information stored in the game RAM 104, thereby reducing the number of parts. is possible. In the setting change mode, even if the RAM clear switch 192 is pressed, the information stored in the game RAM 104 or the like is not erased at the timing of the pressing operation.

As shown in FIG. 18(B), after the set value "1" is displayed on the 7-segment display 300 when the setting change mode is entered, for example, if the RAM clear switch 192 is pressed, , the fourth display area 340 of the 7-segment display 300 displays the set value "2". That is, the display of the set value "1" is switched to the display of the set value "2". This allows the setting changer to know that the setting value has been changed to "2".

Further, when the RAM clear switch 192 is pressed down, as shown in FIG. 18C, a set value change indicating an upward arrow is superimposed on the display screen 50a of the image display device 50 and the image SH during setting change is displayed. Image YG is displayed. By displaying the setting value change image YG, it is possible for the setting changer to understand that the setting value has been changed (increased). The setting value change image YG is displayed for several seconds after the RAM clear switch 192 is pressed, and then disappears, and only the setting change image SH is displayed again on the display screen 50a.

Further, when the RAM clear switch 192 is pressed, a voice saying "The set value has been changed" is output from the speaker 149, as shown in FIG. 18(C). The voice saying "The setting value has been changed" makes it possible for the setting changer to understand that the setting value has been changed. Note that the voice "The setting value has been changed" is output only once, and after that, the voice "The setting can be changed" is repeated as described above.

Further, when the RAM clear switch 192 is pressed, the frame lamp 212 and the board lamp 54 emit light in a special second light emission mode, as shown in FIG. 18(C). Light emission in the second light emission mode enables the setting changer to recognize that the setting value has been changed. The light emission in the second light emission mode is executed for several seconds after the RAM clear switch 192 is pressed down, and then the light emission in the first light emission mode is resumed as described above.

Subsequently, when the RAM clear switch 192 is pressed while the set value "2" is displayed on the 7-segment display 300 as shown in FIG. A set value “3” is displayed in the fourth display area 340 of the segment display 300 . That is, the display of the set value "2" is switched to the display of the set value "3". This allows the setting changer to know that the setting value has been changed to "3".

Further, as shown in FIG. 18(D), a setting value change image YG is displayed on the display screen 50a of the image display device 50, a voice saying "The setting value has been changed" is output from the speaker 149, and a frame lamp is displayed. 212 and the board lamp 54 emit light in a special second lighting manner. By these means, it is possible for the setting changer to recognize that the setting value has been changed again.

By the way, when the RAM clear switch 192 is pressed in the setting change mode, the setting changer basically faces the back side of the pachinko game machine PY1 (see FIG. 8) and looks at the 7-segment display 300. FIG. Therefore, it is difficult for a setting changer to grasp the display of the setting value change image YG on the display screen 50a and the light emission in the special second light emission mode from the frame lamp 212 and the board lamp . Therefore, the display of the set value change image YG and the light emission in the special second light emission mode are mainly aimed at the employees of the game arcade around the pachinko game machine PY1 to inform them that the set values have been changed. It is meant to inform. In this way, employees of surrounding game arcades can know that the setting values have been changed, so that they can know that the setting values have not been illegally changed.

Next, a method for determining the set value will be described with reference to FIG. 18(E). In order to confirm the set value, it is necessary to rotate the setting key cylinder 180 from the rotation position toward the standby position using the setting key in the setting change mode. As a result, the setting change mode is terminated, and the last setting value displayed in the setting change mode is confirmed. The operation of rotating the setting key cylinder 180 from the rotating position toward the standby position will be referred to as a "setting confirming operation".

When the setting confirmation operation is performed, as shown in FIG. 18(F), the display screen 50a of the image display device 50 displays a setting value confirmation image SK showing characters "The setting value is confirmed." . By displaying the setting value confirmation image SK, it is possible to let the setting changer or an employee of the surrounding game arcade recognize that the setting value is confirmed. Note that the setting value confirmation image SK is hidden after being displayed for a very short time after the setting confirmation operation is performed.

Further, when the setting confirmation operation is performed, a voice saying "the setting value is confirmed" is output from the speaker 149, as shown in FIG. 18(F). The voice saying "The set value has been finalized" makes it possible for the setting changer or an employee of the surrounding game arcade to know that the set value has been finalized. Note that the voice saying "The setting value has been confirmed" is output only once at the timing when the setting confirmation operation is performed.

Further, when the setting confirmation operation is performed, the frame lamp 212 and the board lamp 54 emit light in a special third light emission mode, as shown in FIG. 18(F). By emitting light in the third light emitting mode, it is possible to let the setting changer or an employee of the surrounding game arcade recognize that the set value has been fixed. It should be noted that the light emission in the third light emission mode ends after being executed for a very short time after the setting confirming operation is performed.

Here, in this embodiment, when the setting confirmation operation is performed and the setting change mode ends, the setting value (for example, " 3”) disappears. That is, the set value is hidden (non-display mode). Then, the 7-segment display 300 instead performs an initial display (see FIG. 18F), which will be described later. In this way, the setting value displayed in the lighting mode is changed to the non-display mode, so that the person who changes the setting can understand that the setting value has been finalized. Furthermore, by not displaying the setting value after it is determined, it is possible to make it difficult for the surroundings to notice the determined setting value.

When the setting values are determined in this way, as shown in FIG. (see FIG. 10) lights up. By lighting all the lighting portions LB1 to LB32 in this way, it is possible to clearly indicate to the setting changer who has performed the setting confirming operation that the initial display is executed.

The meaning of the initial display on the 7-segment display 300 is as follows. The 7-segment display 300 displays the set value as described above, and also displays the base as described later. However, the set value or base displayed on the 7-segment display 300 is based on the premise that the 7-segment display 300 is functioning normally, and if the 7-segment display 300 itself fails or malfunctions, , or the possibility of unauthorized modification is not completely eliminated.

Therefore, in this embodiment, when the setting change mode ends, the initial display is automatically performed on the 7-segment display 300 . This allows the setting changer to know that the 7-segment display 300 is functioning normally. In other words, it is possible to confirm that the set values displayed in the setting change mode are correct. Additionally, it is possible to recognize that bases displayed after the initial display will also be displayed correctly. If the setting change mode is not entered when the power is turned on, the initial display is performed on the 7-segment display 300 immediately after the power is turned on.

In this embodiment, the gaming machine shifts to a playable state on condition that the "setting confirmation operation" is completed as shown in FIG. 18(G). In other words, the normal power-on processing without operation of the setting key cylinder 180 and the RAM clear switch 192 is performed, and the game is ready for play.

7. Method of confirming setting value A method of confirming the setting value will be described with reference to FIG. 19 . In this embodiment, it is necessary to shift to the setting confirmation mode as shown in FIG. 19 in order to confirm the setting values. In order to shift to the setting confirmation mode, unlike the setting change mode described above, two conditions are required. The first condition is that the setting key cylinder 180 is in the rotational position (on state). The second condition is that the power switch 195 is turned on to switch from the cut-off state to the on state. That is, the setting change mode is entered by turning on the power switch 195 while the setting key cylinder 180 is in the rotating position (on state) without operating the RAM clear switch 192 . Since there are many similarities between the setting change mode and the setting confirmation mode described above, differences will be mainly described below.

As shown in FIG. 19(A), when the setting confirmation mode shift operation is performed to shift to the setting confirmation mode, as shown in FIG. The set value (for example, "6") that was set before the power was turned on is displayed. That is, the setting value information set during the previous game (hereinafter referred to as "setting value information") is not erased even if the cut-off state is established. Therefore, when the setting confirmation mode shift operation is performed at power-on, the setting values set during the previous game are displayed on the 7-segment display 300 based on the stored setting value information.

When the mode is shifted to the setting confirmation mode, as shown in FIG. 19(B), an image GSH indicating the current setting indicating the characters "Current setting is 6" is displayed on the display screen 50a of the image display device 50. be. Thus, by looking at the image GSH regarding the current settings, it is possible to grasp the current settings without looking at the 7-segment display 300 arranged on the back side of the gaming machine.

Further, when the mode is shifted to the setting confirmation mode, as shown in FIG. 19B, the frame lamp 212 and the board lamp 54 emit light in a special first light emission mode. By starting light emission in the first light emission mode, it is possible for the person who confirms the setting to know that the setting confirmation mode has been correctly entered. Further, the frame lamp 212 and the board lamp 54 continue to emit light in the first light emission mode until the setting confirmation mode ends. In this way, the person who changes the settings can recognize that the mode is the setting confirmation mode as long as he/she continues to see the light emission in the first light emission mode. In this embodiment, light emission is performed in the first light emission mode as in the setting change mode, but light emission may be performed in a light emission mode dedicated to the setting confirmation mode.

Next, a method for ending the setting confirmation mode will be described with reference to FIG. 19(C). To terminate the setting confirmation mode, it is necessary to use the setting key to rotate the setting key cylinder 180 from the rotating position toward the standby position. This ends the setting confirmation mode.

When the operation for ending the setting confirmation mode is performed, as shown in FIG. 19(D), the display screen 50a of the image display device 50 displays the current setting value confirmation indicating the characters "The setting confirmation mode is terminated." Image GSK is displayed. Note that this current setting value confirmation image GSK is hidden after being displayed for a very short time after the setting confirmation end operation is performed.

Also, when the operation to end the setting confirmation mode is performed, as shown in FIG. 19(D), a voice saying "Confirmation mode is terminated" is output from the speaker 149, and the game transitions to the playable state.

8. Setting value non-setting error Next, a setting value non-setting error when information indicating a setting value (hereinafter referred to as “setting value information”) is not stored in the pachinko game machine PY1 will be described. The set value information is stored in the set value information storage unit 107 (see FIG. 6) of the game RAM 104 each time the set value is changed in the setting change mode. However, when the pachinko game machine PY1 is shipped from the production factory (factory shipment), the setting value information storage unit 107 does not store the setting value information. In other words, no set value is set.

This pachinko game machine PY1 is designed to be able to shift to an error mode when the power is turned on in a state in which no setting value is set. Even if no setting value is set, if the setting change mode transition operation is performed, the setting change mode is entered instead of the error mode. The error mode is a mode in which a game cannot be played in the pachinko game machine PY1, and is not canceled unless the power switch 195 is turned off to cut off the power.

In the error mode, as shown in FIG. 20A, in the fourth display area 340 of the 7-segment display 300, the lighting portions LB25, LB28, LB29, LB30, and LB31 (see FIG. 10) are changed to "E ” in an error lighting manner. By this light emission, it is possible for employees of the game arcade or the like to recognize that the error mode has been entered, that is, that the set value has not been set. The light emission in the error lighting mode continues until the error mode is canceled.

When the mode is the error mode, as shown in FIG. 20B, an operation suggesting image SE showing characters "The setting value is not set. Please perform an operation to shift to the setting change mode" is displayed on the display screen 50a. Is displayed. By displaying this operation suggestion image SE, it is possible for an employee of the game parlor or the like to grasp the situation in which the set value must be set. The display of the operation suggestion image SE continues until the error mode is released.

In the error mode, a special error sound is output from the speaker 149 as shown in FIG. 20(B). Also, at this time, as shown in FIG. 20B, the frame lamp 212 and the board lamp 54 emit light in a special error light emission mode. By outputting the error sound and emitting light in the error light emitting mode, it is possible for employees of the game arcade to recognize that the game is in the error mode. The output of the error sound and the light emission in the error light emission mode continue until the error mode is cancelled.

In addition, in this embodiment, when this non-setting error is detected, a security signal is output from the game control board 100 through the wiring connected to the CN9 of the external terminal board 150 . With this signal, the data display 500 and the hall computer 600 can recognize that the setting of the game machine is not set or that there is an abnormality in the setting information, and call attention to the setting of the game machine. It can be carried out.

Here, in this embodiment, the set value information stored in the set value information storage unit 107 of the game RAM 104 is not erased even when the RAM clear switch 192 is pressed. Therefore, once the setting value information is stored in the setting value information storage unit 107 by performing the setting change mode transition operation after the shipment from the factory, the setting value information is not stored in the setting value information storage unit 107 after that. does not occur. Therefore, in this case, when the power is turned on after the next time, the error mode will not be entered. In short, the transition to the error mode occurs when the setting value has never been set and the setting change mode transition operation is not performed when the power is turned on, or when some problem (noise, etc.) occurs and the retained information is lost. is deleted. In this way, even when the RAM clear switch 192 is simply pressed down or when the power is not turned on (shutoff state), by not erasing the set value information, unnecessary transition to the error mode can be avoided. It is possible to prevent it.

9. Control Operation of Pachinko Game Machine Next, the operation of the game control microcomputer 101 will be described with reference to FIGS. 21 to 28, and the operation of the effect control microcomputer 121 will be described with reference to FIGS. First, the operation of the game control microcomputer 101 will be described.

[Main Control Main Processing] The game control microcomputer 101 provided on the game control board 100 reads out and executes the main control main processing program shown in FIG. 21 from the game ROM 103 when the power is turned on. Note that counters, timers, flags, statuses, buffers, etc. appearing in the explanation of the operation of the game control microcomputer 101 are provided in the game RAM 104 . The initial value of the counter is "0", the initial value of the flag is "0" or "OFF", and the initial value of the status is "1".

As shown in FIG. 21, in the main control main process, first, a power-on process (S001), which will be described later, is performed. After power-on processing (S001), interrupts are prohibited (S002), and normal design/special design main random number update processing is executed (S003). In this normal symbol/special symbol main random number update process (S003), various random number counter values shown in FIG. 13 are updated by adding one. When each random number counter value reaches the upper limit, it returns to "0" and is added again. The initial value of each random number counter may be a value other than "0", or may be changed randomly. Also, each random number may be a so-called hardware random number generated using a known random number generation circuit such as a counter IC.

When the normal design/special design main random number update process (S003) ends, the interrupt is permitted (S004). While interrupts are enabled, it is possible to execute main-side timer interrupt processing (S005). The main-side timer interrupt processing (S005) is executed based on an interrupt pulse that is repeatedly input to the game CPU 102 at a cycle of, for example, 4 msec. That is, it is executed, for example, at a 4 msec cycle. And, after the main side timer interrupt processing (S005) is completed, before the next main side timer interrupt processing (S005) is started, various counters by normal design / special design main random number update processing (S003) Value update processing is repeatedly executed. If an interrupt pulse is input to the game CPU 102 in the interrupt disabled state, the main timer interrupt processing (S005) is not started immediately, but is started after the interrupt is permitted (S004).

