JP7246720B2 - game machine - Google Patents

Description

TECHNICAL FIELD The present invention relates to a gaming machine that determines whether or not to execute a special game, and executes an effect based on the determination result.

In the pachinko game machine, when a game ball enters a predetermined starting hole, it is determined whether or not to execute a special game advantageous to the player. Various effects are performed using an image display means or the like during the variable display of the special symbols for informing the result of this determination (see Patent Document 1, for example).

JP 2017-79840 A

By the way, when adopting a configuration that can change the determination probability determined to execute a special game by an operation, it is necessary to perform appropriate effect control according to this configuration.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a gaming machine capable of performing appropriate effect control.

The present invention employs the following configurations in order to solve the above problems.
A gaming machine according to the present invention is a gaming machine comprising a game control unit for controlling a game and an effect control unit for controlling an effect, wherein the game control unit executes a special game advantageous to a player. Determination means for determining whether or not, and a determination probability that the determination means determines that the special game will be executed according to a predetermined operation using the operation means is one of a plurality of probabilities. setting means for setting a setting value; setting value transmission means for transmitting the setting value set by the setting means at least when the setting by the setting means is completed; and a determination result of the determination means can be transmitted. and a determination result transmission means, and the effect control unit can receive the set value transmitted by the set value transmission means and the determination result of the determination means transmitted by the determination result transmission means. , it is possible to control the effect according to the determination result of the determination means without being based on the set value, and the set value set by the setting means corresponds to one effect among the effects, The possibility of executing the special game is made different.

According to this invention, it is possible to perform appropriate effect control.

Schematic front view of gaming machine 1 Enlarged view of indicator 4 in FIG. A perspective view of the game machine 1 showing a state in which the inner frame 3 and the game board unit 201 are opened with respect to the outer frame 6. Front view showing part of the game board unit 201 seen from the back side Explanatory diagram for explaining the performance indicator 215 mounted on the game control board 100 Front view showing part of board case 210 of game control board 100 Front view showing part of board case 210 of game control board 100 Block diagram showing a configuration example of a control device provided in the game machine 1 An explanatory diagram for explaining various storage areas of the main RAM 103 and stored information. Explanatory diagram for explaining a setting change mode, a setting confirmation mode, a first RAM clear mode, a second RAM clear mode, and a power restoration mode. Explanatory diagram showing features of each mode illustrated in FIG. Explanatory diagram for explaining the flow of the game Explanatory diagram for explaining the setting related to the jackpot probability Explanatory diagram for explaining various random numbers Explanatory diagram for explaining the fluctuation pattern table A screen diagram illustrating the screen configuration of the liquid crystal screen 5 in the normal game state. Explanatory diagram exemplifying the flow of reach production Screen diagram for explaining the zebra effect Explanatory diagram for explaining the execution ratio, appearance rate, and reliability of the zebra effect Explanatory diagram for explaining a zebra effect determination table for determining whether or not to execute a zebra effect. A flowchart showing an example of timer interrupt processing executed in the game control board 100 Detailed flowchart of switch processing in step S2 of FIG. Detailed flowchart of the first start opening switch process in step S21 of FIG. Detailed flowchart of the second start opening switch process in step S22 of FIG. Detailed flowchart of pre-determination processing in steps S218 and S228 of FIGS. Detailed flowchart of special symbol processing in step S3 of FIG. Detailed flowchart of big hit determination processing in step S309 of FIG. Detailed flowchart of variation pattern selection processing in step S310 of FIG. Detailed flowchart of stop processing in step S320 of FIG. Detailed flowchart of game state setting processing performed at the end of jackpot game Flowchart showing an example of timer interrupt processing executed in the effect control board 130 Detailed flowchart of command reception processing in step S50 of FIG. Detailed flowchart of pending command reception processing in step S53 of FIG. Detailed flowchart of the fluctuation start command reception process in step S56 of FIG. Detailed flowchart of the variable effect pattern setting process in step S565 of FIG. Detailed flowchart of the notice effect pattern setting process in step S566 of FIG. Flowchart showing an example of timer interrupt processing executed in the image sound control board 140 Detailed flowchart of image output control processing in step S41 of FIG. Explanatory diagram for explaining another flow of the game Explanatory diagram for explaining other settings related to the jackpot probability Explanatory diagram for explaining other execution ratios, appearance rates, and reliability of zebra effects

Hereinafter, a gaming machine 1 according to an embodiment of the gaming machine of the present invention will be described with appropriate reference to the drawings.

[Example of schematic configuration of gaming machine 1]
First, a schematic configuration of the game machine 1 will be described with reference to FIG. Here, FIG. 1 is a schematic front view of the gaming machine 1. FIG. As illustrated in FIG. 1, the gaming machine 1 includes a game board 2 on which accessories related to winning and judgment are provided, and an inner frame 3 surrounding the game board 2 . The inner frame 3 supports a transparent glass plate arranged parallel to the game board 2 at a predetermined interval, and the glass plate and the game board 2 form a game area 10 in which game balls can flow down. It is

When the player grips the handle 20 and rotates the lever 21 clockwise, game balls stored in the upper tray 28 are guided to a shooting device (not shown), and are played with a hitting force corresponding to the rotation angle of the handle 20. Launched into area 10 . The game area 10 is provided with game nails, windmills, etc. (not shown), and the shot game ball is guided to an upper position in the game area 10, and touches the game nails, the windmills, etc. It falls in the game area 10 along the game board 2 while changing the movement direction. It should be noted that the shooting of game balls is temporarily stopped when the player operates the stop button 22 .

The upper tray 28 stores game balls and prize balls supplied to the shooting device. Below the upper plate 28, a lower plate 29 for storing prize balls is provided. When the player operates the take-out button 23 arranged close to the lower tray 29, a part of the lower surface of the lower tray 29 is opened, and the game balls accumulated in the lower tray 29 are arranged below the lower tray 29. It drops into a box (not shown). In addition, the upper plate 28 and the lower plate 29 may be composed of one plate.

When the player performs so-called "left-handed hitting", in which the player rotates the handle 20 at a small rotation angle, the game ball is launched with a relatively weak hitting force. In this case, the game ball flows down the left area in the game area 10 as illustrated by the arrow 35 . On the other hand, when the player performs a so-called "right-handed hit" in which the player keeps rotating the handle 20 at a large rotation angle, the game ball is hit with a relatively strong hitting force. In this case, the game ball flows down the right area in the game area 10 as illustrated by the arrow 36 .

A first starting port 11, a second starting port 12, two normal winning ports 14, and an electric tulip 17 are provided on the passage path of the left-handed game ball as accessories related to winning and judgment. In addition, on the passage path of the right-handed game ball, there are the second starting opening 12, the big winning opening 13, the two normal winning openings 14, the gate 16, and the electric tulip 17 as accessories related to winning and judgment. is provided.

The game ball launched into the game area 10 enters any one of the first starting hole 11, the second starting hole 12, the big winning hole 13, and the normal winning hole 14 in the process of flowing down along the game board 2. may win prizes. In this case, a predetermined number of prize balls are paid out to the upper tray 28 or the lower tray 29 according to the place where the prize was won. For example, when a game ball enters the first start port 11, four prize balls are paid out, and when a game ball enters the second start port 12, two prize balls are paid out, and the game is played in the big win port 13. When the balls win, 14 prize balls are put out, and when the game balls enter the normal prize winning port 14, 3 prize balls are put out. The game balls that did not win a prize are discharged from the game area 10 through the discharge port 18. - 特許庁

The first starting port 11 is a starting region that is always open, and the second starting port 12 is a starting region that is opened only when an electric tulip 17 as a normal electric accessory is operating. In the gaming machine 1, when the game ball passes through the first start port 11 and wins, or when the game ball passes through the second start port 12 and wins, a jackpot game (special game) advantageous to the player is played. It is determined whether or not to execute, and the symbol indicating the determination result is displayed on the first special symbol display 41 or the second special symbol display 42 of the display 4, which will be described later. Then, when a symbol indicating a big win is stopped and displayed, a big win game for opening the big winning opening 13 is executed.

In the following description, the judgment executed on the condition that the game ball enters the first start port 11 is called "first special symbol judgment", and the condition that the game ball enters the second start port 12. The judgment to be executed is called "second special symbol judgment", and these judgments are collectively called "special symbol judgment".

The big winning opening 13 is a special winning area that is opened according to the result of the special symbol determination. A plate for opening and closing the big winning opening 13 is provided at the opening of the big winning opening 13 . The big winning opening 13 is normally closed by this plate. On the other hand, when a predetermined big winning symbol indicating that the judgment result of the special symbol judgment is "big winning" is stopped and displayed on the display device 4, the big winning game to open the big winning opening 13 by actuating the plate. is executed. During the jackpot game, a large winning opening until a predetermined condition (in this embodiment, 9 game balls enter the big winning opening 13, or 29.5 seconds elapse after the opening of the big winning opening 13) is satisfied. 13 is maintained in an open state and then closed, and is executed a predetermined number of times (5 times or 10 times in this embodiment: see FIGS. 14B and 14C) at predetermined time intervals.

In this way, since the big winning opening 13 is opened for a long time during the big winning game, the player can win more prizes than when the big winning game is not performed by hitting right during the big winning game. You can get the ball.

The electric tulip 17 is arranged close to the second starting port 12 and has a pair of blade members. The electric tulip 17 has a closed posture (see the solid line in FIG. 1) in which the pair of blade members closes the second start port 12, and an open posture in which the second start port 12 is opened (see the broken line in FIG. 1). It is configured to be able to change its posture.

The second starting port 12 is normally closed by an electric tulip 17, as illustrated in FIG. On the other hand, when the game ball passes through the gate 16, it is determined whether or not to open the second starting port 12, although the prize ball is not paid out. Here, when it is determined that the second starting port 12 is to be opened, the pair of blade members of the electric tulip 17 maintain the open posture for a specified time and then return to the closed posture for a specified number of times. In this way, the second starting port 12 is in a state in which it is difficult for the game ball to pass when the electric tulip 17 is not operating, whereas it is in a state in which the game ball can easily pass when the electric tulip 17 is operated. Become.

Incidentally, in the following description, the determination executed on the condition that the game ball passes through the gate 16 is called "normal symbol determination".

The normal winning opening 14 is always open like the first starting opening 11, and is a winning opening from which a predetermined number (three in this embodiment) of winning balls are paid out by winning of game balls. In addition, unlike the first starting hole 11 and the like, even if a game ball enters the normal winning hole 14, no determination is made.

[Configuration example of effect means of game machine 1]
As exemplified in FIG. 1, the game board 2 or the inner frame 3 is provided with a liquid crystal display device 5, a speaker 24, a production accessory 7, a board lamp 25, etc. for performing various effects. Further, the inner frame 3 incorporates a frame lamp 37 (see FIG. 8) not shown in FIG.

The liquid crystal display device 5 is an image display device that displays an effect image, and the display screen of the liquid crystal display device 5 (hereinafter also referred to as "liquid crystal screen 5") is provided at a position that is easily visible to the player. On the liquid crystal screen 5, for example, decorative patterns for notifying the judgment result of the special pattern judgment, characters and items for performing advance notice effects suggesting the reliability of the big win, and the number of reserved special pattern judgments are displayed. An effect image including various display objects such as an icon and the icon suggesting that the special symbols are displayed in a variable manner is displayed. Note that the image display device may be configured by another image display device such as an EL display device.

The speaker 24 outputs musical pieces, voices, sound effects, etc. in synchronization with or asynchronously with the display effects performed on the liquid crystal screen 5 to perform sound effects. Note that the speaker 24 is also used for warning against illegal games, error notification, and the like.

The performance accessory 7 is arranged in front and to the side of the liquid crystal screen 5. - 特許庁The production accessory 7 has a built-in light-emitting element (for example, an LED). The production accessory 7 performs a predetermined production by both or one of the movement of the accessory itself and the light. In this embodiment, the performance accessory 7 is configured in a star-like shape, and is configured to be rotatable with the depth direction of the gaming machine 1 as its axial direction.

The board lamp 25 and the frame lamp 37 perform various effects with light, such as changing the lighting or blinking pattern and changing the emission color.

[Configuration example of input means of gaming machine 1]
As illustrated in FIG. 1, the inner frame 3 is provided with a performance button 26 and a performance key 27 as input means for the player to make an input. The effect button 26 is a push button for inputting operation information when pressed by the player. The effect key 27 is a so-called cross key for the player to perform a selection operation or cursor movement, and is composed of an up key, a down key, a left key, and a right key. In the gaming machine 1, there are cases where an effect corresponding to the operation of the effect button 26 and the effect key 27 is performed.

[Configuration example of display 4]
FIG. 2 is an enlarged view of the display 4 in FIG. The display device 4, as illustrated in FIG. 2, includes a first special symbol display device 41, a second special symbol display device 42, a first special symbol reservation display device 43, a second special symbol reservation display device 44, and a normal design. It is composed of a display device 45, a normal symbol reservation display device 46, a game state display device 47, a round display device 48, and the like.

When the first special symbol determination is performed, the first special symbol display device 41 variably displays the symbol and then stops and displays the symbol indicating the determination result of the first special symbol determination to determine the first special symbol determination. Notify the results. When the second special symbol determination is performed, the second special symbol display device 42 displays the symbol in a variable manner, and then stops and displays the symbol indicating the determination result of the second special symbol determination to determine the second special symbol determination. Notify the results. On the first special symbol display device 41 and the second special symbol display device 42, as symbols indicating the determination result, a big winning symbol indicating "big win" or a losing symbol indicating "losing" are stopped and displayed. be done.

The first special symbol reservation display 43 displays the number of reservations for the first special symbol determination. The second special symbol reservation display 44 displays the number of reservations for the second special symbol determination.

When the normal symbol determination is performed, the normal symbol display 45 notifies the determination result of the normal symbol determination by variably displaying the symbol and then stop-displaying the symbol indicating the determination result of the normal symbol determination. The normal symbol reservation display 46 displays the number of normal symbol determination pending. The game state display 47 displays the game state at the time when the gaming machine 1 is powered on. When the first special symbol display 41 or the second special symbol display 42 stop-displays the jackpot pattern, the round indicator 48 displays the opening pattern of the jackpot 13 during the jackpot game.

In the following description, the symbol displayed on the first special symbol display 41 or the second special symbol display 42 is called "special symbol", and the symbol displayed on the normal symbol display 45 is "normal symbol". shall be called Also, the special symbol displayed on the first special symbol display 41 is called "first special symbol", and the special symbol displayed on the second special symbol display 42 is called "second special symbol". may be distinguished.

[Example of internal configuration of gaming machine 1]
FIG. 3 is a perspective view of the game machine 1 showing a state in which the inner frame 3 and the game board unit 201 are opened with respect to the outer frame 6. FIG. FIG. 4 is a front view showing part of the game board unit 201 viewed from the back side.

As illustrated in FIG. 3, the gaming machine 1 includes an outer frame 6, a game board unit 201, and an inner frame 3. As shown in FIG. The outer frame 10 is fixed to an island provided in a game hall (so-called “hall”). The game board unit 201 and the inner frame 3 are configured to be rotatable with respect to the outer frame 6 with the vertical direction of the game machine 1 as an axial direction.

The inner frame 3 is provided with the above-described handle 20 and the like on its front side, and a door opening switch 31 for detecting whether or not the inner frame 3 is opened with respect to the outer frame 6 on its back side. (see FIG. 3) is provided.
When the door opening switch 31 does not detect the opening of the inner frame 3, it outputs a signal indicating that the inner frame 3 is not opened to the game control board 100, and detects the opening of the inner frame 3 , outputs to the game control board 100 a signal indicating that the inner frame 3 is open.

The game board unit 201 is rotatable with respect to the outer frame 6 by rotatably supporting the base frame 202 constituting the game board unit 201 with respect to the outer frame 6 . On the surface side of the base frame body 202, the above-described game board 2 and the liquid crystal display device 5 and the like, which are visible to the player through an opening provided in the game board 2, are assembled. On the back side of the body 202, a back cover 203 covering the back side of the liquid crystal display device 5, a board case 210 enclosing a game control board 100 described later, and the like are assembled (see FIG. 4).

[Configuration example of game control board 100]
Next, a configuration example of the game control board 100 that controls the progress of the game will be described with reference to FIG. Here, FIG. 5 is an explanatory diagram for explaining the performance indicator 215 mounted on the game control board 100. As shown in FIG. As illustrated in FIG. 5A, the game control board 100 includes a performance indicator 215 for displaying the performance of the gaming machine 1, and a RAM clear switch 216 for initializing a part of the main RAM 103 storage area. , a setting key insertion part 218 (and a setting key switch 217: see FIG. 8) forming a keyhole for inserting a setting key, etc. are mounted.

[Configuration Example of Board Case 210]
The board case 210 is a box-shaped member that encloses the game control board 100 on which these members are mounted. It is made of a transparent resin member so that the presence or absence of unauthorized modification can be visually confirmed. Since the substrate case 210 is made of a transparent resin member in this manner, information displayed on the performance indicator 215 can be viewed through the substrate case 210 (see FIG. 4). In addition, in FIG. 4, illustration of the members mounted on the game control board 100 is omitted except for the performance indicator 215 for convenience of explanation.
Further, although the detailed description is omitted, when the case members constituting the board case 210 are separated from each other, the board case 210 is broken at the joints of these members, leaving traces of opening the board case 210 . configured to remain.

As shown in FIG. 4, the board case 210 is provided with a reset cover 211 and a setting cover 213 .

<Hardware Configuration for RAM Clear Processing>
The game control board 100 is mounted with a RAM clear switch 216, which is a switch for initializing a part of the storage area of the main RAM 103 provided in the game control board 100 (see FIGS. 5A and 8). . In this embodiment, by performing a predetermined operation using the RAM clear switch 216 and the power switch 32 (see FIG. 4), it is possible to cause the game machine 1 to perform RAM clear processing.

Although not shown, the RAM clear switch 216 (see FIG. 5) is enclosed in the board case 210 together with the game control board 100. FIG. Further, the board case 210 is formed with an insertion hole for inserting a reset pin 212 (for example, see FIG. 6A) for operating the RAM clear switch 216 at a position corresponding to the RAM clear switch 216 . One end of the reset pin 212 abuts on the RAM clear switch 216 and the other end is exposed outside the substrate case 210 . Therefore, the hall clerk can operate (depress) the RAM clear switch 216 by depressing the reset pin 212 .

By the way, since the RAM clear switch 216 is a switch for initializing a part of the storage area of the main RAM 103, it is not preferable that it can be easily operated.

For this reason, the board case 210 is provided with a reset cover 211 (see FIGS. 4 and 6A) that covers the other end of the reset pin 212 exposed to the outside of the board case 210 . The reset cover 211 is configured to be rotatable with the depth direction of the gaming machine 1 as its axial direction, and is normally in a posture in which the other end of the reset pin 212 is covered by the weight of the reset cover 211 . (See Figure 4). On the other hand, the hall clerk rotates the reset cover 211 in the direction indicated by the arrow in FIG. See FIG. 6(A)). As a result, operation of the reset pin 212 becomes possible.

<Performance indicator 215>
The performance indicator 215 displays the performance of the gaming machine 1 and is mounted on the game control board 100 (see FIGS. 5A and 8). The performance indicator 215 in this embodiment is configured with four 7-segment displays 215A, 215B, 215C, and 215D arranged in a horizontal row (see FIG. 5(B)). As illustrated, it is provided at the upper right end portion of the game control board 100 when the game control board 100 is viewed from above.

As will be described in detail later, the performance indicator 215 displays highly important information such as the base value B in the low base state of the gaming machine 1 and the setting value related to the probability of a big win. In the gaming machine 1 of this embodiment, the vertical width α of each of the 7-segment displays 215A, 215B, 215C, and 215D is set to 9 mm, and the horizontal width β is set to 5 mm. The surface area is set to 45 mm 2 (=9×5). Therefore, the hall clerk can easily visually recognize the information displayed on the performance indicator 215 .

FIG. 5(C) is a view showing part of the game control board 100 as seen from the direction of the arrow 220 shown in FIG. 5(A). As shown in FIG. 5(C), a pin portion consisting of five pins is provided on the back surface of each display portion of each of the 7-segment displays 215A, 215B, 215C, and 215D. It is fixed to the game control board 100 and electrically connected to the game control board 100 by the pin portion.

By the way, conventionally, when an electronic component with a relatively large area is mounted on the game control board 100, an illegal electronic component is placed between the surface of the game control board 100 and the electronic component (under the electronic component). Known cheats to implement. As described above, in order to improve the visibility of each information displayed on the performance indicator 215, the area of the display surface of the performance indicator 215 of this embodiment is set to a predetermined threshold value (36 mm 2 ) or more (this embodiment Then, it is 45 mm2). Therefore, it is assumed that the above-described fraudulent act is facilitated.

In consideration of the above circumstances, in this embodiment, it is difficult to mount other electronic components between the performance indicator 215 (each 7-segment display 215A, 215B, 215C, 215D) and the surface of the game control board 100 (substantially technically impossible). Specifically, as understood from FIG. 5C, the performance indicator 215 is configured to be mounted so as to be close to the surface of the game control board 100 (so that a large gap does not occur). For example, a configuration in which the distance between the back surface of the display portion of the performance indicator 215 and the surface of the game control board 100 is 3 mm or less is preferable. According to the above configuration, the inconvenience described above is suppressed.

Further, as shown in FIG. 5A described above, no electronic components are mounted on the surface of the game control board 100 from the upper edge UE to the area where the performance indicator 215 is provided. Therefore, when viewed from the upper edge UE side, the performance indicator 215 does not overlap other electronic components as shown in FIG. 5(C). Therefore, when viewed from the upper edge UE side of the game control board 100, since the performance indicator 215 is not hidden by other electronic parts, unauthorized electronic parts are mounted between the performance indicator 215 and the game control board 100. There is an advantage that it is easy to check whether or not the

Note that the area where electronic components are not mounted is not limited to the area from the upper edge UE to the area where the performance indicator 215 is provided. As long as the area where the performance indicator 215 is provided from any one of the edges, it still has the above advantages. In the gaming machine 1 of the present embodiment, two areas, the area from the upper edge UE to the area where the performance indicator 215 is provided and the area from the right edge RE to the area where the performance indicator 215 is provided, are electronic It is defined as an area where components are not mounted. Therefore, it is easier to confirm whether or not illegal electronic components are mounted between the performance indicator 215 and the game control board 100, as compared with the case where the electronic components are not mounted in one area. There is an advantage.

This performance indicator 215 has both a function of displaying the base value in the low base state and a function of displaying the setting value related to the probability of big wins in the gaming machine 1. These functions will be described in detail later. . In this embodiment, a case will be described in which the performance indicator 215 that displays the base value (in this embodiment, the rightmost 7-segment display 215D) is also used as a setting indicator that displays the setting value, but other embodiments will be described. Then, a setting display for displaying setting values may be provided separately from the performance display 215 . Also, the number of 7-segment displays constituting the performance indicator 215 is not limited to four, and may be three or less or five or more.