[Power ON Processing] As shown in FIG. 22, in the power ON processing (S001), the game control microcomputer 101 first sets access permission to the game RAM 104 (S010). As a result, information can be written to or read from the game RAM 104 . Subsequently, it is determined whether or not the RAM clear switch 192 is ON (depressed) and the setting key cylinder switch 180a is ON (S011). That is, it is determined whether or not the setting change mode transition operation is being executed. If the setting change mode transition operation has been executed (YES in S011), the process proceeds to step S013 via setting change mode processing (S012) described later.

On the other hand, if it is determined in step S011 that the setting change mode transition operation has not been executed (NO in S011), then it is determined whether setting value information is stored in the setting value information storage unit 107 (S016). ). If the set value information is not stored (NO in S016), it means that the set value has not been set even once, and the process proceeds to error mode processing (S021) described later. On the other hand, if the set value information is stored (YES in S016), then it is determined whether or not the RAM clear switch 192 is ON (S017). In short, the process of step S017 is a process of determining whether or not the RAM clear switch 192 has been pressed, although the setting change mode is not entered. If the RAM clear switch 192 is ON (YES in S017), the process proceeds to step S013.

On the other hand, if the RAM clear switch 192 is not ON (NO in S017), then it is determined whether or not the setting key cylinder switch 180a is ON (S018). In short, the process of step S018 is a process of determining whether or not the setting key cylinder 180 is in a rotating state, although the setting change mode is not entered. If the setting key cylinder switch 180a is ON (YES in S018), a set value confirmation mode process, which will be described later, is executed (S019), and the process proceeds to step S020. On the other hand, if the setting key cylinder switch 180a is not ON (NO in S018), it means that the RAM clear switch 192 has not been pressed and the setting key cylinder 180 has not been rotated when the power was turned on. In this case, the process proceeds to step S020 without executing the setting confirmation mode process of step S019. When the process proceeds to step S020, a power interruption restoration process, which will be described later, is executed, and the process proceeds to step S022.

In step S013, the information stored in the game RAM 104 is cleared (S013). However, at this time, the setting value information stored in the setting value information storage unit 107 and the information stored in the base information storage unit are not cleared.

In this way, even if the RAM clear switch 192 is pressed when the power is turned on, the set value information is not cleared, so that the game can be restarted with the set values set before the power failure. In other words, it is possible to play a game without shifting to the setting change mode and setting the setting value each time the power is turned on.

After step S013, the game control microcomputer 101 initializes the working area of the game RAM 104 (S014). In this initial setting process, the initial setting information read from the game ROM 103 is set in the work area of the game RAM 104 . Subsequently, to the effect control board 120, a RAM clear notification command for notifying the clearing of the contents stored in the game RAM 104 is transmitted (S015), and the process proceeds to step S022. In step S022, as other power-on processing, for example, setting of game CPU 102, setting of SIO, PIO, CTC (circuit for managing interrupt time), etc. are performed, and this processing ends.

[Setting Change Mode Processing] As shown in FIG. 23, in the setting change mode processing (S012), the game control microcomputer 101 first sets the effect control board 120 for notifying the transition to the setting change mode. A mode transition command is transmitted (S030). Then, in order to output a setting changing signal to the external terminal board 150 along with the shift to the setting change mode, the output setting is switched to ON (S031). Next, it is determined whether setting value information is stored in the setting value information storage unit 107 (S032). If the set value information is stored (YES in S032), the set value is set before the power failure, so the set value is displayed on the 7-segment display 300 based on the set value information (S033) (Fig. 18(B)). Specifically, the game control microcomputer 101 transmits serial data for displaying the set value to the LED driver 350 from the serial data transmission terminal. In this way, the setting changer can grasp the set value set before the power failure on the 7-segment display 300 immediately after performing the setting change mode transition operation. After step S033, to the effect control board 120, a first set value specifying command (set value command for display) for notifying the information of the set value at the present time (set value information) is transmitted (S034). , proceed to step S035. On the other hand, if the set value information is not stored in step S032 (NO in S032), steps S033 and S034 are bypassed and the process proceeds to step S035.

In step S035, it is determined whether or not the RAM clear switch 192 is ON. That is, it is determined whether or not the RAM clear switch 192 has been pressed in the setting change mode. If it is ON (YES in S035), new setting value information is stored in the setting value information storage unit 107 in order to advance the setting value by one (S036). When the set value is "6" and the RAM clear switch 192 is pressed, set value information indicating that the set value is "1" is stored. Subsequently, based on the new set value information, the set value is displayed on the 7-segment display 300 (S037) (see FIGS. 18B, 18C, and 18D). As a result, it is possible for the setting changer to understand that the setting value has been moved up.

Subsequently, the game control microcomputer 101 transmits a set value change command for notifying that the set value has been changed to the effect control board 120 (S038), thereby increasing the set value by one. information (set value information). Then, in step S039, it is determined whether or not the setting key cylinder switch is OFF. That is, it is determined whether or not a setting confirmation operation has been performed. If it is not OFF (NO in S039), it is not yet time to end the setting change mode, so the process returns to step S035. On the other hand, if it is OFF (YES in S039), to the effect control board 120, the second setting value designation command (fixed setting value command) that is finally decided is transmitted (S040), and the setting change mode A setting mode end command is sent to notify the end (S041). Then, the output setting of the setting changing signal is turned off (S042). The set value displayed on the 7-segment display 300 is turned off (S043), and the process proceeds to step S013 (see FIG. 22). In this way, as soon as the setting key cylinder switch 180a is turned off, the setting value is not visible on the 7-segment display 300, making it difficult for the surroundings to grasp the fixed setting value. Since the processing after step S013 has been described above, the description thereof is omitted. In this way, in the setting change mode process, it is possible to send various information such as the fact that the game machine has shifted to the setting change mode and the setting values related to the game machine to the sub-control board such as the effect control board 120 using commands. state. At the same time, the output setting of the signal output from the game control microcomputer 101 to the external terminal board 150 is switched. These commands and signals are executed in the output process (S106) of FIG. 27, which will be described later.

[Setting value confirmation mode processing] As shown in FIG. 24, in the setting value confirmation mode processing (S019), the game control microcomputer 101 first displays the setting value on the 7-segment display 300 based on the setting value information ( S050). Subsequently, it is determined whether or not a predetermined time (for example, 3 seconds) has elapsed since the 7-segment display 300 started displaying the set value. If it has not passed (NO in S051), the process of step S051 is repeated, and the display of the set value on the 7-segment display 300 continues. On the other hand, if it has elapsed (YES in S051), the setting value displayed on the 7-segment display 300 is changed to a non-display mode (S052), and step S020 (see FIG. ). As described above, in the setting value confirmation mode processing (S019), unlike the above-described setting change mode processing (S012), the setting value is not changed, and the current setting value is simply displayed on the 7-segment display 300. Only.

[Restoration Process at Power Failure] As shown in FIG. 25, in the restoration process at power failure (S020), the game control microcomputer 101 first determines whether or not the power failure flag is ON (S060). The power failure flag is a flag that indicates the occurrence of power failure, and is a flag that is turned ON in power failure monitoring processing (see FIG. 28), which will be described later. If the power-off flag is not ON (NO in S060), there is a possibility that the power has not been cut off normally, so the process proceeds to step S065.

On the other hand, if the power interruption flag is ON (YES in S060), the checksum of the game RAM 104 is calculated (S061), and the checksum of the game RAM 104 stored (stored) at the time of the power interruption ( (See step S161 in FIG. 28)) is determined (S062). If these checksum values do not match (NO in S062), it is determined that the contents stored in the game RAM 104 are abnormal, and the process proceeds to step S065. On the other hand, if the checksum values match (YES in S062), it is determined that the contents stored in the game RAM 104 are normal, and the process proceeds to step S063.

In step S063, setting management of the work area of the game RAM 104 at the time of power recovery is performed. In this setting process, the power recovery information is read from the game ROM 103 and set in the work area of the game RAM 104 . After that, the game control microcomputer 101 turns off the power-off flag (S064), and proceeds to the above-described step S022 (see FIG. 22). Since the processing after step S022 has been described above, the description thereof is omitted.

On the other hand, in step S065, the information stored in the game RAM 104 is cleared. At this time, the setting value information stored in the setting value information storage unit 107 and the information related to the base stored in the base information storage unit 108 (information on the total number of shot balls, information on the total number of winning balls, one Previous base information, second previous base information, third previous base information) are not cleared. However, when proceeding to step S065, there is a possibility that the power supply is not normally cut off, or there is a possibility that the checksum value does not match and the storage contents of the game RAM 104 are abnormal. . Therefore, instead of the process of step S065, the setting value information and the information related to the base may also be cleared. In this case, after clearing the setting value information, setting value information indicating, for example, "1" may be newly stored in the setting value information storage unit 107 as the setting value of the initial value. In addition, in the process of step S065, if the power-off flag set in the game RAM 104 is ON, the power-off flag is turned OFF.

After step S065, the work area of the game RAM 104 is initialized (S066). In this initial setting process, the initial setting information read from the game ROM 103 is set in the work area of the game RAM 104 . Subsequently, the game control microcomputer 101 transmits a RAM clear notification command for notifying the clearing of the storage content of the game RAM 104 to the effect control board 120 (S067), and the above-described step S022 (see FIG. 22). ).

[Error Mode Processing] As shown in FIG. 26, in the error mode processing (S021), the game control microcomputer 101 first displays "E" (see FIG. 20) in the fourth display area 340 of the 7-segment display 300. An error display process is executed to indicate characters (S080). As a result, the fourth display area 340 of the 7-segment display 300 emits light in an error lighting manner so as to represent the letter "E". Thus, by showing the character "E" on the 7-segment display 300 to the employees of the game arcade or the like, it is possible to make them understand the transition to the error mode.

Subsequently, the game control microcomputer 101 transmits an error command for notifying the transition to the error mode to the performance control board 120 (S081), and outputs a security signal to the external terminal board 150. Therefore, the security signal output setting is turned on (S082). Thereafter, loop processing is performed without returning to the power-on processing (S001, see FIG. 22). In this way, when shifting to the error mode, the error mode continues until the power is turned off. Therefore, the game cannot be started unless the setting value is set by shifting to the setting change mode when the power is turned on next time.

[Main Side Timer Interrupt Processing] The game control microcomputer 101 repeats the main side timer interrupt processing shown in FIG. 27 every short period of time, such as 4 msec. First, the game control microcomputer 101 determines the jackpot random number used for the jackpot lottery, the hit type random number for deciding the jackpot type, the reach random number for deciding whether or not to set the reach state in the effect symbol variation effect, and the variation pattern. A random number update process is performed to update the fluctuation pattern random number, the normal symbol random number (hit random number) used for the normal symbol lottery, etc. (S101). At least part of each random number may be a so-called hardware random number generated using a known random number generation circuit such as a counter IC. If all random numbers are hardware random numbers, there is no need to update the random numbers by software. Moreover, the random number generation circuit may be incorporated in the game control microcomputer 101 .

Next, the game control microcomputer 101 performs input processing (S102). In the input process (S102), various sensors (first starting hole sensor 11a, second starting hole sensor 12a, gate sensor 13a, big winning hole sensor 14a, general winning hole sensor 10a) mainly attached to the pachinko game machine PY1 , discharge port sensor 18a (see FIG. 6)) is read, and a prize ball command for dispensing prize balls corresponding to the type of the prize winning port is set in the output buffer of the game RAM 104. The set prize ball command is transmitted to the payout control board 170 .

Subsequently, the game control microcomputer 101 executes a starting opening sensor detection process (S103), a special action process (S104), and a normal action process (S105). In the starting opening sensor detection process (S103), if there is a prize winning detection by the first starting opening sensor 11a or the second starting opening sensor 12a, it is determined that the number of pending memories corresponding to the winning opening detected is less than four. Random numbers such as jackpot random numbers (jackpot random numbers, hit type random numbers, reach random numbers, and fluctuation pattern random numbers (see FIG. 13A)) are acquired as conditions. Also, if there is passage detection by the gate sensor 13a, normal pattern random numbers (see FIG. 13(B)) are acquired on condition that the number of normal pattern reservations is less than four.

In the special operation process (S104), the random numbers such as the jackpot random numbers acquired in the starting sensor detection process (S103) are stored in the jackpot determination table (see FIGS. 14A to 14F) based on the set value indicated by the set value information. ), a hit type determination table (see FIG. 12), a reach determination table (see FIG. 15A), and a special figure variation pattern determination table (see FIG. 16). It should be noted that the big-hit determination processing for determining whether or not the game is a big-hit by using the big-hit determination table shown in FIGS. Then, special symbols are displayed (variation display and stop display) for showing the result of the big winning lottery. When displaying the special symbols, a variation start command including information on the variation pattern of the variation display of the special symbols is set in the output buffer of the game RAM 104 . Then, as a result of judging the jackpot random number, if the jackpot is won, the jackpot game is to open the jackpot 14 according to a predetermined opening pattern (opening time and number of times of opening, see FIG. 14) corresponding to the type of jackpot. (special game). When executing this jackpot game, an opening command including information on the type of the jackpot symbol that has been won is set in the output buffer of the game RAM 104 . In the special operation process (S104), if there is no memory of a random number such as a jackpot random number, a customer waiting standby command for causing the production control microcomputer 121 to execute a customer waiting production is set.

In the normal operation process (S105), the normal symbol random number acquired in the starting sensor detection process (S103), the normal symbol hit determination table (see FIG. 15 (B)) is used for determination, and the normal symbol variation pattern selection table (Refer to FIG. 15(C)) is used to select the variation time of the normal symbol according to the game state. Then, the display of the normal design (fluctuation display and stop display) for informing the determination result of the normal drawing lottery is performed. As a result of the determination of the normal symbol random number, when the normal winning symbol is won, an auxiliary game is performed to open the electric chew 12D according to a predetermined opening pattern (opening time and number of openings, see FIG. 17) according to the game state. conduct.

Subsequently, the game control microcomputer 101 executes an output process (S106) for outputting the command set in each process described above to the effect control board 120 or the like. In the output process (S106), signal output to the external terminal board 150 is also performed.

For example, when the inner frame 21 or the front door 23 is opened, a door open signal is output from the game control board 100 to the external terminal plate 150 . The door open signal is output to the second CN, and is a signal output when the open state is detected by either the front door open sensor TS1 or the inner frame open sensor TS2. This signal is turned off when the front door open sensor TS1 and the inner frame open sensor TS2 are detected to be closed. In this embodiment, two sensors, the front door open sensor TS1 and the inner frame open sensor TS2, are used to detect the open state of each of the inner frame 21 and the front door 23. Installation of these sensors The number, location, output condition of the door opening signal, etc. can be changed as appropriate. By outputting a signal corresponding to the open state of the inner frame 21 and the front door 23, the data display 500 and the hall computer 600 indicate that the inner frame 21 and the front door 23 are open. It can be recognized, and it is possible to call attention to fraudulent activity in advance.