<Hardware configuration of the present embodiment related to setting change processing>
FIG. 6 is a front view showing part of the board case 210 of the game control board 100, and FIG. 6A is a diagram illustrating the hardware configuration in this embodiment relating to setting change processing. (B) is a diagram illustrating a hardware configuration in another embodiment related to setting change processing.

The setting key insertion portion 218 is configured to have an insertion portion main body fixed to the game control board 100 and a rotating member that rotates with respect to the insertion portion main body. A keyhole is formed for the clerk to insert the setting key.

As will be described in detail later, in the gaming machine 1 of the present embodiment, a hall clerk holding a setting key (not shown) operates a setting key switch through a setting key insertion portion 218 (see FIG. 6A). 217 (see FIG. 8), reset pin 212 (see FIG. 6(A)), and power switch 32 (see FIG. 4) by performing a predetermined operation, the jackpot probability determined as a jackpot in the special symbol determination can be changed. That is, in this embodiment, by performing a predetermined operation using the setting key switch 217, the reset pin 212, and the power switch 32, it is possible to cause the gaming machine 1 to perform a setting change process related to the probability of a big win. .
Also, by performing a predetermined operation using the setting key switch 217, a set value indicating which probability the jackpot probability is set is displayed on the performance indicator 215 (in this embodiment, the rightmost 7-segment display 215D). It is possible to confirm this by lighting the display.

In this way, in order to change the setting of the jackpot probability using the setting key switch 217, or to confirm the setting of the jackpot probability, the substrate case 210 has a setting key inserted into which a setting key is inserted. A portion 218 (see FIG. 6A) is provided. This setting key insertion portion 218 is mounted on the game control board 100, and the keyhole is exposed to the outside of the board case 210 through an opening formed at a position corresponding to the setting key insertion portion 218 in the board case 210. (See FIG. 6(A)). Although not shown in the drawing, the setting key insertion portion 218 includes a setting key switch 217 (for example, 90 degrees) for detecting that the rotating member of the setting key insertion portion 218 has been rotated clockwise by a predetermined angle (for example, 90 degrees). 8) are arranged close to each other, and when the setting key switch 217 detects that the rotating member has been rotated by a predetermined angle (turned on), it outputs a detection signal to that effect. Output to the game control board 100 .

Incidentally, by operating the setting key to rotate the rotating member of the setting key insertion portion 218, the performance of the game machine 1 can be changed by changing the probability of a big win, or the set value related to the current probability of a big win can be changed. From the viewpoint of fraud prevention, it is not preferable that the above operation using the setting key can be easily performed.

For this reason, the substrate case 210 is provided with a setting cover 213 (see FIGS. 4 and 6A) that covers the setting key insertion portion 218 (the keyhole of the rotating member). The setting cover 213 is configured to be rotatable with the depth direction of the game machine 1 as its axial direction, and normally assumes a posture in which the setting key insertion portion 218 is covered by the weight of the setting cover 213 (Fig. 4). On the other hand, the hall clerk turns the setting cover 213 in the direction shown by the arrow in FIG. )reference). This allows the setting key to be inserted into the keyhole of the setting key insertion portion 218 . 6A illustrates a state in which the rotating member of the setting key insertion portion 218 is not rotated, and FIG. 6B illustrates a state in which the rotating member of the setting key insertion portion 218 is rotated. The state shown is exemplified.

<Power switch 32>
As illustrated in FIG. 4 , a power switch 32 is provided at a lower right position of the board case 210 in the base frame 202 . Although not shown in the drawing, the gaming machine 1 is electrically connected to an island power supply device via an island power supply line provided on the island, and by turning the power switch 32 "ON", a game is played. Power supply from the island power supply system is started to the entire control device of the machine 1 .

In this embodiment, the power switch 32 is one of operation means for causing the gaming machine 1 to perform RAM clear processing and setting change processing. It is preferable that it is not easy to operate and operate the power switch 32 with one hand at the same time, or to operate the reset pin 212 and the power switch 32 at the same time with one hand.

Therefore, in the gaming machine 1 of the present embodiment, when it is assumed that the operation is performed with the right hand, for example, the power switch 32 is operated with the little finger while rotating the reset cover 211 with the thumb and pressing the reset pin 212. The power switch 32 is arranged at a position distant from the reset pin 212 to such an extent that such operations cannot be performed.
Assuming that the right hand is operated, for example, the power switch 32 can be operated with the little finger while inserting the setting key into the keyhole of the setting key insertion portion 218 with the thumb and forefinger to rotate the rotating member. The power switch 32 is arranged at a position distant from the setting key insertion portion 218 to the extent that it is impossible to turn on the power switch.

Thus, in the gaming machine 1 of the present embodiment, the reset cover 211 covering the reset pin 212 is provided, the setting cover 213 covering the keyhole of the setting key insertion portion 218 is provided, and the power switch 32 is connected to the reset pin 212 and the setting cover 213 . By providing the key insertion part 218 at a position some distance away from the keyhole, a configuration is adopted in which the operation related to the RAM clear process and the operation related to the setting change process cannot be easily performed with one hand.

<First Modification of Hardware Configuration for Setting Change Processing>
In the present embodiment, the reset pin 212 is used to switch the jackpot probability when changing the setting related to the jackpot probability, but in another embodiment, as shown in FIG. For example, a switching button 222 (for switching setting values) is provided at a position close to the setting key insertion portion 218 in the substrate case 210, and the setting is performed using the setting key insertion portion 218, the switching button 222, and the power switch 32. A configuration in which a change operation is performed may be adopted.

In this case, for example, when the setting key is inserted into the keyhole of the setting key insertion portion 218 and the rotating member is rotated by a predetermined angle (ON posture), the power switch 32 is turned "ON". is displayed on one of the 7-segment displays (for example, 7-segment display 215D) of the performance indicator 215, and each time the switch button 222 is pressed, the displayed setting value is switched. When the rotating member is returned to its original posture (OFF posture), the current set value is updated to the set value displayed on the performance indicator 215 immediately before returning the rotating member to its original posture. It is conceivable to perform an operation or process. In this case, the set value is set on the condition that the power switch 32 is turned "OFF" and then "ON" after the setting key is operated to return the rotating member to its original posture. It is good also as a structure which confirms the change of.

<Second Modification of Hardware Configuration for Setting Change Processing>
FIG. 7 is a front view showing part of the board case 210 of the game control board 100. As shown in FIG. In another embodiment, a setting switching button (not shown) for switching the setting related to the jackpot probability is mounted on the game control board 100, and instead of the setting key inserting portion 218, as illustrated in FIG. A configuration in which a setting change pin 219 for operating the switching button is provided on the substrate case 210 may be employed.

In this case, it is conceivable to perform the following operations and corresponding processing. For example, when the power switch 32 is turned "ON" while pressing the setting change pin 219, the setting value can be changed. In this state, each time the hall clerk operates the setting change pin 219, the display of the set value displayed on any of the 7-segment displays (for example, the 7-segment display 215D) of the performance indicator 215 is switched, and the power switch is switched. When the power switch 32 is turned "OFF" and then turned "ON", the setting value is updated to the setting value displayed immediately before the power switch 32 is turned "OFF".

[Configuration of control device of gaming machine 1]
FIG. 8 is a block diagram showing a configuration example of a control device provided in the gaming machine 1. As shown in FIG.
On the back side of the game board 2 (game board unit 201: see FIG. 3), in addition to a ball tank for storing game balls sent out to the upper tray 28 or the lower tray 29, the operation of the game machine 1 is controlled. A controller is provided. As illustrated in FIG. 4, the control device of the gaming machine 1 includes a game control board 100 (an example of a game control unit) for controlling the progress of the game such as transmission of various judgments and commands, commands received from the game control board 100 A production control board 130 (an example of a production control unit) that controls production based on, an image sound control board 140 that controls production by images and sounds, and a lamp control board that controls production by various lamps and movable bodies. 150 and the like.
The configuration of the control device is not limited to this. For example, the effect control board 130, the image sound control board 140, and the lamp control board 150 may be configured by one control board.

[Configuration example of game control board 100]
The game control board 100 includes a main CPU 101 , a main ROM 102 and a main RAM 103 . The main CPU 101 performs various arithmetic processes related to determination and the number of awarded balls to be paid out, based on programs and the like stored in the main ROM 102 . The main ROM 102 stores a base calculation program and the like for calculating a base value B in a low base state, which will be described later. The main RAM 103 is used as a storage area for temporarily storing various data used when the main CPU 101 executes the above programs or as a work area for data processing.

The game control board 100 includes a count switch 110, a first start switch 111, a second start switch 112, an electric tulip control unit 113, a gate switch 114, a big win switch 115, a big win control unit 116, and a normal win. An opening switch 117, a door opening switch 31, a performance display 215, a RAM clear switch 216, a setting key switch 217, and respective displays 41 to 48 constituting the display 4 are connected. In addition, since the gaming machine 1 in the present embodiment has four normal winning openings 14, it is provided with four normal winning opening switches 117, but in FIG. It is written.

The count switch 110 is for counting the number of game balls hit into the game area 10, detects the game balls hit into the game area 10, and outputs the detection signal to the game control board 100. . The main CPU 101 counts the number of game balls hit into the game area 10 based on the detection signal output from the count switch 110 .

The first starting port switch 111 detects that a game ball has entered the first starting port 11 and outputs the detection signal to the game control board 100 . The second starting port switch 112 detects that a game ball has entered the second starting port 12 and outputs the detection signal to the game control board 100 . The electric tulip control unit 113 opens and closes the second starting port 12 by activating an electric solenoid connected to a pair of blade members of the electric tulip 17 so as to be able to transmit drive in response to a control signal from the game control board 100. do. The gate switch 114 detects that the game ball has passed through the gate 16 and outputs the detection signal to the game control board 100 .

The big winning hole switch 115 detects that a game ball has entered the big winning hole 13 and outputs the detection signal to the game control board 100 . The big winning gate control unit 116 opens and closes the big winning gate 13 by activating an electric solenoid connected to a plate that closes the big winning gate 13 so as to be able to transmit drive based on a control signal from the game control board 100. do. The normal winning opening switch 117 detects that the game ball has entered the normal winning opening 14 and outputs the detection signal to the game control board 100 .

The door open switch 31 detects that the inner frame 3 is open and outputs the detection signal to the game control board 100 . The setting key switch 217 detects that the rotating member of the setting key inserting portion 218 has been rotated clockwise by a predetermined angle (turned on), and outputs the detection signal to the game control board 100 . .

The performance indicator 215 displays the performance of the gaming machine 1. The performance indicator 215 has a function of blinking the base value B in the low base state, and a setting change mode and a setting confirmation mode, which will be described later with reference to FIG. It also has a function of lighting and displaying a set value related to the probability of a big hit of 1. The blinking display of the base value B and the lighting display of the set value will be described in detail later.

The RAM clear switch 216 is a switch for instructing erasure of information stored in a partial area of the main RAM 103 and is mounted on the game control board 100 . When the power switch 32 is turned "ON" while the reset pin 212 is pressed, the RAM clear switch 216 outputs a RAM clear signal to the game control board 100. FIG. In response to this, the main CPU 101 executes RAM clear processing (first RAM clear processing to be described later: see FIG. 10) for a partial area of the main RAM 103 .

When the main CPU 101 of the game control board 100 receives a detection signal from the first starting port switch 111, the second starting port switch 112, the big winning port switch 115, or the normal winning port switch 117, the game ball wins. A payout control board (not shown) is instructed to pay out a predetermined number of prize balls according to the location, and the number of prize balls to be paid out is managed based on information from the payout control board. Although detailed description is omitted, the payout control board supplies game balls to the upper tray 28 or the lower tray 29 by controlling a drive motor that sends out game balls from the ball tank.

The main CPU 101 acquires various random numbers as acquired information at the timing when the detection signal is input from the first starting switch 111, and executes the first special symbol determination using the acquired random numbers. In addition, various random numbers are acquired as acquisition information at the timing when the detection signal from the second starting port switch 112 is input, and the second special symbol determination is executed using the acquired random numbers.

When the game ball is detected by the first start switch 111 or the second start switch 112 and the detection signal is input, the main CPU 101 acquires a jackpot random number, a pattern random number, a reach random number, and a variation pattern random number. do.

Here, the jackpot random number is a random number for determining a jackpot or a loss. The symbol random number is a random number for determining the type of jackpot when it is determined to be a jackpot. The ready-to-win random number is a random number used for determining whether to perform a ready-to-win effect or to perform a no-reach effect when it is determined that the winning game is lost. The variation pattern random number is a random number for determining the variation pattern when the special symbols are variably displayed.

When the main CPU 101 acquires these random numbers, first, the main CPU 101 determines whether or not to execute a jackpot game based on whether or not the acquired jackpot random number matches a predetermined random number value stored in the main ROM 102 . judge. Here, when it is determined that a jackpot game is to be executed, the type of jackpot is determined based on which random number of predetermined random numbers stored in the main ROM 102 matches the acquired pattern random number. Here, as the types of jackpots, for example, after the jackpot game is over, the game is controlled in the "probability variable game state", and after the jackpot game is over, the game is played in the "time-saving game state". An example is a "regular jackpot" in which is controlled.

<About game status>
As shown in FIG. 12, which will be described later, the gaming machine 1 of the present embodiment controls the game in one of the "normal game state", "probability variable game state", and "time-saving game state".

"Normal game state" is a normal game state in which special symbol determination is performed in a low probability state in which the probability of executing a jackpot game by special symbol determination is relatively low, and the electric chew support function is not provided. . That is, in the normal game state, the big win probability determined to execute the big win game is set to a relatively low probability. In addition, the probability that the second starting port 12 is determined to be opened by the normal design determination is set to a relatively low probability (eg 1/12), and the fluctuation time of the normal design is relatively long (eg 25 seconds) and the opening time of the second starting port 12 when it is determined to open the second starting port 12 is set to a relatively short time (for example, 0.1 seconds×1 time).

"Probability variation gaming state" is a gaming state in which special symbol determination is performed in a high probability state with a relatively high probability of being determined to execute a jackpot game, and an electric chew support function is provided. That is, in the variable probability gaming state, the big hit probability determined to execute the big hit game by the special symbol determination is set to a relatively high probability. In addition, the probability that the second starting port 12 is determined to be opened by the normal design determination is set to a relatively high probability (eg 12/12), and the fluctuation time of the normal design is relatively short (eg 2 seconds). and the opening time of the second starting port 12 is set to a relatively long time (for example, 1.6 seconds×3 times) when it is determined to open the second starting port 12 .

"Time-saving game state" is a game state in which special symbol determination is performed in the low probability state and an electric chew support function is provided. That is, in the time-saving gaming state, the jackpot probability determined to execute the jackpot game by the special symbol determination is set to a relatively low probability. In addition, the probability that the second starting port 12 is determined to be opened by the normal design determination is set to a relatively high probability (eg 12/12), and the fluctuation time of the normal design is relatively short (eg 2 seconds). and the opening time of the second starting port 12 is set to a relatively long time (for example, 1.6 seconds×3 times) when it is determined to open the second starting port 12 .

Comparing each game state with respect to the variation pattern of the special symbol, in the "normal game state", it is easy to set a variation pattern with a relatively long variation time of the special symbol, A variation pattern in which the variation time of the special symbol is relatively short is likely to be set.

In addition, in the following description, the state in which it is easy to win the game ball to the second start port 12 by providing the electric chew support function is "high base state" (in this embodiment, "probability variable game state" and “time-saving gaming state” correspond to this), and the state in which it is not easy for the game ball to enter the second start port 12 because the electric chew support function is not provided is a “low base state” (this In the embodiment, "normal game state" corresponds to this).

When the main CPU 101 determines not to execute the jackpot game based on the determination based on the jackpot random number, the main CPU 101 determines whether the reach random number matches the predetermined random value stored in the main ROM 102. It is determined whether to perform a performance or to perform a non-reach performance. In addition, the main CPU 101 determines the variation pattern of the special symbols when the special symbols are variably displayed regardless of whether or not the jackpot game is performed. Thereby, the fluctuation time of the special symbol is determined.

When the main CPU 101 determines to execute a jackpot game and determines the type of jackpot, the main CPU 101 controls the opening and closing of the jackpot 13 via the jackpot controller 116 to play a jackpot game corresponding to the jackpot type. to run.

Further, the main CPU 101 obtains a random number at the timing when the detection signal from the gate switch 114 is input, and uses the obtained random number to execute normal symbol determination. When it is determined to open the second starting port 12 , the second starting port 12 is temporarily opened by operating the electric tulip 17 via the electric tulip control section 113 .

Further, the main CPU 101 causes the display devices 41 to 48 constituting the display device 4 to execute the processing described above with reference to FIG.

Further, when the main CPU 101 receives a detection signal from the door open switch 31 indicating that the inner frame 3 is open, the main CPU 101 outputs an error message such as "the door is open" from the speaker 24. Execute notification processing. Further, the main CPU 101 receives a detection signal from the door opening switch 31 indicating that the inner frame 3 is open when a predetermined operation instructing execution of setting change processing relating to the probability of a big win is performed. On this condition, the setting change process is executed. On the other hand, when a predetermined operation instructing execution of setting change processing relating to the jackpot probability is performed, if a detection signal from the door opening switch 31 indicating that the inner frame 3 is open is not input, the setting is changed. Execute error handling without performing any processing. Note that the setting change process will be described later in detail with reference to FIG.

<Calculation and display of base value B>
Further, the main CPU 101 calculates the base value B in the low base state based on the base calculation program stored in the main ROM 102 and displays the calculated base value B on the performance display 215 . This base value B is the total number of game balls launched into the game area 10 in the low base state (when the player is hitting left), and the first start port 11 in the low base state. When the total number of prize balls paid out in response to the winning of game balls is H, and when the base state is low Assuming that F is the total number of prize balls paid out in response to winning of game balls, it can be calculated based on the following formula.
B % = (H + F) / G x 100

Although not shown in the figure, the main RAM 103 stores the total number G, and the main CPU 101 reads the stored total number each time the count switch 110 outputs a detection signal in the low base state. A first update process is performed to update G to a value obtained by adding "1".

Also, the main RAM 103 stores the total number of prize balls H, and in this embodiment, four prize balls are paid out each time a game ball wins the first start hole 11 . For this reason, the main CPU 101 updates the stored total number of prize balls H to a value obtained by adding "4" every time the detection signal is output from the first starting port switch 111 in the low base state. Perform update processing.

Further, the main RAM 103 stores the total number of prize balls F, and in this embodiment, three prize balls are paid out each time a game ball enters the normal winning hole 12 . For this reason, the main CPU 101 updates the stored total number of prize balls F to a value by adding "3" each time a detection signal is output from the normal winning opening switch 117 in the low base state. process.

The main CPU 101 performs recalculation based on the above formula when performing any one of the above-described first update process, second update process, and third update process. For example, 100 game balls are launched into the game area 10 and the total number G becomes "100", and 9 game balls enter the first start hole 11 and the total number of prize balls H becomes "36" (= 4 × 9), and when 8 game balls enter the normal winning hole 12 and the total number of prize balls F is "24" (= 3 × 8), (36 + 24) / 100 × 100 A base value B of %=60% can be calculated.
In this case, the performance indicator 215 blinks the base value B, for example, "B060" (see FIG. 10). Specifically, "B" is blinking on the leftmost 7-segment display 215A, "0" is blinking on the second 7-segment display 215B from the left, and "6" is displayed on the third 7-segment display 215C from the left. is blinking, and "0" is blinking on the rightmost 7-segment display 215D. Since the blinking display of these four leftmost 7-segment displays is synchronized, the base value "B060" appears to blink as a whole. In addition, this flashing display of the base value B of "B060" continues until any value of the total number G, the total number of prize balls H, or the total number of prize balls F is updated. Once updated, the blinking display of the base value B recalculated based on the updated value starts.

In addition, in the gaming machine 1 of the present embodiment, except for the setting change mode and the setting confirmation mode, which will be described later with reference to FIG. The base value B is flashed on the device 215 .
Therefore, the hall clerk rotates the inner frame 3 and the game board 201 to display the performance indicator 215 whenever the power of the gaming machine 1 is turned on, except during the above two modes. It is possible to ascertain the current base value B by exposing .

Also, when the jackpot game is performed, or when the high base state triggered by the jackpot game (in the present embodiment, "probability variable game state" or "time-saving game state"), the second The first update process, the second update process, and the third update process are all interrupted. Therefore, the base value B displayed on the performance indicator 215 is never updated.
Further, when the player returns from the high base state to the low base state and resumes "left-handed", the first update process, the second update process, and the third update process are resumed, and the above calculation formula A process is performed to appropriately update the blinking display of the performance indicator 215 so as to indicate the base value B calculated based on.

In addition, in this embodiment, in the low base state, the total number of prize balls paid out in response to the game balls entering the first starting hole 11, and the game balls entering the two normal winning holes 14 A case will be described in which the base value B is calculated based on the total number of prize balls F paid out in response to winning.
On the other hand, in another embodiment, a gate similar to the gate 16 through which normal symbol determination is performed when a game ball passes is provided in the left side area of the game area 10, and the total number of prize balls H and the total prize are provided. In addition to the number of balls F, when the game ball hit left by the player in the low base state wins the second start hole 12, the base value B is based on the total number of prize balls D corresponding to the winning. may be calculated. The calculation formula for calculating the base value B in this case is as follows.
B % = (H + F + D) / G x 100

Also, in the gaming machine 1, the performance indicator 215 always displays the base value B or the set value relating to the probability of a big win when power is supplied from the outside (an island power supply device, not shown). On the other hand, when power is not supplied to the gaming machine 1 from the outside, the performance indicator 215 does not display the base value B or the setting value.

[Configuration example of production control board 130]
The performance control board 130 includes a sub CPU 131 , a sub ROM 132 , a sub RAM 133 and an RTC (real time clock) 134 . The sub CPU 131 performs arithmetic processing when controlling effects based on programs stored in the sub ROM 132 . The sub RAM 133 is used as a storage area for temporarily storing various data used when the sub CPU 131 executes the above programs or as a work area for data processing. The RTC 134 measures the current date and time (date and time).

The sub CPU 131 sets the effect contents based on the game information regarding the special symbol determination, the normal symbol determination, the jackpot game and the like transmitted from the game control board 100 . At that time, the input of the operation information from the production button 26 or the production key 27 may be received, and the contents of production corresponding to the operation information may be set. The sub CPU 131 transmits to the image sound control board 140 and the lamp control board 150 a command instructing execution of the set effect content.