When the variable display of the first special symbol and the second special symbol is stopped and displayed, a symbol determination signal is output from the game control board 100 to the external terminal board 150 . The symbol determination signal is output to the 3rd CN, and the variation of the first special symbol and the second special symbol is stopped and displayed (the "jackpot symbol" or "losing symbol" is stopped and displayed. ) is a signal output with a predetermined length at the timing. When the data display device 500 or the hall computer 600 receives the pattern determination signal, it becomes possible to tally how many times the pachinko gaming machine PY1 has played a pattern variation game (variation display of special symbols). . In this embodiment, the first special symbol and the second special symbol are output as one signal regardless of whether the symbol variations of the first special symbol and the second special symbol are stopped and displayed. Dedicated wiring (signal line) corresponding to the stop display of each symbol variation, such as a first symbol confirmation signal corresponding only to and a second symbol confirmation signal corresponding only to a second special symbol, etc. good.

When a game ball enters the first start port 11 and when a game ball enters the second start port 12, a start port signal is output from the game control board 100 to the external terminal plate 150. be done. The starter signal is output to the 4th CN, and is a signal output with a predetermined length at the timing when the game ball is detected by the first starter sensor 11a and the second starter sensor 12a. is. When the data display device 500 or the hall computer 600 receives this start-up signal, it becomes possible to tally the winning state of the start-up of the gaming machine.

During the execution period of the special game (jackpot game), a jackpot signal is output from the game control board 100 to the external terminal plate 150 . The jackpot signal is output to the 5th CN, and is a signal that is always kept ON during execution of the special game and turned OFF upon completion of the special game. By outputting a signal corresponding to the special game state in this way, the data display 500 and the hall computer 600 can recognize the occurrence of the big win, and can notify the occurrence of the big win.

As a game state, when the variable time reduction function is in the operating state (time saving state), a time saving signal is output from the game control board 100 to the external terminal plate 150 . The time saving signal is output to the 6th CN, and the ON state is always maintained when the variable time reduction function is in the operating state (time saving state), and the end of the variable time saving function (non-time saving state) is a signal that is turned off by Similarly, when the probability variation function is in the operating state (high probability state) as the game state, a high probability medium signal is output from the game control board 100 to the external terminal plate 150 . The high-probability medium signal is output to the 7th CN, and is always maintained in the ON state when the high-probability state is in effect, and when the high-probability state ends and the normal-probability state (non-high-probability state) is entered. This signal is turned off. By outputting the time saving signal and the high probability signal in this way, the data display 500 and the hall computer 600 can recognize that the gaming machine is in the time saving state and the high probability state.

When it is determined that a game ball enters each winning hole and a prize ball is paid out, a main prize ball signal is output from the game control board 100 to the external terminal board 150 . The main prize ball signal is output to the 8th CN, and is a signal that is output with a predetermined length at the timing when a prize ball to be paid out occurs (timing when the game ball enters the prize winning opening). is. When the data display 500 or the hall computer 600 receives this main prize ball signal, the number of prize balls to be paid out by the gaming machine can be tallied. In this embodiment, the game control microcomputer 101 counts the number of prize balls in advance, and when it is expected that 10 prize balls will be generated, a signal of a predetermined length once ( one pulse signal) is output. The output condition of the signal can be appropriately changed, such as outputting a signal of a predetermined length (one pulse signal) once in response to the generation of one prize ball.

Also, when some kind of fraudulent act is performed with respect to the pachinko game machine PY1, or when various errors are detected, a security signal is output from the game control board 100 to the external terminal board 150. FIG. The security signal is output to the ninth CN, and is always kept ON during the period when the pachinko game machine PY1 is in an abnormal state, and when the abnormal state of the pachinko game machine PY1 is resolved. This is a signal that turns off at

When the pachinko game machine PY1 is in the setting change mode, the game control board 100 outputs a setting change signal to the external terminal board 150 . The signal during setting change is output to the 10th CN, and the ON state is maintained during the period in which the game control microcomputer 101 determines that the setting is being changed, and the game control microcomputer 101 sets This signal is turned off when it is determined that the change has been completed. With this setting change signal, the data display 500 and the hall computer 600 can recognize that the setting of the gaming machine is being changed, and can call attention to the setting change or report fraudulent activity.

When a prize ball is paid out from the gaming machine, a prize ball signal is output from the payout control board 170 to the external terminal board 150 . The prize ball signal is a signal that outputs information to the first CN, and is a signal that is output with a predetermined length at the timing when ten prize balls are paid out. In the present embodiment, the output timing of the prize ball signal is set to 1 unit for 10 balls. When the data display device 500 or the hall computer 600 receives this prize ball signal, the actual number of prize balls paid out from the gaming machine can be tallied.

In this embodiment, the pachinko game machine PY1 is provided with a call switch YS, and the player can call a hall clerk by operating the call switch YS. A call signal is output from the payout control board 170 to the external terminal board 150 when the call switch YS is operated. This call signal is maintained on while the call switch YS is in the detection state, and is turned off when the call switch YS is in the non-detection state.

[Power-off monitoring process] In the power-off monitoring process (S107), as shown in FIG. Otherwise (NO in S160), this processing ends. The power-off signal is a signal output from the power supply substrate 190 when the monitored power supply voltage (for example, 24 V DC) is not detected for a predetermined period (for example, 25 ms). If a power-off signal is input (YES at S160), a checksum is calculated and stored in the game RAM 104 (S161), and a power-off flag is turned on (S162). Then, prohibition of access to the game RAM 104 is set (S163). This makes it impossible to write or read information to or from the game RAM 104 . Thereafter, loop processing is performed without returning to the main side timer interrupt processing (S005, see FIG. 27).

In parallel with the processing in the game control microcomputer 101 described above, the effect control microcomputer 121 performs the processing shown in FIGS. The operation of the effect control microcomputer 121 will be described below.

[Sub-control main process: FIG. 29] The effect control microcomputer 121 provided in the effect control board 120 reads and executes the sub-control main process program shown in FIG. 29 from the effect ROM 123 when the power is turned on. Note that counters, timers, flags, statuses, buffers, etc. appearing in the description of the operation of the effect control microcomputer 121 are provided in the effect RAM 124 .

As shown in FIG. 29, in the sub-control main process, a sub-side power supply start-up process (S1001) is performed. Here, processing such as confirmation of a sub-side power interruption flag (a flag that is turned on at the time of power interruption) and confirmation of whether or not the contents of the performance RAM 124 are normal is performed. In subsequent step S1002, other initial settings are performed. In the other initial settings, for example, settings of the effect CPU 122, settings of SIO, PIO, CTC (circuit for managing interrupt time), etc. are performed. Also, if the sub-side power-off flag is ON, it is turned OFF.

In step S1003, interrupts are prohibited. Next, random number seed update processing is executed (S1004). In the random number seed update process (S1004), the values of various effect determination random number counters are updated. The random numbers for determining the effect include the random numbers for determining the effect pattern for determining the effect pattern, the random numbers for determining the variable effect pattern for determining the variable effect pattern, and the random numbers for determining the effect for determining the various effect effects. etc. The random number update method can be the same method as the random number update process performed by the game control board 100 described above. Instead of adding 1 to the random value at the time of updating, it is also possible to add 2 at a time. This also applies to the random number update process performed by the game control board 100 described above.

When the random number seed update process (S1004) ends, the command transmission process is executed (S1005). In the command transmission process ( S1005 ), various commands stored in the output buffer in the performance RAM 124 of the performance control board 120 are transmitted to the image control board 140 . The image control board 140 that has received the command executes various effects (variation effect, opening effect, round effect, ending effect, etc.) using the image display device 50 according to the command. The effect control microcomputer 121 subsequently permits an interrupt (S1006). After that, steps S1003 to S1006 are looped. While interrupts are enabled, reception interrupt processing (S1007), 1 ms timer interrupt processing (S1008), and 10 ms timer interrupt processing (S1009) can be executed.

[Receiving Interrupt Processing: FIG. 30] In the receiving interrupt processing (S1007), when the strobe signal (STB signal) is turned ON, that is, the strobe signal sent from the game control board 100 is sent to the external INT input section of the effect control microcomputer 121. When input, this process is executed with priority over other interrupt processes (S1008, S1009). As shown in FIG. 30, in the reception interrupt process (S1007), various commands transmitted from the game control board 100 are stored in the reception buffer of the effect RAM 124 (S1101).

[1 ms timer interrupt processing: FIG. 31] 1 ms timer interrupt processing (S1008) is executed each time an interrupt pulse of 1 msec cycle is input to the effect control board 120. FIG. As shown in FIG. 31, in the 1 ms timer interrupt processing (S1008), first, input processing is performed (S1201). In the input processing (S1201), switch data (edge data and level data) is created based on detection signals from the input section detection sensor 40a (see FIG. 7) and the select button detection sensor 42a (see FIG. 7).

Subsequently, lamp data output processing is performed (S1202). In the lamp data output process (S1202), the set lamp data (data for controlling the emission of the frame lamp 212 and the board lamp 54) is sent to the sub-drive board so that the frame lamp 212 and the board lamp 54 will emit light at a timing suitable for the performance. 162. As a result, the sub-drive board 162 controls the light emission of the frame lamp 212 and the board lamp 54, so that the frame lamp 212 and the board lamp 54 are in a special first light emission mode (see FIG. 18B). , a special second light emission mode (see FIGS. 18C and 18D), a special third light emission mode (see FIG. 18F), and a special error light emission mode (see FIG. 20B). It is possible.

Next, drive control processing (S1203) is performed. In the drive control process (S1203), drive data is created and output in order to drive the board movable body 55k at a timing suitable for the performance. That is, the board movable body 55k is driven in a predetermined operation mode according to the drive data. Then, watchdog timer processing (S1204) for resetting the watchdog timer is performed, and this processing ends.

[10 ms timer interrupt processing: FIG. 32] 10 ms timer interrupt processing (S1009) is executed each time an interrupt pulse of 10 msec cycle is input to the effect control board 120. FIG. As shown in FIG. 32, in the 10 ms timer interrupt processing (S1009), first, received command analysis processing, which will be described later, is performed (S1301). Next, a switch state acquisition process is performed to store the switch data created by the 1 ms timer interrupt process in the effect RAM 124 as switch data for the 10 ms timer interrupt process (S1302). Subsequently, switch processing for setting the display contents of the display screen 50a based on the switch data stored in the switch state acquisition processing (S1302) is performed (S1303).

Subsequently, the production control microcomputer 121 creates audio data (control data for outputting audio from the speaker 149) and executes audio control processing for outputting the audio data to the image control board 140 (S1304). By this voice control processing (S1304), as will be described later, a voice saying "Settings can be changed" (see (B) and (E) in FIG. 18) and a voice saying "Setting values have been changed" (see FIG. 18) (C) and (D)), and a voice saying "The set value has been determined" (see (F) in FIG. 18) and a special error sound) are output from the speaker 149 . After that, the effect control microcomputer 121 executes other processes such as creating lamp data and updating various random numbers for determination of effect (S1305), and ends this process.

[Received command analysis process: FIGS. 33 to 35] In the received command analysis process (S1301), first, the effect control microcomputer 121 determines whether or not a setting change mode transition command is received from the game control board 100 (S1401 ), and if received, the setting mode transition effect processing (S1402) is performed.

In the setting mode transition effect processing (S1402), a setting mode transition effect command or the like for displaying the setting changing image SH shown in FIG. As a result, the image CPU 141 of the image control board 140 that has received the setting mode transition effect command displays the setting changing image SH on the display screen 50a. Also, in the setting mode transition effect processing (S1402), voice data for outputting a voice saying "The setting can be changed" (see FIG. 18B) is set in a predetermined storage area of the RAM 124 for effect. As a result, the audio CPU 147 of the image control board 140 that has received the audio data causes the speaker 149 to output the audio "The setting can be changed." Also, in the setting mode effect (S1402), the lamp data for causing the frame lamp 212 and the board lamp 54 to emit light in a special first light emission mode (see FIG. 18(B)) is set in a predetermined storage area of the effect RAM 124. do. As a result, the sub-drive board 162 that has received the lamp data causes the frame lamp 212 and the board lamp 54 to emit light in a special first light emission mode. As described above, the display of the setting changing image SH, the voice saying "The setting can be changed", and the light emission in the special first light emission mode allow the person who changes the setting to enter the setting change mode and make any setting. It is possible to let the user know that the value can be changed.

Subsequently, it is determined whether or not the first setting value designation command has been received (S1403). If the first setting value designation command has been received, the value of the first setting value designation command (the value of the setting value at the time of shifting to the setting change mode) is set in the setting value flag 126 (S1404), and the next step S1405. proceed to

Subsequently, the effect control microcomputer 121 determines whether or not the setting value change command is received from the game control board 100 (S1405), and sets the setting change flag 127 to "1" if it is received (S1406). At the same time, according to the content of the received setting value change command, a setting value change rendering process is performed (S1407). In the set value change effect processing (S1407), a set value change effect command for displaying the set value change image YG shown in FIGS. 18C and 18D is set in the output buffer of the RAM 124 for effect. As a result, the image CPU 141 of the image control board 140 that has received the setting value change effect command displays the setting value change image YG superimposed (layered) on the setting changing image SH on the display screen 50a.

Also, in the setting value change effect processing (S1407), the sound data for outputting the sound "The setting value has been changed" (see FIG. 18C or FIG. 18D) is stored in the effect RAM 124 in a predetermined storage area. As a result, the audio CPU 147 of the image control board 140 that has received the audio data causes the speaker 149 to output the audio "The set value has been changed." Also, in the set value change effect processing (S1407), the lamp data for causing the frame lamp 212 and the board lamp 54 to emit light in a special second light emission mode (see FIG. 18(C) or FIG. 18(D)) is used for effect. It is set in a predetermined storage area of RAM 124 . As a result, the sub-drive board 162 that has received the lamp data causes the frame lamp 212 and the board lamp 54 to emit light in a special second light emission mode. As described above, the display of the setting value change image YG, the sound "The setting value has been changed", and the light emission in the special second light emission mode can be used not only by the person who changed the setting but also by the employees of the surrounding game parlors. It is also possible for the staff to grasp the circumstances in which the set values have been changed. In the present embodiment, when resetting to the same setting value, which is called "change of setting", for example, when the setting value is "1", the setting change mode is entered and the setting value is changed. Even if it is set to "1" again, the information of the setting change flag 127 is changed to "1" based on the reception of the setting value change command in order to determine that the setting has been changed. I am assuming. Also, if the information of the setting change flag 127 is already "1", it is left as "1".