[Configuration example of image sound control board 140]
The image sound control board 140 includes a general CPU 141, a control ROM 142, a control RAM 143, a VDP (Video Display Processor) 144, an audio DSP (Digital Signal Processor) 145, and the like. The supervising CPU 141 performs arithmetic processing when controlling images and sounds representing effects for which the contents of effects are set in the effect control board 130 based on programs stored in the control ROM 142 . The control RAM 143 is used as a storage area for temporarily storing various data used when the overall CPU 141 executes the above programs or as a work area for data processing.

The VDP 144 generates images displayed on the liquid crystal screen 5 . Acoustic DSP 145 generates acoustic data output from speaker 24 . The overall CPU 141 generates control signals based on commands from the production control board 130 and programs stored in the control ROM 142 and outputs them to the VDP 144 and the audio DSP 145 to control the operations of the VDP 144 and the audio DSP 145 .

Although not shown in the figure, the VDP 144 includes an image ROM for storing material data necessary for image generation, a drawing engine for executing image drawing processing, and an image drawn by the drawing engine to the liquid crystal display device 5 . It has an output circuit that outputs to In the image ROM, material data such as sprite data (single image data) consisting of a collection of pixel information, movie data consisting of a collection of a plurality of image data, etc. are stored in a compressed state. , based on the control signal from the general CPU 141, uses the material data stored in the image ROM to perform drawing processing on the frame buffer. The output circuit outputs the image drawn in this frame buffer to the liquid crystal display device 5 at a predetermined timing.

Also, although not shown in the figure, the audio DSP 145 includes an audio ROM for storing various audio data related to sound effects such as music, voice, and sound effects, and a work area for data processing by the audio DSP 145. SDRAM is connected. The audio DSP 145 reads the audio data corresponding to the control signal from the general CPU 141 from the audio ROM to the SDRAM, executes data processing, and outputs the processed audio data to the speaker 24 .

[Configuration example of lamp control board 150]
The lamp control board 150 includes a lamp CPU 151 , a lamp ROM 152 and a lamp RAM 153 . The lamp CPU 151 performs arithmetic processing when controlling the production accessory 7, the board lamp 25, the frame lamp 37, etc. based on the program stored in the lamp ROM 152. FIG. The lamp RAM 153 is used as a storage area for temporarily storing various data used when the lamp CPU 151 executes the above programs or as a work area for data processing.

The lamp ROM 152 stores light emission pattern data and operation pattern data. Here, the light emission pattern data is data indicating the respective light emission patterns of the light emitting elements, the board lamps 25, the frame lamps 37, and the like, which the production accessory 7 has. The action pattern data is data indicating the action pattern of the performance accessories 7 and the like.

The lamp CPU 151 reads the light emission pattern data corresponding to the command received from the production control board 130 from the light emission pattern data stored in the lamp ROM 152 to the lamp RAM 153, , controls the light emission of the frame lamp 37 . In addition, the lamp CPU 151 reads the operation pattern data corresponding to the command received from the production control board 130 from the operation pattern data stored in the lamp ROM 152 to the lamp RAM 153, and drives the motor for operating the production accessory 7. to control.

Further, when the player operates the effect button 26 or the effect key 27, the lamp CPU 151 transmits to the effect control board 130 an operation command notifying that effect.

[Configuration example of main RAM 103]
<Determination Storage Area 1030, Reserved Storage Areas 1031 to 1038>
FIG. 9 is an explanatory diagram for explaining various storage areas of the main RAM 103 and information to be stored. As exemplified in FIG. 9A, the main RAM 103 has a storage area for storing acquisition information obtained when a game ball wins at the first start port 11 or the second start port 12. storage area 1030, first reserved storage area 1031, second reserved storage area 1032, third reserved storage area 1033, fourth reserved storage area 1034, first reserved storage area 1035, second reserved storage area 1036, third reserved storage area A storage area 1037 and a fourth reserved storage area 1038 are provided.

The determination storage area 1030 is a storage area for storing various information used for the special symbol determination when the special symbol determination is actually executed. The first reserved storage area 1031 to the fourth reserved storage area 1034 are storage areas for storing various information related to the first special symbol determination, and the first reserved storage area 1035 to the fourth reserved storage area 1038 are the second It is a storage area in which various information related to special symbol determination is stored. In addition, when the execution of the special symbol determination becomes possible in a state in which the right related to the first special symbol determination and the right related to the second special symbol determination are reserved, the second special symbol is higher than the first special symbol determination. Judgment is prioritized. Therefore, in the determination storage area 1030, when the second special symbol determination is suspended when executing the special symbol determination, various information stored in the first suspension storage area 1035 is shifted, and the first When only the special symbol determination is reserved, various information stored in the first reserved storage area 1031 is shifted.

As illustrated in FIG. 9B, the reserved storage areas 1031 to 1038 are respectively acquired by the main CPU 101, an area for storing a jackpot random number, an area for storing a pattern random number, an area for storing a reach random number, It includes an area for storing variation pattern random numbers, an area for storing pre-determination information that is information indicating the result of pre-determination, and the like. The jackpot random numbers, pattern random numbers, reach random numbers, and variation pattern random numbers are as described above.

The pre-determination information is information obtained by a pre-determination process (see FIG. 25), which will be described later, based on a jackpot random number, a symbol random number, a reach random number, and a fluctuation pattern random number. Preliminary judgment information is specifically, winning start information, information indicating whether the judgment result of special symbol judgment is a jackpot, information indicating what kind of jackpot if it is a jackpot, Information indicating the variation pattern of the special symbol, information indicating the game state of the gaming machine 1, and the like are included. Here, the winning starting gate information is acquired when the game ball wins the first starting gate 11 with the jackpot random number, the pattern random number, the reach random number, and the fluctuation pattern random number stored in the same reserved storage area. It is information indicating whether the game ball was acquired when the game ball entered the second starting port 12 or won a prize. Pre-determination information including these information is stored in the same reservation storage area as the jackpot random numbers, pattern random numbers, reach random numbers, and variation pattern random numbers used in the pre-determination process.

The five pieces of information explained based on FIG. 9(B) are stored in the first reservation storage area 1031 to the fourth reservation storage area 1034 in order from the first reservation storage area 1031 each time the game ball wins the first start port 11. Each time a game ball wins in the second starting port 12, it is stored in one of the first reservation storage area 1035 to the fourth reservation storage area 1038 in order from the first reservation storage area 1035.

For example, when the information is not stored in any of the first reserved storage area 1031 to the fourth reserved storage area 1034 and five pieces of information related to the first special symbol determination are newly acquired, the five pieces of information are It is stored in the first reserved storage area 1031 . Also, for example, when five information related to the first special design determination is newly acquired in a state in which five pieces of information are stored in each of the first reserved storage area 1031 and the second reserved storage area 1032, the five pieces of information is stored in the third reserved storage area 1033 .

In addition, when the information stored in the first reserved storage area 1031 is shifted to the determination storage area 1030 when executing the first special symbol determination, it is stored in the reserved storage area after the second reserved storage area 1032. The information is shifted to the first reserved storage area 1031 side. For example, when the information stored in the first reserved storage area 1031 to the third reserved storage area 1033 is shifted to the judgment storage area 1030, the second Information stored in reserved storage area 1032 is shifted to first reserved storage area 1031 and information stored in third reserved storage area 1033 is shifted to second reserved storage area 1032 .

Such shift processing of information is similarly performed in the first reservation storage area 1035 to the fourth reservation storage area 1038 in which the information related to the second special symbol determination is stored. In addition, in the gaming machine 1 in the present embodiment, when both the first special symbol determination and the second special symbol determination are suspended, that is, information is stored in both the first reserved storage area 1031 and the first reserved storage area 1035. If stored, the shift processing in the first reserved storage area 1035 to the fourth reserved storage area 1038 is preferentially performed prior to the shift processing in the first reserved storage area 1031 to the fourth reserved storage area 1034 .

By the way, even if the game ball enters the first starting port 11 or the second starting port 12 and various random numbers are obtained when the special symbols are variably displayed or during the jackpot game, the special symbol judgment and the special symbol are not performed. Variable display cannot be performed immediately.

Therefore, when various random numbers are acquired under such circumstances, the main CPU 101 stores the acquired random numbers, etc. to 1038. On the other hand, when the special symbols are not variably displayed, the determination of the special symbols is not suspended, and the jackpot game is not in progress, the main CPU 101 receives various random numbers and the like as a result of winning the starting game. It is assumed that it is directly stored in the determination storage area 1030 .

<Game state storage area 1039>
Further, as illustrated in FIG. 9A, the main RAM 133 is provided with a game state storage area 1039 for storing information indicating which game state the current game state is. In the present embodiment, information indicating that the current gaming state is "probability variable gaming state", information indicating that the current gaming state is "time-saving gaming state", current gaming state is "normal gaming state", Alternatively, the game state storage area 1039 stores information indicating that the current game state is the “jackpot game state” in which the jackpot game is being executed.

<Setting value temporary storage area 1040>
Further, as illustrated in FIG. 9A, the main RAM 103 is provided with a setting value temporary storage area 1040 . This setting value temporary storage area 1040 is a storage area for temporarily storing a setting value relating to a jackpot probability determined to execute a jackpot game during a setting change process to be described later.
The setting values stored in the setting value temporary storage area 1040 are deleted from the setting value temporary storage area 1040 when the setting change process is completed.

<Set value main storage area 1041>
Further, as illustrated in FIG. 9A, the main RAM 103 is provided with a set value main storage area 1041 . The main setting information storage area 1041 is a storage area for storing setting values determined by a setting change process, which will be described later.
As will be described later, in the setting change process, when a confirmation operation for confirming the setting is performed, the same setting value as the setting value stored in the setting value temporary storage area 1040 is stored in the setting information main storage area 1041. .

In addition, in the gaming machine 1 of the present embodiment, two types of RAM clear processing, a first RAM clear processing and a second RAM clear processing, which will be described later, are prepared as RAM clear processing for initializing information stored in the main RAM 103. there is
On the other hand, in the setting value temporary storage area 1040, although the setting values stored in the setting value temporary storage area 1040 are not erased even if the first RAM clear processing is performed, the stored setting values are erased when the second RAM clear processing is performed. be done.
On the other hand, the set values stored in the main set value storage area 1041 are not erased regardless of whether the first RAM clear processing or the second RAM clear processing is performed.

<Performance Display Storage Area 1042>
Further, as illustrated in FIG. 9A, the main RAM 103 is provided with a performance display storage area 1042 . In this performance display storage area 1042, the total number G of game balls launched into the game area 10 in the low base state described above, and the number of game balls winning the first start port 11 in the low base state are stored. The total number of prize balls paid out according to H, and when the game balls have entered the two normal winning holes 14 provided in the left side area of the game area 10 in the low base state. The total number of awarded balls F of the paid out prize balls and the base value B in the low base state calculated based on these variables are stored.

(Regarding retention of information)
The gaming machine 1 is activated by supplying power from the outside (an island power supply device (not shown)) to a power supply board provided in the gaming machine 1 . When power is supplied from the outside in this manner, each piece of information stored in the main RAM 103 is held by the power supplied from the power supply board.
On the other hand, when power is not supplied from the island power supply device to the power supply board, each information stored in the main RAM 103 is held by power supplied from a backup power supply (not shown).

On the other hand, as shown in FIG. 9A, the main setting value storage area 1041 and the performance display storage area 1042 are RAM clear processing non-target regions that are not subjected to the first RAM clear processing or the second RAM clear processing. It has become.
Therefore, regardless of whether or not power is supplied to the gaming machine 1 from the outside, the set values stored in the main set value storage area 1041 and the information stored in the performance display storage area 1042 are displayed. Retained without being erased.