Subsequently, the effect control microcomputer 121 determines whether or not the second set value designation command is received from the game control board 100 (S1408), and when the second set value designation command is received, the set value flag Update processing (S1409) is performed. In this set value flag update process (S1409), the value of the set value flag 126 is updated according to the contents of the second set value designation command. For example, if the value of the second setting value designation command is "1", the value of the setting value flag 126 is updated to "1". Similarly, when the value of the second setting value designation command is "2", the value of the setting value flag 126 is updated to "2". In this embodiment, since the settings are made in six steps from "1" to "6", there are six types of second setting value designation commands. Then, the value of the setting value flag 126 is updated according to the types of these six types of second setting value specifying commands. As a result, the effect control microcomputer 121 can grasp the set value at the present time, and the effect means such as the image display device 50 can execute the suggestion effect suggesting the set value.

Subsequently, the effect control microcomputer 121 determines whether or not the setting mode end command is received from the game control board 100 (S1410), and if it is received, the setting mode end effect processing (S1411) is performed. In the setting mode end effect processing (S1411), a setting value confirmation effect command for displaying the setting value confirmation image SK shown in FIG. 18F is set in the output buffer of the effect RAM 124. As a result, the image CPU 141 of the image control board 140, which has received the setting value confirmation effect command, changes the setting shown in FIG. The display is switched to the value confirmation image SK.

Also, in the setting mode end rendering process (S1411), voice data for outputting a voice saying "The set value has been finalized" (see FIG. 18F) is set in a predetermined storage area of the RAM 124 for rendering. As a result, the audio CPU 147 of the image control board 140 that has received the audio data causes the speaker 149 to output the audio "The set value has been finalized." Also, in the setting mode end rendering process (S1411), lamp data for causing the frame lamp 212 and the board lamp 54 to emit light in a special third light emission mode (see FIG. 18(F)) is stored in a predetermined storage area of the RAM 124 for rendering. set to As a result, the sub-drive board 162 that has received the lamp data causes the frame lamp 212 and the board lamp 54 to emit light in a special third light emission mode. As described above, the display of the setting value confirmation image SK, the voice saying "The setting value has been confirmed", and the light emission in the special third light emission mode enable not only the setting changer but also the employees of the surrounding amusement arcades to Also, it is possible to grasp the situation in which the set value is determined.

Subsequently, the effect control microcomputer 121 determines whether or not the RAM clear notification command is received from the game control board 100 (S1412). Change (S1413) and proceed to the next step.

Subsequently, the effect control microcomputer 121 determines whether or not a power activation command is received from the game control board 100 (S1414). , mini-character effect processing 1 (S1416) is executed when the power is turned on. Then, the RAM clear flag is changed from "1" to "0" (S1417), the setting change flag 127 is changed from "1" to "0" (S1418), and the process proceeds to the next step.

Subsequently, the effect control microcomputer 121 determines whether or not a variation start command is received from the game control board 100 (S1419), and if received, after performing a variation effect start process (S1420) described later, The auxiliary effect start process (S1421) is executed.

Subsequently, the effect control microcomputer 121 determines whether or not the fluctuation stop command is received from the game control board 100 (S1422). Along with performing the fluctuation effect end processing (S1424), the auxiliary effect end processing is performed (S1425). In the fluctuation production end processing (S1424) and the auxiliary production end processing (S1425), the fluctuation stop command is analyzed, and based on the analysis result, the fluctuation production and the fluctuation production end command for ending the auxiliary production, Then, an auxiliary effect end command is set in the output buffer of the RAM 124 for effect.

Subsequently, effect information storage processing (S1426) is performed. In the effect information storage process (S1426), information regarding the effect pattern decided upon receipt of the change stop command and various information related to the auxiliary effect (mini character effect) currently being executed are stored in the game history information storage area 129 of the effect RAM 124. Save to . In the present embodiment, information on final stop symbols of the left effect symbol EZ1, middle effect symbol EZ2, and right effect symbol EZ3, and information on the variable game number (the value of the variable game number counter 128, the value of the variable game number display area HR, types, etc.), and performance information on various mini-characters (types of mini-characters, types of special mini-character determination performances, cumulative mini-character point MP values, etc.).

Subsequently, the effect control microcomputer 121 determines whether or not an opening command is received from the game control board 100 (S1427), and if received, performs an opening effect selection process (S1428). In the opening effect selection process (S1428), the opening command is analyzed, and based on the analysis result, the pattern (contents) of the opening effect to be executed during the opening of the jackpot game is selected. Then, an opening performance start command for starting the opening performance in the selected opening performance pattern is set in the output buffer of the RAM 124 for performance.

Subsequently, the effect control microcomputer 121 determines whether or not a round designation command is received from the game control board 100 (S1429), and if received, performs a round effect selection process (S1430). In the round effect selection process (S1430), the round designation command is analyzed, and based on the analysis result, the pattern (contents) of the round effect to be executed during the round game of the jackpot game is selected. Then, a round effect start command for starting the round effect in the selected round effect pattern is set in the output buffer of the RAM 124 for effect.

Subsequently, the effect control microcomputer 121 determines whether or not an ending command is received from the game control board 100 (S1431), and if received, performs an ending effect selection process (S1432). In the ending effect selection process (S1432), the ending command is analyzed, and based on the analysis result, the pattern (contents) of the ending effect to be executed during the ending of the jackpot game is selected. Then, an ending effect start command for starting the ending effect in the selected ending effect pattern is set in the output buffer of the RAM 124 for effect.

Subsequently, the effect control microcomputer 121 determines whether or not an error command is received from the game control board 100 (S1433), and if received, performs an error mode notification process (S1434). In the error mode notification process (S1434), an operation suggestion effect command for displaying the operation suggestion image SE shown in FIG. 20B is set in the output buffer of the effect RAM 124. As a result, the image CPU 141 of the image control board 140 that has received the operation suggestion rendering command displays the operation suggestion image SE shown in FIG. 20(B) on the display screen 50a.

Also, in the error mode notification process (S1434), audio data for outputting a special error sound (see FIG. 20B) is set in a predetermined storage area of the RAM 124 for effect. As a result, the audio CPU 147 of the image control board 140 that has received the audio data causes the speaker 149 to output a special error sound. Also, in the error mode notification process (S1434), lamp data for causing the frame lamp 212 and the board lamp 54 to emit light in a special error light emission mode (see FIG. 20(B)) is set in a predetermined storage area of the effect RAM 124. do. As a result, the sub-drive board 162 that has received the lamp data causes the frame lamp 212 and the board lamp 54 to emit light in a special error light emission mode. As described above, the display of the operation suggestion image SE, the special error sound, and the light emission in the special error light emission mode inform the employees of the amusement arcade that the error mode has been entered, that is, that the set value is set. It is possible to make them understand that they are not. Moreover, in this form, when this non-setting error is detected, a security signal is output from the game control board 100 via the wiring connected to CN9 of the external terminal board 150. FIG. With this signal, the data display 500 and the hall computer 600 can recognize that the setting of the game machine is not set or that the setting information is abnormal. In conjunction with a special error sound, hall facilities can also call attention to the settings of the game machine.

Subsequently, the effect control microcomputer 121 performs other processes (S1435) based on received commands other than the above commands (for example, processes for performing effects associated with variable display of normal symbols). Then, the received command analysis processing (S1301) ends.

[Process 1 for resetting the number of variable games at power startup] The process 1 for resetting the number of variable games at power startup will be described with reference to FIGS. 36 to 40. FIG. In the power-on variable game count reset process 1 (S1415), first, the effect control microcomputer 121 checks the value of the setting change flag 127 (S1601). Then, if the value of the setting change flag 127 is "1" (YES in S1601), a first reset lottery process (S1603), which will be described later, is performed. On the other hand, if the value of the setting change flag 127 is "0" (NO in S1601), the value of the RAM clear flag 125 is checked (S1602). Then, when the value of the RAM clear flag 125 is "1" (YES in S1602), a first reset lottery process (S1603), which will be described later, is performed. On the other hand, when the value of the RAM clear flag 125 is "0" (NO in S1602), a second reset lottery process (S1604), which will be described later, is performed. Subsequently, after each determination of the first reset lottery process (S1603) and the second reset lottery process (S1604), it is determined whether or not the reset lottery has been won (S1605). If the reset lottery is won (YES in S1605), the variable game number counter 128 is set to "0" (S1606).

Subsequently, the effect control microcomputer 121 performs a reset display mode lottery process (S1607). In this reset display mode lottery process (S1607), a lottery regarding a reset display mode is performed for each set value using a lottery table as shown in FIG. 40, which will be described later. Then, when the reset display mode is won in the reset display mode lottery process (S1607) (YES in the determination of S1608), the first reset variable game number display process (S1609) is performed. In this first reset time variable game number display process (S1609), the special variable game number display mode determined in step S1608 (the first special display mode (blue) in FIG. 49(B), the (C ) The second special display mode (red), (A) special display mode (gold) in FIG. 50) is displayed in the variable game number display area HR provided on the display screen 50a. On the other hand, if the reset display mode is not won in the reset display mode lottery process (S1607) (NO in the judgment of S1608), the second reset variable game number display process (S1610) is performed. . In this second reset variable game number display process (S1610), the normal variable game number display mode ((A) in FIG. 49 to be described later) determined in step S1608 is displayed in the variable game number display area provided on the display screen 50a. Display in HR.

In addition, the effect control microcomputer 121 judges whether or not the reset lottery has been won (S1605), and if it is not won (in the case of NO in S1605), the value of the variable game number counter 128 being saved is reset (S1611). In the variable game number continuation display process (S1612), the variable game number information and the type of the variable game number display area HR as shown in (B) and (C) of FIG. A number information continuous display image HS2 (continuous display image) is displayed in the variable game number display area HR provided on the display screen 50a.

Next, details of the first reset lottery process (S1603) and the second reset lottery process (S1604) will be described with reference to FIGS. In the first reset lottery process (S1603) and the second reset lottery process (S1604) in the present embodiment, a reset table (see FIG. 39) corresponding to six levels of set values from "1" to "6" ) is used to determine whether to reset the value of the variable game number counter 128 (variable game number information) or to take over the previous variable display number information.

The first reset lottery process (S1603) is executed when a setting change operation is performed (YES in S1601) and when a RAM clear operation is performed (YES in S1602). First, in the first reset lottery process (S1603), as shown in FIG. 6", a lottery is conducted using the sixth reset table (see (F) in FIG. 39) (S1702). Incidentally, the judgment value in the case of resetting the variable number of games in the sixth reset table is 0 to 94, and the judgment value in the case of winning the previous variable display number information is 95 to 99. Then, the determination result information using the sixth reset table is set in a predetermined storage area of the effect control microcomputer 121 (S1703), and the process continues to determine whether or not the reset lottery is won (S1605).

Subsequently, the production control microcomputer 121 determines whether or not the setting value is "5" (S1704), and if the setting value is "5", the fifth reset table (Fig. 39 (E)) is used to draw lots (S1705). The determination value for resetting the variable number of games in the fifth reset table is 0 to 89, and the determination value for succession of the previous variable display number information is 90 to 99. Then, the determination result information using the fifth reset table is set in a predetermined storage area of the effect control microcomputer 121 (S1703), and the process continues to determine whether or not the reset lottery is won (S1605).

Subsequently, the production control microcomputer 121 determines whether or not the setting value is "4" (S1706), and if the setting value is "4", the fourth reset table (Fig. 39 (D)) is used to draw lots (S1707). Incidentally, the determination value in the case of resetting the variable number of games in the fourth reset table is 0 to 84, and the determination value in the case of winning the previous variable display number information is 85 to 99. Then, the determination result information using the fourth reset table is set in a predetermined storage area of the production control microcomputer 121 (S1703), and the process continues to determine whether or not the reset lottery is won (S1605).

Subsequently, the effect control microcomputer 121 determines whether or not the setting value is "3" (S1708), and if the setting value is "3", the third reset table (Fig. 39 (C)) is used to draw lots (S1709). Incidentally, the judgment value for resetting the variable number of games in the third reset table is 0 to 79, and the judgment value for succession of the previous variable display number information is 80 to 99. And, along with setting the determination result information using the third reset table in a predetermined storage area of the effect control microcomputer 121 (S1703), it continues to determine whether or not reset lottery was won (S1605).

Subsequently, the effect control microcomputer 121 determines whether or not the setting value is "2" (S1710), and if the setting value is "2", the second reset table (Fig. 39 (B)) is used to draw lots (S1711). Incidentally, the judgment value in the case of resetting the variable number of games in the second reset table is 0 to 74, and the judgment value in the case of succession of the previous variable display number information is 75 to 99. Then, the determination result information using the second reset table is set in a predetermined storage area of the effect control microcomputer 121 (S1703), and the process continues to determine whether or not the reset lottery is won (S1605). On the other hand, it is determined whether or not the setting value is "2" (S1710), and if the setting value is not "2" (if the setting value is "1"), the second A lottery is performed using the 1 reset table (see (A) of FIG. 39) (S1712). In addition, the determination value in the case of resetting the variable number of games in the first reset table is a value of 0 to 69, and the determination value in the case of winning to take over the variable display number information of the previous time is 70 to 99. . Then, the determination result information using the first reset table is set in a predetermined storage area of the production control microcomputer 121 (S1703), and the process continues to determine whether or not the reset lottery is won (S1605).

In this way, if there is a setting change operation (if the determination in S1601 is YES), or if there is no setting change operation but the ram clear operation is performed (if the determination in S1602 is YES), the A first reset lottery process (S1603) as indicated by 37 is performed. Then, in the first reset lottery process (S1603), as shown in (A) to (F) of FIG. Determines whether to inherit the variable display number information. In the present embodiment, the order of the set values is "1"<"2"<"3"<"4"<"5"<"6", and the higher the set value (the highest setting) , the reset of the variable game number is more likely to be selected, and the rate at which the previous variable display number information is inherited is set to be low. By configuring the first reset lottery process (S1603) in this way, when a setting change operation is performed and when a reset operation is performed, the number of variable games is reset in the higher setting. easy. Therefore, by confirming that the reset of the variable game number is displayed, the visitor selects a gaming machine in anticipation that the setting value of the gaming machine is set high, and plays the game.

On the other hand, the second reset lottery process (S1604) is executed when the setting change operation is not performed (NO in S1601) and when the ram clear operation is not performed (NO in S1602). It is a thing. In this second reset lottery process (S1604), the effect control microcomputer 121 determines whether or not the value of the set value is "6" (S1801). lottery using the 12th reset table (see (L) in FIG. 39) (S1802). Incidentally, the judgment value for resetting the variable number of games in the twelfth reset table is 0 to 5, and the judgment value for winning the previous variable display number information is 6 to 99. Then, the determination result information using the twelfth reset table is set in a predetermined storage area of the effect control microcomputer 121 (S1803), and the process continues to determine whether or not the reset lottery is won (S1605).