Therefore, the set value is erased from the main set value storage area 1041 in spite of the fact that the jackpot probability is set, and as a result, there is a problem that the special symbol determination as to whether or not to execute the jackpot game cannot be properly performed. does not occur. In addition, since each information stored in the performance display storage area 1042 is retained over a long period of time, it is not limited to the period from when power supply is started to when it is finished in one day. By cumulatively calculating the base value B over a long period of time such as a month, the calculated base value B can be blinked on the performance indicator 215 .

[About the 5 modes when the power is turned on]
FIG. 10 is an explanatory diagram for explaining the setting change mode, setting confirmation mode, first RAM clear mode, second RAM clear mode, and power restoration mode. The game machine 1 of the present embodiment operates in a setting change mode, a setting confirmation mode, and a first RAM according to the states of the setting key switch 217 and the RAM clear switch 216 when the power is turned on (when the power switch 32 is turned "ON"). Transition to either clear mode or power restoration mode.

"Power ON" in FIG. 10 means that the power switch 32 has been turned ON to start supplying power to the gaming machine 1 from the outside. "Setting key ON" in FIG. 10 means that the turning member of the setting key insertion portion 218 is in the ON posture by the operation using the setting key by the hall clerk. Also, "setting key OFF" (written together with "power ON") in FIG. 10 means that the rotating member of the setting key insertion portion 218 is in the OFF posture. That is, the setting key is not inserted into the keyhole of the setting key insertion portion 218, or even if the setting key is inserted into the keyhole of the setting key insertion portion 218, the posture of the rotating member changes to the ON posture. It means that you are not "SETTING KEY OFF" written together with two downward arrows in FIG. 10 is an operation using the setting key for changing the posture of the rotating member of the setting key insertion portion 218 from the ON posture to the OFF posture. means that

"RAM clear switch OFF" in FIG. 10 means that the RAM clear switch 216 is not operated (that is, the reset pin 212 is not pressed), and "RAM clear switch OFF" in FIG. "Switch ON" means that the RAM clear switch 216 is being operated (that is, the reset pin 212 is being pressed).

Here, the power restoration mode is a mode in which power restoration processing is performed to restore the gaming state before the power shutdown. The first RAM clear mode is a mode in which RAM clear processing is performed on each storage area within the first RAM clear processing target area illustrated in FIG. 9A. The setting change mode is a mode in which setting change processing for changing the setting values stored in the main setting value storage area 1041 is performed. The setting confirmation mode is a mode in which a setting confirmation process is performed to display the setting values stored in the main setting value storage area 1041 on the performance indicator 215 .

In this embodiment, as described above with reference to FIG. and are provided.

<Power recovery mode>
In the gaming machine 1 of the present embodiment, the power switch 32 is turned on without pressing the RAM clear switch 216 (reset pin 212) while the setting key insertion portion 218 is in the OFF posture. Then, immediately after the gaming machine 1 is activated, it shifts to the power recovery mode (see FIG. 10).

When the power restoration mode is entered, the main CPU 101 stores the backup data stored in the main RAM 103 in the work area (for example, the game state storage area 1039) of the main RAM 103, and executes timer interrupt processing (see FIG. 21), which will be described later. Perform power recovery processing to make it executable. By performing this power restoration process, the game state is restored to the state before the power supply from the outside was interrupted.

In this power recovery mode, for example, a power recovery screen is displayed on the liquid crystal screen 5 with the text "power recovery in progress" superimposed on a solid black background image, and the voice "power recovery in progress" is repeated from the speaker 24. output.

Further, in this power restoration mode, the main CPU 101 blinks the base value B stored in the performance display storage area 1042 on the performance indicator 215 (see FIG. 10). In addition, in this embodiment, the set value is displayed on the performance indicator 215 in other modes. Therefore, in order to more effectively suppress the problem that the hall clerk confuses the base value B and the set value, the set value is lit and displayed on the performance indicator 215 (in the setting change mode and the setting confirmation mode). On the other hand, the base value B is flashed on the performance indicator 215 . This is the same for the first RAM clear mode and the second RAM clear mode.

As illustrated in FIG. 10, when the first RAM clearing process in the first RAM clearing mode or the second RAM clearing process in the second RAM clearing mode is performed, the backup data is discarded. The game state is restored to the initial state (normal game state).

<First RAM clear mode>
In the present embodiment, the power switch 32 is turned "ON" while pressing the RAM clear switch 216 (reset pin 212) while the turning member of the setting key insertion portion 218 is in the OFF posture. Then, the game machine 1 shifts to the first RAM clear mode immediately after the game machine 1 is started (see FIG. 10).

After shifting to the first RAM clear mode, the main CPU 101 performs a first RAM clear process for initializing each storage area within the first RAM clear target area. Specifically, for example, when information such as a jackpot random number is stored in the determination storage area 1030 or the first reserved storage area 1031, a process of erasing this information is performed. In addition, when information indicating that the current game state is the "probability variable game state" is stored in the game state storage area 1039, this information indicates that the current game state is the "normal game state". Perform processing to update the information. If the backup data is stored in the main RAM 103, processing for discarding the backup data is also performed.

In this first RAM clearing mode, for example, a RAM clearing screen is displayed on the liquid crystal screen 5 by superimposing the words "RAM is being cleared" on a solid black background image, and a voice saying "RAM is cleared" is heard from the speaker. 24 is repeatedly output. In this first RAM clear mode, the main CPU 101 causes the performance indicator 215 to display the base value B stored in the performance display storage area 1042 (see FIG. 10). Then, when the first RAM clearing process is completed, the mode automatically shifts to the power recovery mode.

<Setting change mode>
In this embodiment, the RAM clear switch 216 (the reset pin 212 is ) is pressed and the power switch 32 is turned on, the main CPU 101 determines whether or not a detection signal indicating that the inner frame 3 is open is input from the door opening switch 31. do. Here, when it is determined that the detection signal indicating that the inner frame 3 is open is not input, that is, when it is determined that the inner frame 3 remains closed, a predetermined error sound is emitted. Error processing including processing for repeatedly outputting from the speaker 24 is performed. When this error processing is performed, the transition to the setting change mode is prohibited until a predetermined error cancellation operation is performed.
On the other hand, when it is determined that the detection signal indicating that the inner frame 3 is open is input, the game machine 1 shifts to the setting change mode immediately after starting (see FIG. 10).

After shifting to this setting change mode, the main CPU 101 performs the following processing. Specifically, first, the same setting value as that stored in the setting value main storage area 1041 is stored in the setting value temporary storage area 1040 . Then, the stored setting value is lit on the rightmost seven-segment display 215D of the performance indicator 215. FIG. When the set values are displayed, the remaining three 7-segment displays 215A-215C of the performance indicator 215 are in a non-display state.

As will be described in detail later, the gaming machine 1 of the present embodiment has the lowest jackpot probability of "1", the next highest jackpot probability of "2", and the highest jackpot probability of " 3” are available. After shifting to the setting change mode, the main CPU 101 changes the setting values stored in the setting value temporary storage area 1040 to "1" and "2" each time the hall clerk operates the RAM clear switch 216 (reset pin 212). , "3", "1", "2", . At that time, every time the reset pin 212 is operated, the speaker 24 outputs a sound such as "1" or "2", which notifies the set value newly lit and displayed on the 7-segment display 215D.
In FIG. 10, by operating the reset pin 212, "1" is displayed on the rightmost 7-segment display 215D to indicate that the setting value "1" is stored in the setting value temporary storage area 1040. The displayed state is exemplified.

In this setting change mode, for example, a setting change screen is displayed on the liquid crystal screen 5 by superimposing the words "setting is being changed" on a solid black background image, and a voice saying "setting is being changed" is heard from the speaker 24. is repeatedly output from When the set value is switched using the reset pin 212, the speaker 24 outputs voices such as "It is 1" and "It is 2" each time the reset pin 212 is operated. be.

The hall clerk turns the turning member of the setting key insertion portion 218 from the ON position to the OFF position as the first operation for confirming the selection of the setting value while the performance indicator 215 displays the desired setting value. Perform the operation to return to the posture. Specifically, the setting key inserted into the keyhole of the setting key insertion portion 218 is rotated 90 degrees counterclockwise so that the rotating member of the setting key insertion portion 218, which is horizontal, becomes vertical. . In the setting change mode, the main CPU 101 determines based on the detection signal from the setting key switch 217 whether or not the rotating member of the setting key insertion portion 218 has been returned from the ON posture to the OFF posture. Here, when it is determined that the rotating member has returned to the OFF posture, the state of the gaming machine 1 shifts from the setting change mode to the second RAM clear mode (see FIG. 10).

In the present embodiment, in the setting change mode, each time the reset pin 212 is operated, a sound is output from the speaker 24 to inform the newly lit set value such as "1" or "2". However, in order to enhance the effect of suppressing the leakage of the setting value, in another embodiment, the above-described sound for notifying the setting value may not be output.

<Second RAM clear mode>
After shifting to the second RAM clear mode, the main CPU 101 performs the second RAM clear process for initializing each storage area in the second RAM clear process target area. This second RAM clear processing target area includes the above-described first RAM clear processing target area, and the RAM clear processing for this first RAM clear processing target region is the same as the first RAM clear processing performed during the first RAM clear mode. is. On the other hand, the main CPU 101 performs processing for erasing the setting values stored in the setting value temporary storage area 1040 as RAM clear processing specific to the second RAM clear processing, which is not included in the first RAM clear processing. In the second RAM clear mode, when the backup data is stored in the main RAM 103, the backup data is discarded, as in the first RAM clear mode.

In the second RAM clearing mode, for example, a RAM clearing screen is displayed on the liquid crystal screen 5, in which characters "RAM clearing" are superimposed on a solid black background image. Then, the speaker 24 outputs a voice saying "RAM has been cleared". At this stage, the selection of the setting value has not been finalized, and as a second operation for finalizing the selection of the setting value, it is necessary to operate the power switch 32 to turn the power back on. Please turn on the power again to confirm the setting." is repeatedly output from the speaker 24.例文帳に追加The latter audio output is intermittently output until the power switch 32 is turned off.

In response to this, when the hall clerk returns the power switch 32 to the OFF state, the main CPU 101 clears the backup data indicating the setting values stored in the setting value temporary storage area 1040 by the second RAM clearing process to a predetermined area of the main RAM 103 . store in When the hall clerk turns on the power switch 32 again, the above-described power recovery mode is entered.

Note that when the main CPU 101 shifts to the power recovery mode, it determines whether or not backup data indicating the set values is stored in a predetermined area of the main RAM 103 . Here, when it is determined that the backup data indicating the setting value is not stored, it is determined that a normal startup operation has been performed, and the process in the power recovery mode is performed. On the other hand, if it is determined that the backup data indicating the setting value is stored, it is determined that the second RAM clear mode has shifted to the power restoration mode, and the following processing is performed in addition to the processing in the power restoration mode.
That is, the setting values stored in the main setting value storage area 1041 are updated (overwritten) so that they become the same setting values as those indicated by the backup data. The backup data is deleted from the main RAM 103 because it becomes unnecessary when the setting values in the main setting value storage area 1041 are updated.

Also, although not shown in FIG. 10, when the second RAM clear mode is switched to the power restoration mode after the power failure is restored, the speaker 24 outputs a voice saying "The settings have been confirmed" in the power restoration mode. output.