Subsequently, the production control microcomputer 121 determines whether or not the setting value is "5" (S1804). If the setting value is "5", the eleventh reset table (Fig. 39 (K)) is used to draw lots (S1804). The determination value for resetting the variable number of games in the 11th reset table is 0 to 4, and the determination value for winning the previous variable display number information is 5 to 99. Then, the determination result information using the eleventh reset table is set in a predetermined storage area of the effect control microcomputer 121 (S1803), and the process continues to determine whether or not the reset lottery is won (S1605).

Subsequently, the production control microcomputer 121 determines whether or not the setting value is "4" (S1806), and if the setting value is "4", the tenth reset table (Fig. 39 (J)) is used to draw lots (S1707). The determination value for resetting the variable number of games in the tenth reset table is 0 to 3, and the determination value for winning the previous variable display number information is 4 to 99. Then, the determination result information using the tenth reset table is set in a predetermined storage area of the effect control microcomputer 121 (S1803), and the process continues to determine whether or not the reset lottery is won (S1605).

Subsequently, the production control microcomputer 121 determines whether or not the setting value is "3" (S1808). 39 (I)) is used to draw a lottery (S1809). Incidentally, the determination value in the case of resetting the variable game number in the ninth reset table is 0 to 2, and the determination value in the case of winning to take over the previous variable display number information is 3 to 99. Then, the determination result information using the ninth reset table is set in a predetermined storage area of the production control microcomputer 121 (S1803), and the process continues to determine whether or not the reset lottery is won (S1605).

Subsequently, the effect control microcomputer 121 determines whether or not the setting value is "2" (S1810), and if the setting value is "2", the eighth reset table (Fig. 39 (H)) is used to draw lots (S1811). Incidentally, the determination values in the case of resetting the variable number of games in the eighth reset table are 0 and 1, and the determination values are 2 to 99 in the case of winning to take over the variable display number information from the previous time. Then, the determination result information using the eighth reset table is set in a predetermined storage area of the production control microcomputer 121 (S1803), and the process continues to determine whether or not the reset lottery is won (S1605). On the other hand, it is determined whether or not the setting value is "2" (S1810), and if the setting value is not "2" (if the setting value is "1"), the second A lottery is made using the 7 reset table (see (G) in FIG. 39) (S1812). Incidentally, the judgment value for resetting the number of variable games in the seventh reset table is only 0, and ranges from 1 to 99. Then, the determination result information using the seventh reset table is set in a predetermined storage area of the effect control microcomputer 121 (S1803), and the process continues to determine whether or not the reset lottery is won (S1605).

In this way, when the setting change operation is not performed (NO in the judgment of S1601) and when the ram clear operation is not performed (NO in the judgment of S1602), the operation shown in FIG. Such a second reset lottery process (S1604) is performed. Then, in the second reset lottery process, as shown in (G) to (L) of FIG. Determine whether to take over the information. Incidentally, in the present embodiment, the second reset lottery process (S1604) and the first reset lottery process (S1603) are similarly set to "1"<"2"<"3"<"4"< In the order of "5" < "6", the higher the setting value (closer to the highest setting "6"), the more likely resetting of the variable game count will be selected, and the percentage of inheriting the previous variable display count information will be lower. is set to However, in the case of the first reset lottery process (S1603), compared to the case where the previous variable display number information is inherited, the rate at which the reset of the variable game number is selected is set extremely high. In the case of the 2-reset lottery process (S1604), the rate at which the reset of the variable game number is selected is set extremely low compared to the case where the previous variable display number information is inherited. With this configuration, when the setting change operation is performed and when the reset operation is performed, the variable number of games is more likely to be reset if the setting is high. Furthermore, if the setting change operation is not performed, and even if the reset operation is not performed, the variable number of games is likely to be reset if the setting is high. Therefore, by confirming that the reset of the variable game number is displayed, the visitor selects a gaming machine in anticipation that the setting value of the gaming machine is set high, and plays the game.

In addition, in the reset display mode lottery process (S1607), a lottery is performed to determine whether or not the special variation game number display mode is to be performed using the determination tables (A) to (C) shown in FIG. In the reset display mode lottery process (S1607), when the set value is "1" or "2", a lottery is performed using the first reset display mode lottery table (see FIG. 40(A)). (S1607). The range of determination values in the first reset display mode lottery table is 0 to 49 for the normal variable game number display mode (white), 50 to 79 for the first special display mode (blue), and 50 to 79 for the first special display mode (blue). 2 The judgment value for the special display mode (red) is 80 to 99, and no judgment value is set for the special display mode (gold). Next, when the set values are "3" and "4", a lottery is conducted using the second reset display mode lottery table (see (B) of FIG. 40) (S1607). The range of determination values in the second reset display mode lottery table is 0 to 29 for the normal variable game number display mode (white), 30 to 69 for the first special display mode (blue), and 30 to 69 for the first special display mode (blue). 2 The judgment value for the special display mode (red) is 70 to 99, and the judgment value for the special display mode (gold) is not set. Next, when the set values are "5" and "6", a lottery is conducted using the third reset display mode lottery table (see (C) of FIG. 40) (S1607). In addition, the range of the judgment value of the lottery table in the third reset display mode is 0 to 9 in the case of winning in the normal variable game number display mode (white), and 10 in the first special display mode (blue). to 29, the determination value for the second special display mode (red) is 30 to 79, and the determination value for the special display mode (gold) is 80 to 99. Thus, in the reset display mode lottery process (S1607), the reset display mode displayed when the number of variable games is reset ((A) to (C) in FIGS. 49 and (A) in FIG. )) according to the value of the setting value, suggesting the current setting value (including the setting value after the setting change, the setting value after the reset operation, and the setting value when winning the reset lottery) be able to.

Details of [Mini character effect processing 1 at power activation] and mini character effect processing 1 at power activation (S1416) will be described with reference to FIGS. 41 to 43. FIG. In the mini-character rendering process 1 (S1416) at the time of power-on according to the present embodiment, the setting values are set in six stages from "1" to "6". Using the determination table (see FIG. 43), a lottery is conducted regarding the type of presentation using mini-characters.

As shown in FIG. 41, in the mini character effect process 1 at power-on (S1416), the effect control microcomputer 121 first checks the value of the setting change flag 127 (S1901). If the value of the setting change flag 127 is "1" (YES in S1901), mini character reset lottery processing (S1903), which will be described later, is performed. On the other hand, if the value of the setting change flag 127 is "0" (NO in S1901), the value of the RAM clear flag 125 is confirmed (S1902). Here, if the value of the RAM clear flag 125 is "1" (YES in S1902), mini character reset lottery processing (S1903), which will be described later, is performed. On the other hand, if the value of the RAM clear flag 125 is "0" (NO in the determination in S1902), the last time information continuous display processing (S1906), which will be described later, is performed. In the mini-character reset lottery process in step S1903, which will be described later, a lottery for resetting mini-character information is performed.

Following step S1903, it is determined whether or not the mini character information reset has been won (S1904). If the result of this determination is that the mini character information reset is won (NO in S1904), the mini character information reset display processing is performed (S1905). In the reset display processing of the mini character information, a reset display image of the mini character information is displayed as shown in FIG. 48A, which will be described later.
On the other hand, if the result of the determination (S1904) of whether or not the reset of the mini character information was won is that the reset of the mini character information is not selected (NO in S1904), the continuous display processing of the previous information (S1906) is performed. . In other words, the last time information continuous display processing is performed when the RAM clear operation is not performed and the setting change operation is not performed, and when the reset of the mini character information is not won in the mini character reset lottery processing (S1903). is executed if In the continuous display processing of the last time information (S1906), the mini character information saved in the game history information saving area 129 at the last power OFF operation is read again, and the mini character information (mini character points) saved at the last power OFF operation is read again. information, status information, color information of the frame area, etc.), the content that was displayed when the power was turned off immediately before is continued to be displayed.

Next, details of the mini character reset lottery process (S1903) will be described. First, as shown in FIG. 42, in the mini character reset lottery process (S1903), the effect control microcomputer 121 determines whether or not the set value is "6" (S2001). If the number is "6", a lottery is performed using the sixth mini-character determination table (see (F) in FIG. 43) (S2002). The judgment values of the sixth mini-character judgment table are assigned 0 to 4 for the continuous display of the previous information, and 5 to 99 for the resetting of the mini-character information. Then, determination result information using the sixth mini character determination table is set in a predetermined storage area of the effect control microcomputer 121 (S2003).

Subsequently, the effect control microcomputer 121 determines whether or not the setting value is "5" (S2004), and if the setting value is "5", the fifth mini character determination table ( (See (E) in FIG. 43) is used to draw a lottery (S2005). The determination values of the fifth mini-character determination table are assigned 0 to 9 for the continuous display of the previous information, and 10 to 99 for the reset of the mini-character information. Then, determination result information using the fifth mini character determination table is set in a predetermined storage area of the effect control microcomputer 121 (S2003).

Subsequently, the effect control microcomputer 121 determines whether or not the setting value is "4" (S2006), and if the setting value is "4", the fourth mini character determination table ( (See (D) of FIG. 43) is used to draw a lottery (S2007). The determination values of the fourth mini-character determination table are 0 to 14 for the continuous display of the previous information, and 15 to 99 for the reset of the mini-character information. Then, determination result information using the fourth mini character determination table is set in a predetermined storage area of the effect control microcomputer 121 (S2003).

Subsequently, the effect control microcomputer 121 determines whether or not the setting value is "3" (S2008), and if the setting value is "3", the third mini character determination table ( (C) of FIG. 43) is used to draw a lottery (S2009). The judgment values of the third mini-character judgment table are assigned 0 to 19 for continuous display of the previous information, and 20 to 99 for resetting the mini-character information. Then, determination result information using the fourth mini character determination table is set in a predetermined storage area of the effect control microcomputer 121 (S2003).

Subsequently, the effect control microcomputer 121 determines whether or not the setting value is "2" (S2010), and if the setting value is "2", the second mini character determination table ( 43 (B)) is used to draw lots (S2011). The determination values of the second mini-character determination table are 0 to 24 for the continuous display of the previous information, and 25 to 99 for the reset of the mini-character information. Then, determination result information using the second mini character determination table is set in a predetermined storage area of the effect control microcomputer 121 . On the other hand, it is determined whether or not the setting value is "2" (S2010), and if the setting value is not "2" (if the setting value is "1"), the second 1 A lottery is performed using the mini character determination table (see (A) in FIG. 43) (S2012). The determination values in the first mini-character determination table are 0 to 29 for the continuous display of the previous information, and 30 to 99 for the reset of the mini-character information. Then, determination result information using the first mini character determination table is set in a predetermined storage area of the effect control microcomputer 121 .

In the mini character effect process 1 (S1416) at the time of power activation, basically when the setting change operation is not performed (NO in S1901) and when the RAM clear operation is not performed (NO in S1902) , continuous display processing of the previous information (S1906) is executed. However, even if the setting change operation is performed, even if the RAM clear operation is performed, if the continuous display of the previous information is selected in the mini character reset lottery process (S1904), the previous information will be displayed. Information continuous display processing (S1906) is executed. In other words, even if the RAM clear operation is performed or the setting change operation is performed, the previous information is continuously displayed according to the determination result of the mini character reset lottery process (S1903). There is also Therefore, from the player's point of view, even if the display mode of the mini character displayed when the power is turned on continues to display the previous information, there is still the possibility that the settings have been changed. can play a game in anticipation of setting changes.

Also, in this embodiment, the tendency of the determination values set in the first to sixth mini character determination tables shown in FIG. The continuous display of the previous information is likely to be selected. On the other hand, the higher the setting (the closer the set value is to "6"), the more difficult it is for the continuous display of the previous information to be selected. Therefore, the higher the current setting value (the setting value after setting change, the setting value after reset operation, and the setting value when winning the mini character information reset lottery), the more reset display of mini character information will be performed. Therefore, the visitor can play the game expecting that the setting has been changed to the high setting by selecting and playing the game machine on which the reset display is being performed.

[Variation effect start process: FIG. 44] In the change effect start process (S1420), the effect control microcomputer 121 first analyzes the change start command (S2101). The variation start command includes information on the variation pattern (see FIG. 16), information on the special figure stop pattern data based on the determination of the big hit, etc., and detailed effect pattern information on the mini character effect (auxiliary effect). Next, the effect control microcomputer 121 selects the effect symbol EZ to be finally stopped and displayed in the variable effect (S2102). And, based on the analysis result of the fluctuation start command, the fluctuation production pattern which is the contents of fluctuation production is selected (S2103). Once the variable production pattern is determined, the time of the variable production, the variable display mode of the production pattern, the presence or absence of the reach production, the content of the reach production, the presence or absence of the suggestion production that suggests the set value, the content of the suggestion production, the SW production (production button production ), the content of the SW effect, the structure of the effect development, the type of the background of the effect pattern, and the like.

Subsequently, the effect control microcomputer 121 performs a notice effect selection process (S2104). As a result, the content of the notice effect such as a so-called step-up notice effect or a chance-up notice effect is determined. Next, drive data setting processing for setting drive data according to the selected variation effect pattern is executed (S2105).

After that, the production control microcomputer 121 sets the selected production pattern, the variable production pattern, and the variable production start command for starting the variable production with the advance notice production to the output buffer of the production RAM 124 (S2106), The production start process (S1420) is ended. When the variable effect start command set in step S2106 is transmitted to the image control board 140, the image CPU 141 of the image control board 140 reads out a predetermined effect image from the image ROM 142 and displays it on the image display device 50. A variable effect is performed on the screen 50a.

[Auxiliary production start process: FIG. 45] In the auxiliary production start process (S1421), the production control microcomputer 121 first analyzes the variation start command (S2201). The variation start command includes information on the variation pattern (see FIG. 16), information on the special stop symbol data based on the determination of the big hit, etc., and detailed effect pattern information on the mini character effect (auxiliary effect). . In the auxiliary effect start process (S1421), the currently set mini character type (MK1 to MK5), mini character lines (MS1, MS2 etc.), action patterns of the mini-character (action pattern A to action pattern E), and mini-character points MP are determined. The number of mini-character points MP to be given is determined by a lottery result based on various determination tables shown in FIG. 46, which will be described later. Then, as shown in FIGS. 48A to 48D to be described later, the cumulative value of mini character points MP is displayed on the upper left of the auxiliary effect display area MH, so that the current mini character points MP can be confirmed. At the same time, the player can guess the setting value of the gaming machine from the cumulative value of the mini character points MP. Since the initial value of the mini-character point MP is "0000", "0000" is displayed when the condition for resetting the mini-character point MP is satisfied.

The effect control microcomputer 121 first analyzes the variation start command (S2201), and executes the mini character effect by determining detailed effect pattern information regarding the mini character effect (auxiliary effect) included in the change pattern information. (S2202). Then, if the mini-character-related effect pattern information indicating that the mini-character effect is to be executed is included, the process proceeds to the next step S2203.

First, in the mini character selection process (S2203), when the set value is 1 to 3, the first mini character determination table shown in FIG. In the case of , the second mini-character determination table shown in FIG. 46B is used to select the type of mini-character to be displayed from five types of characters A to E. FIG. In this embodiment, character E can be selected in the second mini-character determination table, but character E cannot be selected in the first mini-character determination table. Therefore, by adopting such distribution, it is determined that the setting value of the gaming machine displaying the character E is 4 or more. In addition, although the point multiplier for characters A, B, and C that can be selected is the same at 1.0, character D is 2.0 and character E is 3.0, which are the multipliers at the time points are obtained. is different. As a result, points tend to increase more easily in the second mini-character determination table, in which character D (high setting suggestive character) and character E (high setting confirmation character) are generally more likely to be selected. there is

Subsequently, in the mini character dialogue selection process (S2204), when the setting value is 1 to 3, the first mini character dialogue determination table shown in FIG. In the case of 4 to 6, the content of the character announcement effect MS to be displayed (the mini character's dialogue content and type (character color)) is selected by lottery using the second mini character dialogue determination table shown in (D) of FIG. do. At this time, when the white character notice is selected, one line is selected from the message group classified as the white character notice and displayed. As an example of the white character notice, the pattern of the character notice effect MS "get 1 point (MS1)" as shown in FIG. 48(C) is included. Similarly, as an example of a message classified as a red character notice, there is a character notice effect MS pattern of "get 5 points (MS2)" as shown in FIG. 48(D). Although there are many other kinds of dialogues of the character announcement effect MS, the explanation is omitted. In the present embodiment, rainbow characters can be selected in the second mini-character dialogue determination table, but rainbow characters cannot be selected in the first mini-character determination table. Therefore, by adopting such allocation, it is determined that the setting value is 4 or more in the gaming machine on which the rainbow character (high setting confirmed character notice) is displayed. In addition, the types of lines (character colors) that can be selected are: the second mini-character line-decision table has a larger number of points to be added than the first mini-character line-decision table; There is a tendency that characters (high setting suggestive character advance notice) and rainbow characters (high setting confirmed character advance notice) are likely to be selected. Therefore, when mini-character lines are executed, points tend to increase more easily in the second mini-character determination table.

Subsequently, in the mini-character action pattern selection process (S2205), when the setting value is 1 to 3, the first action pattern determination table shown in FIG. is 4 to 6, using the second action pattern determination table shown in (F) of FIG. Select from four types of C and operation pattern D. In this embodiment, the motion pattern D can be selected in the second motion pattern determination table, but the motion pattern D cannot be selected in the first motion pattern determination table. Therefore, by adopting such allocation, it is determined that the setting value of the game machine displaying the operation pattern D is 4 or more. The types of mini-character motion patterns (action patterns) that can be selected are motion pattern B, motion pattern C, motion pattern C, motion pattern B, motion pattern C, etc., which have a larger number of points to be increased in the second motion pattern determination table than in the first motion pattern determination table. D tends to be more likely to be selected. Therefore, when the mini-character action effect is executed, points tend to increase more easily in the second action pattern determination table.

Subsequently, in mini character point update processing (S2206), mini character points are updated according to the lottery results of mini character selection processing (S2203), mini character line selection processing (S2204), and mini character movement pattern selection processing (S2205). . In this mini character point update process, the point multiplier set according to the type of character selected in the mini character selection process (S2203) is used as a reference, and the increase points determined in the mini character dialogue selection process (S2204) and , the current mini-character points are updated by multiplying the total value of the increased points determined in the mini-character action pattern selection process (S2205) by the point multiplier as the added value of the mini-character points MP. For example, when the type of the selected mini-character is "Character A: Magnification 1.0", the color of the dialogue is "White notice: 1 point" and the action pattern is "Action pattern A: 1 point". If so, add 2 points total. Similarly, when the type of the selected mini-character is "Character E: Magnification 3.0", "Rainbow character notice: 100 points" is selected for the dialogue color, and "Movement pattern E: 100 points" is selected for the movement pattern. 600 points increase in total. By doing so, a gaming machine that has acquired high points despite the fact that the number of variable games played is small can have a sense of expectation that the set value is set high. .

Subsequently, in the mini character point update process (S2206), if the set value is 1 to 5, the first status information update table shown in FIG. , the possessed item (status information FA), and the color of the frame area YR. On the other hand, when the set value is 6, the second status information update table shown in (H) of FIG. Change the color of the frame region YR. The second status information update table has lower threshold values for clothing set C and clothing set D than in the first status information update table. Furthermore, clothing E is set only in the second status information update table. By doing so, when the high setting (6) is set, the clothing set C and the clothing set D are easily selected even if the number of games is small. It can be inferred that the number of games is set to high (6). Also, since the clothing set E is selected only when the high setting (6) is selected, it is determined that the set value is 6 when the clothing set E is selected.

In addition, in the mini-character point update process (S2206), the color of the frame area YR is changed according to the cumulative value of the mini-character points. For example, when the set value is 1 to 5, the color of the frame region YR is changed in the first status information update table. In the first status information update table, the color of the frame region YR is changed from a blue frame (second frame region YR2, first normal frame image) to a red frame (third frame region YR3, second normal frame image). The mini character points required to be changed are 6000 or more. On the other hand, when the setting value is "6", the color of the frame region YR is changed in the second status information update table. In this second status information update table, the frame area is changed from a red frame (third frame area YR3, second normal frame image) to a gold frame (fourth frame area YR4, special frame image). The required mini character points are 3000 or more. That is, in the case of the high setting (6), compared with other setting values, the red frame (the third frame region YR3, the red frame (the third frame region YR3, second normal frame image) to a gold frame (fourth frame region YR4, special frame image). Therefore, it is possible to estimate the set value by paying attention to the relationship between the numerical value of the accumulated points and the color of the frame region YR.

Subsequently, in step S2207, the selected mini-character type (MK1 to MK5), mini-character dialogue type (MS1, MS2, etc.), mini-character movement pattern type (movement pattern A to movement pattern D), and mini-character clothing. And the auxiliary effect start command for starting the auxiliary effect such as items is set in the output buffer of the effect RAM 124 (S2106), and the auxiliary effect start process (S1421) is ended.

[Variation number display update process: FIG. 47] In the variation number display update process (S1423), the effect control microcomputer 121 first analyzes the variation stop command (S2301) and updates the value of the variable game number counter 128 in the effect RAM 124. +1 update (S2302). Subsequently, the effect RAM 124 executes a variable game number counter storage process (S2303) for storing the updated value of the variable game number counter 128 in the game history information storage area 129, and updates the variable game number display contents (S2304). ). As a result, the display number of the variable game number images displayed in the variable game number display area HR shown in FIGS. becomes.

Here, the display mode of the mini character effect (auxiliary effect) according to the present embodiment will be described with reference to FIG. As shown in FIG. 48(A), the auxiliary effect display area MH is provided with a frame area portion YR in a portion forming the outline of the auxiliary effect display area MH. An auxiliary effect display area MH is provided inside this frame area, and a mini character effect can be executed in this display area. The action pattern of this mini-character effect displays the action image of the mini-character drawn by lottery in the mini-character action pattern selection process (S2205) described later. In addition, in this embodiment, the color and shape of the frame region portion YR are the first frame region portion YR1 (white frame, frame image at reset) having a white frame portion as shown in FIG. A second frame region portion YR2 (blue frame, first normal frame image) having a blue frame portion as shown in (B), and a third frame region portion having a red frame portion as shown in FIG. 48(C) Four types are provided: YR3 (red frame, second normal frame image), and fourth frame region portion YR4 (golden frame, special frame image) having a gold frame portion as shown in FIG. 48(D). The details of the change in the color of the frame region YR will be described later.

In the auxiliary effect display area MH, only mini characters are displayed as shown in FIGS. 48(A) and (B), and in addition to mini characters as shown in FIGS. There may be cases where a notice effect is performed with letters. When this character announcement effect (MS1, MS2) is performed, characters are displayed in the mini-character serif display area MSR, and the color of the characters and the color of the mini-character serif display area MSR are interlocked. It can be changed to gold or rainbow color. Then, in the mini-character dialogue display area MSR, the dialogue of the mini-character drawn by lottery in the mini-character dialogue determination process (S2204), which will be described later, is displayed in a predetermined color determined by lottery. In this embodiment, the types of mini-characters displayed are character A ((A) in FIG. 48, first mini-character image MK1), character B ((B) in FIG. 48, second mini-character image MK2), and character C. In addition to ((C) and (D) in FIG. 48, third mini-character image MK3), there are character D (fourth mini-character image MK4) and character E (fifth mini-character image MK5), which are not shown. There are 5 types. Also, during execution of the mini-character presentation, there are cases where mini-character lines, which will be described later, are displayed, and there are cases where the mini-characters perform actions according to a predetermined action pattern, but the detailed action contents of the mini-characters are not shown.

Also, in the auxiliary effect display area MH, a mini character point MP is displayed at the upper left as shown in FIGS. 48(A) to (D). As shown in FIG. 48A, when the mini-character reset is performed, the value of the mini-character points MP is reset and the reset image MP1 "0000" is displayed. On the other hand, when the information was continuously displayed last time, the mini-character continuous display image MP2, which is "0513" in the present embodiment, is displayed as shown in FIG. 48B. Also, as shown in (C) and (D) of FIG. 48, as the mini-character point MP increases, the value of this mini-character point MP is updated to MP3, MP4, and the like.

Also, each mini-character changes its clothes and possessed items (status information FA) according to the cumulative value of mini-character points MP. Specifically, five types of "clothes A set (FA1)", "clothes B set (FA2)", "clothes C set (FA3), "clothes D set (FA4), and "clothes E set (FA5)" are set. It is

FIG. 48A is an example of a display mode when the mini character information reset display process (S1905) is executed in the mini character presentation process 1 at power-on (S1416). In this display example, the character A (MK1) is selected and the mini character point MP is displayed as "0000 (initial value)". When the mini character point is "0000 (initial value)", the first status information update table (see FIG. 46(G)) and the second status information update table (see FIG. 46(H)) In both cases, the type of clothes/item is "Clothes A set (FA1)", and the color of the frame area YR is "white". Part YR1) is displayed. Therefore, when the display mode as shown in FIG. 48A is selected, the setting change operation is performed by the hall clerk, or the RAM clear operation is performed, and the mini character information is displayed. (YES in S1904). Accordingly, the player plays the game expecting that the setting change operation has been performed by seeing the reset display mode as shown in FIG. 48(A).

Next, in the case of FIG. 48B, it is a display example when the character B (MK2) is selected and the mini-character point MP is "0513" points. Scenes in which such a display mode is displayed are when the mini character point MP reaches "0513" points when the player plays a game, and when the mini character point MP has already reached "0513" points. It is conceivable that the previous information continuation display process (S1906) is executed in the process of the mini character effect process 1 at startup (S1416). Then, when the value of the mini character point MP is "0513", both the first status information update table (see FIG. 46(G)) and the second status information update table (see FIG. 46(H)) , the type of clothes/items is "Clothes B set (FA2)" and the color of the frame area YR is "blue", so the clothes B set (FA2) is equipped and the blue frame (second frame area YR2) will be displayed. Here, when a visitor sees such a display mode, since the previous day's information (previous information) is continuously displayed, the game machine may be left unattended with the previous day's settings. will have to guess. Therefore, when the player sees the image display mode as shown in FIG. 48B, the player plays the game expecting the previous day's set values to remain unchanged.

Next, FIG. 48(C) is a display example when the character C (MK3) is selected and the mini character points are "6666" points. Scenes in which such a display mode is displayed are when the mini character point MP reaches "6666" points when the player plays the game, and when the mini character point MP has already reached "6666" points. It is conceivable that the previous information continuation display process (S1906) is executed in the process of the mini character effect process 1 at startup (S1403). In this display example, if the setting is in the range of 1 to 5, it is determined by the first status information update table (see (G) in FIG. 46), so "6666" is in the range of "6000 to 7999". becomes. In this case, "clothes set D (FA4)" and a red frame (third frame area YR3) are displayed. On the other hand, if the setting is 6, in the case of the second status information update table (see (H) in FIG. 46), "6666" is "5000 or more", so "clothes E set (FA5) , and a gold frame (fourth frame region YR4) should be selected. That is, in the case of the display mode as shown in FIG. 48C, the latter case of setting 6 is denied, and it is possible to guess that setting 1 to 5 are used. Here, when a visitor sees such a display mode, since the previous day's information (previous information) is continuously displayed, the game machine may be left unattended with the previous day's settings. will have to guess.

Next, in the case of (D) in FIG. 48, the mini character point is displayed as "3333", and the "clothes D set (FA4)" and gold frame (fourth frame area YR4) are displayed. there is Scenes in which such a display mode is displayed are when the mini character point MP reaches "3333" points when the player plays the game, and when the mini character point MP has already reached "3333" points. It is conceivable that the previous information continuation display process (S1906) is executed in the process of the mini character effect process 1 at startup (S1416). In this display example, if the setting is in the range of 1 to 5, it is determined by the first status information update table (see (G) in FIG. 46). The C set (FA3) should be selected, and the blue frame (second frame region YR2) should be selected as the frame color. However, in (D) of FIG. 48, "clothes set D (FA4)" and a gold frame (fourth frame area YR4) are displayed. That is, in the case of the display mode as shown in FIG. 48(D), the former cases of settings 1 to 5 are denied, and the setting 6 can be assumed. Here, when the visitor sees such a display mode, the previous day's information (previous information) is continuously displayed, so it is assumed that the game machine is left as it is with the previous day's settings. Not only do you make guesses, but you play the game with great expectations that the setting is 6.

By updating the status information FA based on the details of the auxiliary effect using the mini-characters and the cumulative history information of the game, and by changing the clothes/items of the character and the frame area YR, the player and Visitors can be used as judgment materials for inferring settings. In addition, by checking the character's clothing and possessed items (status information FA) at the time the hall starts operating, it can be used as a judgment material for estimating the possibility that the setting has been changed.