In this way, the main CPU 101 updates the set values stored in the main set value storage area 1041 in accordance with predetermined operations using the power switch 32, the setting key switch 217, and the RAM clear switch 216, so that the jackpot A jackpot probability determined to execute a game is set to one of a plurality of probabilities. The jackpot probability for each set value will be described in detail later with reference to FIG. 13 and the like.

In this embodiment, the setting value cannot be selected unless the power switch 32 is operated to turn on the power again after the setting key is used to return the rotating member of the setting key insertion portion 218 to the OFF position in the setting change mode. A case of not being confirmed will be explained. On the other hand, in another embodiment, for example, a configuration may be adopted in which the selection of the setting value is confirmed on the condition that the rotating member of the setting key insertion portion 218 is returned to the OFF posture.

Also, in this embodiment, a case will be described in which the second RAM clear processing is performed on the second RAM clear processing target area after the setting change mode is shifted to the second RAM clear mode. On the other hand, in another embodiment, immediately after shifting to the setting change mode, the first second RAM clear processing is performed on the second RAM clear processing target area, and after shifting from the setting change mode to the second RAM clear mode, The second RAM clear processing may be performed for the second RAM clear processing target area. In this way, by performing the RAM clear process twice for the area targeted for the second RAM clear process, information stored in a part of the storage area within the area targeted for the second RAM clear process may be initialized due to an error or the like. It is possible to effectively suppress the occurrence of the problem that the

<Setting confirmation mode>
In this embodiment, the turning member of the setting key insertion portion 218 is in the ON position (the setting key 33 is inserted into the keyhole and the turning member of the setting key insertion portion 218 is rotated 90 degrees clockwise). Then, if the power switch 32 is turned "ON" without pressing the RAM clear switch 216, the game machine 1 shifts to the setting confirmation mode immediately after starting (see FIG. 10). In this setting confirmation mode, the setting of the jackpot probability cannot be changed. You can check the setting value of

When shifting to the setting confirmation mode, the main CPU 101 causes the rightmost 7-segment display 215D of the performance indicator 215 to light up and display the setting values stored in the main setting value storage area 1041 . Note that FIG. 10 illustrates a state in which a numerical value of 3 indicating that the current set value is "3" is illuminated on the rightmost 7-segment display.

In this setting confirmation mode, for example, a setting confirmation screen is displayed on the liquid crystal screen 5 by superimposing the words "setting confirmation" on a solid black background image, and the speaker 24 outputs a voice saying "setting confirmation is in progress". is repeatedly output from

After confirming the setting, the hall clerk rotates the setting key 33 counterclockwise by 90 degrees to return the rotating member of the setting key insertion portion 218 to the OFF posture. In response to this, the main CPU 101 terminates the setting confirmation mode and shifts to the power recovery mode. Along with this, the display of the performance indicator 215 changes from the state where the performance indicator 215 lights and displays the setting value related to the jackpot probability to the state where the performance indicator 215 blinks the base value B in the low base state. can be switched.

In this embodiment, immediately after the power is turned on, a case will be described in which the current setting value can be confirmed, but in other embodiments, a non-game state where the game is not progressing will be described. A setting confirmation mode is entered by inserting the setting key into the keyhole of the setting key insertion portion 218 and changing the posture of the rotating member from the OFF posture to the ON posture (for example, when waiting for a customer). You may

[Features of each mode]
FIG. 11 is an explanatory diagram showing features of each mode illustrated in FIG. The five modes described above with reference to FIG. 10 have the following features.

<Characteristics of Power Recovery Mode>
The power recovery mode is characterized in that it is shifted to the power recovery mode by turning the power switch 32 "ON" without pressing the RAM clear switch 216 (reset pin 212) while the setting key insertion portion 218 is in the OFF posture.
Further, the power recovery mode is characterized in that it also shifts from the first RAM clear mode, the second RAM clear mode, and the setting confirmation mode described above with reference to FIG.

In the power recovery mode, the above-described power recovery processing is performed, and a power recovery screen including the characters "power recovery in progress" is displayed on the liquid crystal screen 5, and a voice saying "power recovery in progress" is output from the speaker 24. By doing so, there is a feature that it is notified that the power supply is being restored.

Also, in the power restoration mode, since it is not necessary to display the set value related to the probability of a big hit, the set value is not displayed during the power restoration mode, and the base value B in the low base state is blinking. (see FIG. 10).

In this embodiment, the first RAM clear mode (or the second RAM clear mode) is shifted to the power recovery mode so that the hall clerk can confirm that the power has been properly turned on, as illustrated in FIG. , to notify that the "power supply" has been restored. On the other hand, when the mode is shifted to the first RAM clear mode or the second RAM clear mode, the backup data stored in the main RAM 103 is discarded. It will not restore the state. Therefore, in another embodiment, the transition from the first RAM clear mode (or the second RAM clear mode) to the power recovery mode may be prevented so that the hall clerk does not misunderstand that the RAM clear processing has not been performed.

<Characteristics of the first RAM clear mode>
The first RAM clear mode is entered by turning the power switch 32 "ON" while pressing the RAM clear switch 216 (reset pin 212) while the rotating member of the setting key insertion portion 218 is in the OFF position. There is a feature.

In the first RAM clearing mode, the first RAM clearing process is executed for the above-described first RAM clearing process target area, and a RAM clearing screen including characters "RAM is being cleared" is displayed on the liquid crystal screen 5, and "RAM is cleared." Cleared." is output from the speaker 24 to notify that the first RAM clear processing target area has been cleared.

Also, in the first RAM clear mode, since it is not necessary to display the setting value related to the jackpot probability, the setting value is not displayed during the first RAM clear mode, and the base value B in the low base state is displayed on the performance display device 215. It is characterized by blinking display (see FIG. 10).

<Characteristics of setting change mode>
The setting change mode is entered by turning the power switch 32 "ON" while pressing the RAM clear switch 216 (reset pin 212) while the turning member of the setting key insertion portion 218 is in the ON posture. Characteristic.

Also, in the setting change mode, the setting value can be changed by operating the reset pin 212, and a setting change screen including the text "setting is being changed" is displayed on the liquid crystal screen 5, and the message "setting is being changed" is displayed. There is a feature that the fact that the setting is being changed is notified by outputting the sound from the speaker 24 .

Also, during the setting change mode, the display of the base value B in the low base state is hidden, and the set value selected using the reset pin 212 is lit and displayed on the 7-segment display on the right end of the performance indicator 215 .

Since the setting change mode is a non-playing state in which no game is played and the base value B is not flashed on the performance indicator 215, the winning of the game ball is detected and the prize balls are paid out according to the winning. are both disabled.

Specifically, in the gaming machine 1 of the present embodiment, unless the setting change mode is shifted to the normal mode (through the second RAM clear mode and the power recovery mode), it is assumed that the game ball is launched into the game area 10. It is not determined that the game ball is hit, but the winning of the game ball to the first start port 11 or the normal winning port 14 is detected, and the timer interrupt processing including the processing of paying out the prize ball based on the detection result. A configuration is adopted in which execution is not permitted. Therefore, the main CPU 101 does not determine that a game ball has been launched into the game area 10 during the setting change mode even if the detection signal is output from the count switch 110 . In addition, during the setting change mode, a detection signal from the first start opening switch 111 (or normal winning opening switch 118) is output in response to the game ball passing through the first starting opening 11 (or normal winning opening 14). Even if it is, the main CPU 101 will not determine that a prize has been won, and of course the main CPU 101 will not instruct the payout control board to pay out prize balls.

Also, during the setting change mode, the base calculation program stored in the main ROM 102 is configured not to start. For this reason, during the setting change mode, the main CPU 101 performs the first updating process of updating the total number G stored in the main RAM 103 even if the detection signal is output from the count switch 110 in the low base state. Not performed. In addition, during the setting change mode, the main CPU 101 updates the total number of prize balls H stored in the main RAM 103 even if the detection signal is output from the first starting port switch 111 in the low base state. 2 update processing is not performed. Further, during the setting change mode, the main CPU 101 updates the total number of prize balls F stored in the main RAM 103 even if a detection signal is output from the normal prize winning port switch 117 in the low base state. update processing is not performed. Since none of these three update processes are executed, recalculation of the base value B based on the above formula is not performed.

Also, during the setting change mode, even if the game ball passes through the first starting port 11, it is not determined that the game ball has won the first starting port 11, so the first special symbol determination is executed, or The right to determine the first special symbol is not reserved, and the main CPU 101 does not instruct the payout control board to pay out prize balls.

In this way, the winning of game balls to the first starting port 11 and the normal winning port 14 is invalidated, and the payout of prize balls corresponding to these winnings is also invalidated in the setting confirmation mode, which will be described later. be.

Note that the following configuration may be employed in other embodiments.
That is, the execution of the timer interrupt process of FIG. 21 is permitted even during the setting change mode, and the main CPU 101, when a detection signal is output from the first starting opening switch 111 (or normal winning opening switch 118), first While it is determined that the game ball has entered the starting port 11 (or the normal winning port 14), in the prize ball processing of step S7 (see FIG. 21), the payout control board is not instructed to pay out the prize balls. may be adopted. In this case, since the game ball win itself is valid, the total number G, the total number H of prize balls, and the total number F of prize balls stored in the main RAM 103 may be updated as appropriate. During the mode, since the game is not being played, it is preferable to adopt a configuration in which the base calculation program is not activated as in the present embodiment, and not to update the above variables.

Returning to FIG. 10, when the setting key is operated in the setting change mode to return the turning member of the setting key insertion portion 218 from the ON posture to the OFF posture, the second RAM clear mode is entered.

<Characteristics of the second RAM clear mode>
In the second RAM clear mode, the second RAM clear process accompanying the setting change process in the setting change mode is executed for the above-described second RAM clear process target area. During this second RAM clearing mode, the second RAM is cleared by displaying a RAM clearing screen including the characters "RAM clearing" on the liquid crystal screen 5 and outputting a voice "RAM has been cleared" from the speaker 24. It is characterized in that it is notified that the area to be processed has been cleared.

In order to prompt the hall clerk to turn the power back on (turn the power switch 32 "OFF" and then "ON" again) as a setting confirmation operation for confirming the setting value selected by the hall clerk, " Please turn the power back on to fix the settings.” is output from the speaker 24 .

Also, in the second RAM clear mode, since it is not necessary to display the setting value related to the jackpot probability, the setting value is not displayed during the second RAM clear mode, and the base value B in the low base state is displayed on the performance display device 215. It is characterized by blinking display (see FIG. 10).

<Features of setting confirmation mode>
The setting confirmation mode is entered by turning the power switch 32 "ON" without pressing the RAM clear switch 216 (reset pin 212) while the turning member of the setting key insertion portion 218 is in the ON posture. There is
This setting confirmation mode is a mode in which the current set value can be confirmed. be done.

If the setting key is operated in the setting confirmation mode to return the rotating member of the setting key insertion portion 218 to the OFF position, the power recovery mode is entered.

Also, although not shown in the figure, in the normal mode during the game in which the game progresses as the main CPU 101 repeatedly executes the timer interrupt processing illustrated in FIG. Also, operations on the RAM clear switch 216 (reset pin 212) are invalid, and processing corresponding to these operations is not performed. In other words, these operations are valid only in the five modes described above based on FIG. 10, excluding the normal mode.

[About the game flow]
FIG. 12 is an explanatory diagram for explaining the flow of the game. As illustrated in FIG. 12, the gaming machine 1 of the present embodiment controls the game in one of the above-described "normal gaming state", "probability variable gaming state", and "time-saving gaming state". .