Next, the variation number display mode of the present embodiment will be described with reference to FIGS. 49 and 50. FIG. As shown in FIGS. 49 and 50, the display screen 50a of the image display device 50 is provided with a variation game number display area HR in the upper right area of the display screen 50a. , the player can be notified by displaying the variable game number display image HS. (A) of FIG. 49 is a display mode displayed when the normal variable game number display mode (white) is selected in the determination of step S1607 in FIG. 36 (NO in the determination of S1608). be. In the normal variable game number display mode HR1, the variable game number display area HR is displayed in white, and the variable game number display image HS1 (reset display image) at the time of resetting the variable game number display image HS is displayed. (B) of FIG. 49 may be displayed when the first special display mode (blue) is selected in the determination of step S1607 of FIG. 36 (YES in the determination of S1608). This is the display mode. In the first special display mode HR2, the variable game number display area HR is displayed in blue, and the variable game number display image HS1 (reset display image) at the time of resetting the variable game number display image HS is displayed. (C) of FIG. 49 may be displayed when the second special display mode (red) is selected in the determination of step S1607 of FIG. 36 (YES in the determination of S1608). This is the display mode. In the second special display mode HR3, the variable game number display area HR is displayed in red, and the variable game number display image HS1 (reset display image) at the time of resetting the variable game number display image HS is displayed. FIG. 50A shows a display mode that may be displayed when the special display mode (gold) is selected in the determination in step S1607 of FIG. 36 (YES in S1608). is. In the special display mode HR4, the variable game number display area HR is displayed in gold, and the variable game number display image HS1 (reset display image) at the time of resetting the variable game number display image HS is displayed.

As described above, in the present embodiment, even when the number-of-variable-games display image HS is "0000", that is, the number-of-reset-time-variable-games display image HS1 indicating that it has been reset is displayed. When displaying the normal variable game number display mode HR1 as shown in (A), and when displaying the first special display mode HR2 as shown in (B) of FIG. There are cases where the special display mode HR3 is displayed, and there are cases where the special display mode HR4 as shown in FIG. 50A is displayed. The display mode of these variable game number display areas HR is determined by the lottery table different for each setting shown in FIG. 40 in the reset display mode lottery process in step S1607 of FIG. Therefore, the higher the setting (the closer the set value is to "6"), the easier it is to display the special display modes (the first special display mode HR2, the second special display mode HR3, and the special display mode HR4). Conversely, the lower the setting (the closer the set value is to "1"), the easier it is to display the normal variable game number display mode HR1, and the special display mode (first special display mode HR2, second special display mode HR3, special display mode). Mode HR4) is less likely to be displayed. With this configuration, the visitor can not only change the setting of the gaming machine but also guess the current set value from the display mode of the variable game number display area HR. A game can be played by positively selecting a game machine that seems promising.

FIG. 50B shows a case where NO is selected in the determination in step S1605 of FIG. This is a display example when the first special display mode HR2 is selected as the number-of-games display area HR. (C) of FIG. 50 shows a case where NO is selected in the determination in step S1605 of FIG. This is a display example when the special display mode HR4 is selected as the display area HR. Even if the continuous display of the variable game number is selected in this way, for example, as shown in FIG. , since the visitor can guess that the previous set value is likely to be set to "5" or "6", the variable game number display image HS1 at reset (reset display image ) is not displayed, the operation of the game machine does not decrease. Of course, because the previous set value was "5" or "6", even if the special display mode HR4 as shown in FIG. In addition, even if the first reset lottery process succeeds in taking over the variable display number information from the previous time, the same display mode may be selected. It is possible to obtain a new enjoyment of selecting a game machine and playing a game while guessing.

In this way, the color of the variable game number display area HR is the normal white frame (normal variable game number display mode HR1) and the special display mode (first special display mode HR2, second special display mode HR3). , or the special display mode HR4), the visitor can enjoy the new pleasure of guessing the setting change operation, reset operation, and current setting value of the game machine. can be done.

Then, as in the present embodiment, by confirming the respective display modes of the variable game number display area HR and the auxiliary effect display area MH, the visitor can change the settings of the gaming machine, perform the reset operation, and perform the current operation. A new pleasure of guessing the setting value can be obtained.

10. Effect of the present embodiment As described above in detail, in the pachinko game machine PY1 of the present embodiment, a game machine having a setting function, when a setting change operation is performed when the power is turned on, when a RAM clear operation is performed, or
Depending on whether the setting change operation and the RAM clear operation are not performed, a lottery is performed as to whether or not to take over the performance contents (game history information) saved at the time of the previous power shutdown. Therefore, by guessing whether or not the setting has been changed, the visitor can play the game while guessing the setting of the game machine to be played from now on or the game machine already playing the game.

11. Modifications Modifications will be described below. In the description of the modified example, the same reference numerals are assigned to the same configurations as those of the pachinko game machine PY1 of the above configuration, and the description thereof is omitted. Of course, the configurations according to the modified examples may be combined as appropriate. Moreover, technical features in the above embodiments and modifications below can be deleted as appropriate unless they are described as essential in this specification.

Further, in the above-described embodiment, the pachinko game machine is configured to be controlled to a jackpot game state (special game state) under the control condition that a special symbol indicating that a jackpot has been won and a special symbol indicating that has been stopped is displayed. On the other hand, it may be configured as a slot machine (rotary type game machine, pachislot game machine).

Also, the type of the slot machine may be any type as long as it is a game machine whose settings can be changed. In the case of a so-called normal machine (type A slot machine) that increases the number of medals obtained by winning a big bonus or regular bonus, the state in which the big bonus or regular bonus is executed corresponds to the special game state. In addition, if it is a so-called ART machine or AT machine that increases the medals acquired during a special game period such as ART (Assist Replay Time) or AT (Assist Time) that can frequently win small roles, the state during ART or AT corresponds to the special game state.

In the above-described embodiment, in the mini-character effect processing 1 (S1416) at power-on shown in FIG. 41, the effect control microcomputer 121 first confirms whether or not there is a setting change operation (S1901) and whether or not there is a RAM clear operation (S1902). , it is determined whether to perform the mini character reset lottery process (S1903) or to perform the previous information continuous display process (S1906). This may be changed to mini-character effect processing 2 (S1416') at power-on as shown in FIG. In the mini character effect processing 2 at power on (S1416'), the effect control microcomputer 121 confirms whether there is a setting change operation (S1901') or not (S1902'). However, if the value of the setting change flag 127 is "1" (YES in S1901') and if the value of the RAM clear flag 125 is "1" (YES in S1902'), the first mini character While performing the reset lottery process (S1903'), if the value of the setting change flag 127 is "0" (NO at S1901') and if the value of the RAM clear flag 125 is "0" (at S1902' NO) differs in that the second mini character reset lottery process (S1904') is performed. Then, in the following step, if YES in the determination of whether the mini character information reset has been won (S1905'), the mini character information reset display process (S1906') is executed. If the determination (S1905') is NO, the previous information continuation display process (S1907') is executed.

In the first mini character reset lottery process (S1903'), determination is made using the first setting change mini character reset table shown in FIG. 52(A). In this first setting change mini-character reset table, the range of determination values for resetting mini-character information is 0 to 99, whereas the determination value for continuous display of previous information is not set. Therefore, it is distributed so as not to win the continuous display of the previous information. In other words, when the settings are changed, the mini character information is always reset. On the other hand, in the second mini character reset lottery process (S1904'), determination is made using the first no setting change mini character reset table shown in FIG. 52(B). In this first mini-character reset table without setting change, the range of determination values for resetting mini-character information is 0 to 29, whereas the range of determination values for continuous display of previous information is 30. ~99. That is, when the settings are changed, there is a 30% chance that the mini character information will be reset, and a 70% chance that the previous information will be continuously displayed. If the result of the determination (S1905') as to whether or not you have won the resetting of the mini character information is YES, the reset display processing of the mini character information (S1906') is performed, thereby enabling the display shown in FIG. On the other hand, if the result of the determination of whether or not the mini character information reset has been won (S1905') is NO, the previous information continues to be displayed (S1907'). )I do. Since the previous information continuous display process is the same as the previous information continuous display process (S1906) in FIG. 41, description thereof will be omitted.

In this way, whenever a setting change operation is performed or a RAM clear operation is performed, the mini character information is always reset. be able to. In addition, even if the hall clerk does not perform the setting change operation and the RAM clear operation, even if the sales are performed only by the normal power-on operation, a certain percentage (30% in the above-described embodiment example) is reset, it is possible to reduce the work load of the hall clerk. In addition, regardless of the setting value, the mini-characters are reset at a constant rate, so that the visitor does not have to make complicated guesses and can play the game expecting the setting change.

Also, in the first mini character reset lottery process (S1903') in the power-on mini character effect process 2 (S1416'), (A) the first setting change mini character reset table (a lottery table that always wins the reset) in FIG. On the other hand, in the second mini character reset lottery process (S1904'), the mini character reset table without first setting change (B) in FIG. 52 was used. In the first mini character reset lottery process (S1903'), the mini character reset table at second setting change (C) in FIG. 52 is adopted, while in the second mini character reset lottery process (S1904'), D) The second setting may be changed to a mini character reset table without change (a table that always wins the continuous display of the previous change information).

In the second setting change mini character reset table shown in FIG. The range of values is 30-99. That is, when the settings are changed, there is a 70% chance that the mini character information will be reset, and a 30% chance that the previous information will be continuously displayed. In the second no-change mini-character reset table shown in (D) of FIG. 52, the range of determination values for resetting the mini-character information is not set. On the other hand, the range of determination values is 0 to 99 in the case of continuous display of the previous information. By doing so, when the setting is changed, there is a 70% probability that the mini character information will be reset, but there is a 30% probability that the previous information will continue to be displayed. Also, if the settings are not changed, the mini character information is not reset, and the previous information can be continuously displayed with a probability of 100%.

With this configuration, when the setting change operation is not performed and the RAM clear operation is not performed, in other words, when only the normal power-on operation is performed, the continuous display of the previous information is always inherited. can be made Then, even when the setting change operation is performed and the RAM clear operation is performed, the previous variable display number information is inherited at a certain rate (30% in the example of the embodiment described above). By doing this, adjustments can be made to reduce the frequency of mini character information resets. You can play games. In addition, even if the information was continuously displayed last time, it does not mean that the setting change cannot be expected at all.

As in the above embodiment, the mini character reset table when the first setting is changed or the mini character reset table when the second setting is changed, the mini character reset table when the first setting is not changed, or the mini character reset table when the second setting is not changed. Thus, by providing two mini-character reset tables for when setting is changed and when setting is not changed, the reset ratio of mini-character information can be changed when setting is changed or when setting is not changed. In this embodiment, the mini character reset tables are provided separately for when the settings are changed and when the settings are not changed. In each case, a lottery may be conducted using a mini character determination table corresponding to each set value.

In the above embodiment, in the first reset lottery process (S1603) in FIG. 37, the second reset lottery process (S1604) in FIG. 38, and the mini character reset lottery process (S1903) in FIG. For this purpose, a dedicated judgment table was provided. However, when the power is turned on, the continuous display of the previous information and the resetting of the mini character information may be selected by lottery based on the mini character determination table shown in FIG.

Also, in this embodiment, as shown in FIG. 45, the mini character selection process (S2203) is executed in the auxiliary effect start process (S1421), and the mini character can be changed. The mini character selection process (S2203) may be omitted, and the player may select a mini character to his liking by operating the effect button (input unit) 40k and the select button 42k during execution of the demonstration effect. Also, in this case, the types of mini-characters that can be selected according to the set values during the execution of the demonstration effect should be limited to characters A to C only, and the point multiplier should be fixed at 1.0. . Alternatively, characters A to E can be freely selected, while the point multiplier is uniformly set to 1.0. In addition, by making the game machine capable of setting the setting information related to the mini character by inputting the key code, the mini character can be freely selected. By performing the mini character point update process using the process (S2205), it is possible to enjoy the auxiliary game of accumulating mini character points regardless of the player's favorite character.

In the above embodiment, as shown in FIGS. 46A and 46B, a plurality of settings are grouped in the mini character determination table such as "Settings 1 to 3" or "Settings 4 to 6". A table of character types was provided. For each of the settings 1 to 6, a mini character determination table may be provided individually. 46(C) and (D), motion pattern determination tables shown in FIGS. 46(E) and (F), and FIGS. 46(G) and (H). As for the status information update table, a dedicated determination table may be provided for each of the settings 1-6.

In the above-described embodiment, as shown in (G) and (H) of FIG. 46, the cumulative value of mini-character points, the type of clothes/items, and the color of the frame area are linked and can be changed. rice field. Alternatively, the type of clothing/item and the color of the frame area may be selected using individual apportionment values for the cumulative value of mini-character points.

In the above-described embodiment, as shown in FIG. 46, the reset of the mini-character points MP and the reset display of the frame area YR are substantially linked. This may be changed so that the reset determination of the mini character points MP and the reset determination of the frame area YR are performed separately. In this case, for example, even if the mini character points MP are reset and displayed as "0000", the color of the frame area YR that was saved when the power was turned off last time may continue to be displayed. Conversely, even if only the color of the frame area YR is white, the mini character point MP is not reset and the value of the mini character point MP that was saved when the power was turned off last time may remain the same. can be created. As a result, it is possible to diversify and complicate the variations of the mini-character presentation at power-on.

In the above-described embodiment, as shown in FIG. 48, a specific numerical value of mini character points MP is displayed in the auxiliary effect display area MH. Instead of displaying this, it may be possible to change the type of clothing to vaguely suggest accumulated points, such as clothing set A to clothing set E. Further, the accumulated points may not only be displayed as points as they are, but may also be displayed in expressions such as experience points and levels, imitating a role-playing game or the like.

In the above-described embodiment, the first to sixth reset tables are used as a lottery when the settings are changed in the power-on variable game number reset process 1 (S1415) in FIG. Seventh to twelfth reset tables are provided as a lottery in the event that no is performed, and reset tables corresponding to the respective set values are provided. By changing this, some or all of the reset tables may be used as common distribution values. Alternatively, one determination table may be used in common both when the setting is changed and when the setting is not changed.

For example, the variable game number reset process 1 (S1415) upon power-on shown in FIG. 36 may be changed to the variable game number reset process 2 (S1415') upon power-on shown in FIG. This modification differs in that the first reset lottery process in step S1603 is changed to the reset determination of the number of variable games (S1603').

In the variable game count reset process 2 (S1415') at power start-up, first, the effect control microcomputer 121 confirms that the value of the setting change flag 127 is "1" (S1601). When the value of the setting change flag 127 is "1" (YES in S1601), it is determined to reset the number of variable games (S1603'). On the other hand, if the value of the setting change flag 127 is "0" (NO in S1601), the value of the RAM clear flag 125 is checked (S1602). Here, if the value of the RAM clear flag 125 is "1" (YES in S1602), it is determined to reset the number of variable games (S1603'). On the other hand, when the value of the RAM clear flag 125 is "0" (NO in S1602), the second reset lottery process (S1604) is performed. The subsequent processing is the same as the variable game count reset processing 1 at power-on (S1415), so description thereof will be omitted.

In this way, when the RAM clear operation is performed and when the setting change operation is performed, the variable number of games may be reset without conducting a lottery for resetting the variable number of games. Also, in this modified example, the first reset lottery process of step S1603 is changed to the reset decision of the variable game number (S1603'), but the second reset lottery process of step S1604 is changed to the reset decision of the variable game number (S1604'). can be changed to

In the above embodiment, in the first reset lottery process (S1603) in FIG. 37, the second reset lottery process (S1604) in FIG. 38, and the mini character reset lottery process (S1903) in FIG. For this purpose, a dedicated judgment table was provided. However, these may be divided into two setting value groups such as settings 1 to 3 and settings 4 to 6, for example. In that case, a determination table or the like that always wins the reset lottery may be used.

In the above-described embodiment, as shown in FIGS. 49A to 49C and FIG. 50A, at the time of resetting, the variable game number display image at reset (“0000”, reset display image) It displayed HS1. When the variable game number information from the previous time is taken over, the variable game number information continuous display image HS2 (continuous display image) is displayed. Instead, at the time of resetting, without displaying "0000", numbers unrelated to the number of previous variable games, special numbers such as "0777 (three seven)" and "0758 (Nagoya)" (number notice image) may suggest that the setting has been changed or suggest that the setting is high. In this case, the contents of the reset display mode lottery process in step S1607 of the power-on variable game count reset process 1 in FIG. 36, the first reset display mode lottery table shown in FIG. Table, 3rd reset display mode Instead of the lottery for the color of the variable game number display area HR performed in the lottery table, special variable game number display images (such as "0777 (three seven)", "0758 (Nagoya)", etc.) number) may be selected by lottery.

In the above-described embodiment, the variable game number reset processing 1 (S1415) at power startup shown in FIG. 36, mini character effect processing 1 (S1416) at power startup shown in FIG. In process 2 (S1403'), reset process 1 (S1402') for resetting the number of variable games at power-on shown in FIG. there were. This may be changed so that the determination of the setting change flag 127 is performed after the determination of the ram clear flag 125 is performed first. Further, in this embodiment, both the determination for confirming the RAM clear flag and the determination for confirming the setting change flag 127 are performed. However, this may be changed so that only the determination for confirming the RAM clear flag 125 or only the determination for confirming the setting change flag 127 may be performed. In particular, in a general game machine, when a setting change operation (including switching to the same setting) is performed, the game RAM 104 of the game control board 100 and the effect control Since the information corresponding to the reset setting value is reset after both of the effect RAMs 124 of the board 120 are initialized, the determination of the RAM clear flag 125 may be omitted only by the determination of the setting change flag 127.

In the above-described embodiment, as game history information, variable game number information, mini character information, and the like are given as examples of game history information. However, it is not limited to these, and may be related to the game history determined based on the game results. For example, the number of executions of the jackpot, the number of executions of the probability variation and time reduction, etc., the number of consecutive occurrences of the jackpot, probability variation, and time reduction, the contents of the production mode that can be executed during the probability variation and time reduction, the game time, the number of acquired game balls, the game ball Any history information related to the game such as the number of shot balls can be employed as the game history information of the present embodiment.

In the above-described embodiment, lotteries such as the variable game count reset process 1 (S1415) at power start-up and the mini character effect process 1 (S1416) at power start-up were always executed when the power was turned on. These are changed, and the hall clerk performs setting change operations such as reset processing 1 for the number of variable games when the power is turned on (S1415), mini character production processing 1 when the power is turned on (S1416), effects related to the reset operation, or settings suggestion effects. It may be possible to select invalidation of the effect related to . Alternatively, it may be possible to customize not only the selection of invalidation but also the occurrence rate of the reset lottery (distribution such as the range of judgment values in the judgment table) by specialized operation by the hall clerk.

In addition, the variable game count display area HR provided on the display screen 50a and the frame area YR provided in the outline of the auxiliary effect display area MH may be always displayed on the display screen 50a, or may be displayed on the display screen 50a at all times. It may be in a non-display state when executing a predetermined effect such as an effect or a big win effect. In addition, the display location may be moved without being limited to the positions shown in the drawings of the present embodiment, or deformation such as enlargement or reduction may be performed. Alternatively, an image display device 50X different from the image display device 50, which is called a sub-liquid crystal, is newly provided in the game board or the game machine frame, and the sub-liquid crystal has a variable game number display region HR and a frame region YR. Even when the player is not playing a game such as during execution of a waiting demonstration, the game is always displayed on the image display device 50 or the image display device 50X so that the player can select a game machine while looking at the variable game number information. can do. Alternatively, an image may be added with an effect image behind the numbers without providing a "frame" such as the variable game number display area HR or the frame area YR.

12. Inventions Shown in the Above-described Embodiments The above-described embodiments show inventions of the following means. In the description of the means described below, the corresponding structural names and expressions in the above-described embodiments and the reference numerals used in the drawings are added in parentheses for reference. However, the constituent elements of each invention are not limited to this appendix.

<Means A>
The invention according to means A1 is
In a gaming machine (PY1) equipped with a game control means capable of setting any one of a plurality of set values with mutually different jackpot determination probabilities,
game history information display means (a production control microcomputer 121 for displaying the variable game number information in the variable game number display area HR) capable of displaying the game history information (variable game number information) held in the gaming machine;
Initialization lottery means (S1415 in FIG. 36, effect control microcomputer 121 for executing variable game count reset process 1 at power startup) for lottery for determining whether or not to initialize the game history information at power startup. It is a gaming machine characterized by

According to the gaming machine with this configuration, by performing a so-called "RAM clearing operation", even if an operation for resetting the information about the game is not performed, according to the lottery result of the initialization lottery means when the power is turned on, when the power is turned off. It is possible to reset the stored predetermined effect content. By doing so, the player can play the game with a sense of expectation that the setting of the gaming machine has been changed.

The invention according to means A2 is
The gaming machine described in A1, when the power is activated with a setting change operation (YES in S1601 of FIG. 36), or when the power is activated with a reset operation (YES in S1602 of FIG. 36), or without these When the power is started (NO in S1602 in FIG. 36), the game history information is initialized at a different rate (the effect control microcomputer 121 that executes the first reset lottery process S1603 or the second reset lottery process S1604). It is a gaming machine characterized by

According to the gaming machine with this configuration, even if the game history information is not reset by performing a so-called "RAM clearing operation", the state is reset according to the lottery result of the initialization lottery means when the power is turned on. can be used as a game machine. By doing so, the player can play the game with a sense of expectation that the setting of the gaming machine has been changed.

The invention according to means A3 is
In the gaming machine described in A2, the ratio of initializing the game history information is set corresponding to each of the plurality of setting values (for each setting of (A) to (L) in FIG. 39). This is a game machine characterized by a reset table).

According to the gaming machine with this configuration, whether the game history information (variable number of games information) is reset or whether the previous game history information (at the end of business on the previous day) (variable number of games information) is maintained as it is can be determined. By confirming, the player guesses whether or not the setting of the game machine has been changed and guesses the current setting value of the game machine, so that the player can play the game with expectation that the setting of the game machine has been changed. can be done.

The invention according to means A4 is
In the gaming machine according to A1, when power is started with a setting change operation (YES in S1601 in FIG. 54) or when power is started with a reset operation (YES in S1602 in FIG. 54), the game history Information is initialized (S1603′ in FIG. 54), while the setting change operation and the power supply startup without the reset operation (NO in S1602 in FIG. 54), the game history information is not initialized (the effect control microcomputer 121 that performs the second reset lottery process S1604).

According to the gaming machine with this configuration, when the power is turned on with a setting change operation or when the power is turned on with a reset operation, the game history information (variable number of games information) is always reset. On the other hand, the game history information is not initialized at a predetermined rate when the power is turned on without a setting change operation or a reset operation (as shown in each reset table in FIG. ” is set so that one or more judgment values are always distributed). By doing so, when the reset operation and setting change operation are performed by the hall clerk, the game history information is always initialized. In the case of a normal power-on that does not involve any operation, at least a certain percentage of the gaming history information (resetting the number of variable games) may not be initialized. A game machine to be played can be selected based on the display mode of information.

The invention according to means A5 is
In the gaming machine described in A4, when the power is turned on without the setting change operation and the reset operation, the rate of non-initialization of the game history information is higher than the rate of initialization (see FIG. 39). In the seventh to twelfth reset tables, the rate of inheriting the previous variable display number information is higher than that of resetting the variable game number).

According to the gaming machine with this configuration, when the power is started without the setting change operation and the reset operation, compared to the rate at which the game history information (variable game number reset) is initialized, the previous variable display number information (percentage of non-initialization) is more likely to be selected. In other words, the game history information is reset by making adjustments so that the game history information is not unnecessarily reset when the power is started without a setting change operation or reset operation, or when the power is normally started. It is possible to increase expectations for the fact that the setting change has been made in the case of

By the way, Japanese Unexamined Patent Application Publication No. 2000-334125 describes a gaming machine that enhances the interest of a player by providing an explanation of game history information of the gaming machine during a jackpot game. However, with such a game machine, although the effect of improving the operation may be obtained for the player who is actually playing the game, it is difficult to decide which machine to play on before playing the game. It was not possible to provide positive judgment materials when making a selection. On the other hand, in the gaming machine of the present embodiment, the game history information may be reset without performing a setting change operation or a so-called "ram-click operation". It is possible to provide information that will be a positive gaming motivation in some cases.

<Means B>
The invention according to means B1 is
In a gaming machine (PY1) equipped with a game control means capable of setting any one of a plurality of set values with mutually different jackpot determination probabilities,
Equipped with production control means capable of controlling production (production control microcomputer 121 for controlling production),
The effect control means is a continuous lottery means (S1416 in FIG. 41) that performs a lottery as to whether or not to take over the predetermined effect contents saved when the power is cut off, with a lottery probability according to the presence or absence of the setting change operation at the time of power startup. , and a microcomputer 121 for effect control that executes a mini character effect process 1 at power-on.

According to the game machine of this configuration, depending on the lottery result of the continuation lottery means when the power is turned on, there is a case where the predetermined performance contents saved when the power is turned off are taken over. Therefore, the visitor and the player can play while guessing that the setting of the gaming machine has been changed or that the setting of the gaming machine has been left as it was the day before.

The invention according to means B2 is
In the gaming machine described in B1, game history information display means capable of displaying game history information (mini character information) held in the gaming machine (for effect control for displaying mini character information in the auxiliary effect display area MH) a microcomputer 121),
The gaming machine is characterized in that the predetermined effect content is the content of the game history information.

According to the gaming machine of this configuration, the game history information display means capable of displaying the game history information is provided, and the game history information saved when the power is cut off is displayed according to the lottery result of the continuation lottery means when the power is turned on. Predetermined performance contents saved at the time of disconnection can be taken over.

The invention according to means B3 is
The gaming machine according to B2, wherein the game history information is updated based on points (mini character points MP) given as the game progresses,
The effect control means changes the display mode of the game history information (miniature character's outfit/item type, color of the frame display part) according to the cumulative value of the points (executes the auxiliary effect start process S1421 in FIG. 45). ) is a game machine characterized by

According to the gaming machine with this configuration, the display mode of the game history information (type of clothes/items, color of the frame display portion) is changed according to the cumulative value of the mini character points MP given as the game progresses. . Therefore, according to the display mode of the game history information, the visitor and the player can intuitively understand whether the game history information is good or bad.

The invention according to means B4 is
The gaming machine described in B3, comprising point number display means capable of displaying the cumulative value of the points (effect control microcomputer 121 for displaying mini character points MP in the auxiliary effect display area MH in FIG. 48). It is a gaming machine characterized by

According to the gaming machine with this configuration, by displaying the cumulative value of the points awarded as the game progresses as an actual numerical value, visitors and players can grasp the quality of the game history information in more detail. can do. In addition, it is possible to more accurately guess the set value of the gaming machine according to the combination of the displayed point value, the mini character's clothing/item type, and the color of the frame area.

The invention according to means B5 is
In the gaming machine according to any one of B1 to B4, the continuation lottery means performs a lottery as to whether or not to take over the predetermined effect content at a first lottery probability when the power source is started with the setting change operation. (the effect control microcomputer 121 that executes the first mini character reset lottery process S1903' in FIG. 51). This game machine is characterized in that a lottery is performed to determine whether or not (the effect control microcomputer 121 that executes the second mini-character reset lottery process S1904' in FIG. 51).

According to the gaming machine with this configuration, a lottery is conducted to determine whether or not the cumulative value of the mini character points MP is to be inherited as it is, depending on whether the power is turned on with a setting change operation or when the power is turned on without a setting change operation. You can set the lottery ratio for winning. Therefore, the game can be played with a new enjoyment of guessing whether or not the set value has been changed from the last continuation state of the mini character points MP.

The invention according to means B6 is
The gaming machine according to B5,
The continuous lottery means may determine that the predetermined effect content is not inherited in the lottery with the second lottery probability (lottery when the setting is not changed) ((B) in FIG. 52). 1) This game machine is characterized by a production control microcomputer 121) that executes a mini character reset table when there is no setting change.

According to the gaming machine with this configuration, the setting may be reset even if the setting change operation is not performed. Therefore, resetting does not confirm that the setting has been changed, so that visitors and players can enjoy choosing a gaming machine.

By the way, Japanese Patent Application Laid-Open No. 2006-326329 provides a new game feature different from the jackpot game, in which the building character grows every time the number of game balls entering the starting hole reaches a predetermined number. A game machine is described. However, in such a game machine, although it is possible to obtain the effect of increasing the motivation of the player who is actually playing the game, it is necessary to decide which machine to play on before playing the game. It was not possible to provide positive judgment materials when making a selection. On the other hand, the gaming machine according to the present embodiment does not reset the game history information even when the setting change operation or the so-called "ram click operation" is performed, and the predetermined effect saved when the power is turned off. The content may be inherited. Therefore, it is possible to provide information that serves as a positive gaming motivation when visitors and players choose a game machine.

PY1 Pachinko machine 50 Image display device 50a Display screen 100 Game control board 101 Game control microcomputer 120 Production control board 121 Production control microcomputer HR Variable game number display area HS Variable game number display image MH: Auxiliary effect display area MP: Mini character points

Claims (2)

In a gaming machine equipped with a game control means capable of setting one of a plurality of set values with mutually different jackpot determination probabilities,
game history information display means capable of displaying game history information held in the game machine;
an initialization lottery means for lottery for determining whether or not to initialize the game history information when the power is turned on ;
A gaming machine , wherein the game history information is initialized at a different rate when the power is turned on with a setting change operation or resetting operation and when the power is turned on without the resetting operation . In a gaming machine equipped with a game control means capable of setting one of a plurality of set values with mutually different jackpot determination probabilities,
game history information display means capable of displaying game history information held in the game machine;
an initialization lottery means for lottery for determining whether or not to initialize the game history information when the power is turned on ;
While initializing the game history information when power is turned on with a setting change operation or when power is turned on with a reset operation,
The game machine is characterized in that the game history information is not initialized at a predetermined rate when power is started without the setting change operation and the reset operation .

Images