A game ball hit to the right by the player does not enter the first starting hole 11, but enters the second starting hole 12. - 特許庁However, in the low base state, it is difficult to open the second starting port 12, and even if it is opened, the opening time is short. Therefore, when the game is controlled in the low base state (corresponding to the "normal game state" in the present embodiment), the player will play the game by hitting the first start port 11 to the left. Become.

When the game ball struck left in the normal game state wins the first starting port 11, the first special symbol determination is executed. Here, when it is determined to execute a jackpot game, the first special pattern display device 41 variably displays the first special pattern, and then the jackpot pattern is stop-displayed as the first special pattern.

Here, when the jackpot pattern indicating that the probability variable jackpot is stopped and displayed (see FIG. 12 (A)), the jackpot game is executed, and after the jackpot game ends, the probability variable game state is substantially until the next jackpot. The game is controlled (see FIG. 12(B)). On the other hand, when the jackpot pattern indicating the normal jackpot is stopped and displayed (see FIG. 12(C)), the jackpot game is executed, and after the jackpot game ends, if it is not determined to be a jackpot midway through, The game is controlled in the "normal game state" until the second special symbol determination (or first special symbol determination) is performed, for example, 80 times (see FIG. 12(D)). In addition, in the gaming machine 1 of the present embodiment, when the determination result of the first special symbol determination is a jackpot, the percentage of the jackpot symbols indicating that the probability variable jackpot is stopped and displayed is 60%, which is a normal jackpot. The percentage of stop-display of the jackpot symbol indicating that the winning is set to 40%.

As exemplified in FIG. 12, when shifting to the "probability variable gaming state" or the "time-saving gaming state", the second starting port 12 is a high base state in which the game ball is more likely to win than the first starting port 11 Become. When the game is controlled in this high base state, the player plays the game by hitting the second starting hole 12 to the right. Further, in the present embodiment, the second special symbol determination is preferentially digested over the first special symbol determination. Therefore, basically, the second special symbol determination is performed in the "probability variable gaming state" or the "time-saving gaming state".

When the game ball passes through the gate 16 in the "probability variable game state", normal symbol determination is performed. As described above, in the normal symbol determination in the "probability variation gaming state", it is determined to open the second start port 12 at a rate of 12/12, and the opening time of the second start port 12 is relatively long ( 1.6 seconds×3 times in this embodiment). Therefore, the game ball hit to the right area of the game area 10 by hitting to the right easily wins the second starting hole 12, and the second special symbol determination is performed in a high probability state. Therefore, in the "probability variable gaming state", it is easier for the player to hit the jackpot than in the "normal gaming state".

When the right-handed game ball wins the second starting port 12, the second special symbol determination is performed, and after the second special symbol is variably displayed, the second special symbol indicates the determination result of the second special symbol determination. appears stopped. Here, when it is determined by the second special symbol determination that the big winning game is not to be executed, the "losing symbol" is stop-displayed as the second special symbol. On the other hand, when it is determined that the jackpot game is to be executed, the "jackpot pattern" is stopped and displayed as the second special pattern. At that time, in the gaming machine 1 of the present embodiment, the jackpot symbol indicating that the probability variable jackpot is displayed at a rate of 60% is stopped, and after the jackpot game ends, it shifts to the "variable probability game state" again (Fig. 12 (E ) and (B)), 40% of the jackpot symbols indicating that it is a normal jackpot are stopped and displayed, and after the jackpot game ends, the game shifts to a “time-saving game state” (FIGS. 12 (F) and (G) reference).

On the other hand, when the game shifts to the "time saving game state" after the jackpot game ends, the second special symbol determination is performed in the same low probability state as the "normal game state". Here, when it is determined that the big winning game is to be executed until the 80th second special symbol determination is performed in the "time saving game state", the "big winning symbol" is stopped and displayed as the second special symbol. At that time, the jackpot pattern indicating that it is a probability variable jackpot is displayed at a rate of 60%, and after the jackpot game ends, it shifts to the "variable probability game state" (see FIGS. 12 (I) and (B)), 40% The jackpot symbols indicating the normal jackpot are stopped and displayed at a rate of , and after the jackpot game ends, the state shifts to the "time-saving game state" again (see FIGS. 12(H) and (G)).

In addition, if it is not determined to execute a big hit game even once 80 times of special symbol determination (basically the second special symbol determination) is performed, a special indicating the determination result of the 80th special symbol determination After the symbols are stopped and displayed, the game state shifts from the "time-saving game state" to the "normal game state" (see FIG. 12(J)).

[Relationship between set value and jackpot probability]
Next, referring to FIG. 13, the relationship between the set values stored in the main set value storage area 1041 and the jackpot probability will be described. Here, FIG. 13 is an explanatory diagram for explaining the setting related to the jackpot probability.

In the gaming machine 1 of the present embodiment, the setting value stored in the main setting value storage area 1041 changes the probability of execution of the jackpot game. Specifically, when the jackpot probability determined to execute the jackpot game is relatively low low probability state (in this embodiment, "normal game state" and "time-saving game state" correspond to this), setting When the set value stored in the main value storage area 1041 is "1" (low setting), the probability of the jackpot is set to 1/220, and the set value stored in the main set value storage area 1041 is set to 1/220. If it is "2" (medium setting), the jackpot probability is set to 1/200, and if the setting value stored in the main setting value storage area 1041 is "3" (high setting), The jackpot probability is set to 1/180.

In addition, in the gaming machine 1 of the present embodiment, the jackpot probability in a high-probability state in which the jackpot probability determined to execute the jackpot game is relatively high (in the present embodiment, "variable probability game state" corresponds to this). The ratio of the jackpot probability in the low probability state is fixed at 8 times regardless of the set value.
Therefore, in the high-probability state, if the setting value stored in the main setting value storage area 1041 is "1" (low setting), the jackpot probability is 1/27.5 (=1/220× 8 times), and when the setting value stored in the setting value main storage area 1041 is "2" (medium setting), the jackpot probability is 1/25 (= 1/200 x 8 times). When the setting value set and stored in the main setting value storage area 1041 is "3" (high setting), the jackpot probability is set to 1/22.5 (=1/180×8 times). be.

Thus, in the present embodiment, since the ratio of the jackpot probability in the high probability state and the jackpot probability in the low probability state is fixed regardless of the set value, when transitioning from the low probability state to the high probability state In addition, it is possible to easily and effectively suppress the problem that the magnitude relationship of the jackpot probability for each setting is greatly disrupted.

By the way, regarding the jackpot probability in the low probability state, for example, the jackpot probability when the setting value is set to the highest setting "3" is changed to the jackpot probability when the setting value is set to the lowest setting "1". If the difference in the jackpot probability between the lowest setting and the highest setting is too large, such as when the jackpot probability is set to twice the jackpot probability, the performance of the gaming machine 1 changes more than necessary depending on the setting. may occur.

For this reason, the jackpot probability in the low probability state when the setting value is set to the lowest setting "1" is compared to the average jackpot probability, which is the average value of all the set jackpot probabilities in the low probability state, for example It is preferably set to a value of -10% or higher. Also, the jackpot probability in the low-probability state when the set value is set to the maximum setting of "3" is preferably set to a value of, for example, +10% or less with respect to the average jackpot probability. This also applies to cases where the number of setting steps is other than three.

[Modified example regarding setting and jackpot probability]
In addition, in another embodiment, the following configuration may be adopted.
That is, in the present embodiment, a case will be described in which the setting regarding the jackpot probability is represented by consecutive natural numbers such as "1" (low setting), "2" (middle setting), and "3" (high setting). On the other hand, in other embodiments, the setting regarding the jackpot probability may be represented by discrete natural numbers such as "1" (low setting), "3" (medium setting), and "5" (high setting). . Also, the information representing the setting regarding the jackpot probability is not limited to a natural number, and may be, for example, a unique name such as "L" (low setting), "M" (middle setting), or "H" (high setting).

In addition, in the present embodiment, a case in which three stages of settings are provided for the probability of a big win will be described as an example, but the number of stages of settings is not limited to this, and may be, for example, two stages. However, the number may be four or more.
However, if the number of setting steps becomes too large, it is expected that the setting operation of the setting value by the hall clerk becomes complicated, so the number of setting steps is, for example, "6" or less. is preferred.

In addition, in the present embodiment, three levels of settings are provided for the jackpot probability in the low-probability state, but in other embodiments, the jackpot probability in the low-probability state may not be set. That is, for example, there is no setting for the jackpot probability in the low-probability state (the jackpot probability is fixed), and a configuration may be adopted in which there is a setting difference regarding the jackpot probability in the high-probability state. In this case, for example, the jackpot probability corresponding to the setting value "1" (low setting), the jackpot probability corresponding to the setting value "2" (medium setting), and the jackpot corresponding to the setting value "3" (high setting) As an example, it is configured such that the probabilities are all the same.

Also, in this embodiment, the case where the ratio of the jackpot probability in the high-probability state and the jackpot probability in the low-probability state is set to 8 times will be described. Other values are possible. That is, the ratio may be, for example, 3 times, which is less than 8 times, or 9 times, which is greater than 8 times.

In this embodiment, the setting value is set to "1" (low setting), the setting value is set to "2" (medium setting), and the setting value is set to "3" (medium setting). High setting) and the case where the ratio of the jackpot probability in the high probability state and the jackpot probability in the low probability state are completely the same will be described.
On the other hand, if the ratios cannot be perfectly matched, the ratios for each setting may be approximated.

For example, if the jackpot random number can take 19800 random numbers from "0" to "19799", 110 random numbers for the set value "3" (high setting) as the winning value in the low probability state is prepared, it is possible to set the jackpot probability to 1/180 (=110/19800). By preparing 1100 random numbers for the set value "3" (high setting) as winning values in the high-probability state, the jackpot probability in the high-probability state is exactly 10 times the jackpot probability in the low-probability state. It can be set to double 1/18 (=(110*10)/19800).

On the other hand, due to the number of values that can be taken by the jackpot random number, if a winning value that is 10 times the winning value in the low probability state is prepared, the jackpot probability in the high probability state and the low probability state If the ratio with the jackpot probability slightly exceeds 10 times, the winning value in the high probability state is slightly reduced from the number of 10 times, and the ratio does not exceed 10 times and the ratio should be approximated by a factor of 10.

[Regarding special symbol judgment using random numbers]
<About processing based on jackpot random numbers>
Next, with reference to FIG. 14, the special symbol determination using the jackpot random number, the symbol random number, and the reach random number will be described. Here, FIG. 14 is an explanatory diagram for explaining various random numbers.

The jackpot random numbers exemplified in FIG. 14(A) are random numbers used in the jackpot determination process (step S309 in FIG. 26) to determine whether or not to execute the jackpot game, and the probability that the jackpot game will be executed is A relatively low low-probability state and a high-probability state with a relatively high probability of being determined to execute a jackpot game are individually set. In addition, in the present embodiment, different numbers of winning values are prepared depending on the set value for each of the low-probability state and the high-probability state (see FIG. 14A).

As illustrated in FIG. 14A, the main ROM 102 stores 90 winning values as jackpot random number winning values with respect to the set value "1" (low setting) in the low probability state. 99 winning values are stored as jackpot random number winning values for the set value "2" (middle setting) in the state, and jackpot random number winning values are stored for the set value "3" (high setting) in the low probability state. 110 winning values are stored as .

When the main CPU 101 acquires a jackpot random number while the game is being controlled in a low-probability state, if the set value stored in the set value main storage area 1041 is "1", the acquired jackpot random number is It is determined whether or not to execute a jackpot game based on whether or not the winning value matches any one of the 90 winning values corresponding to the set value "1". Also, if the set value stored in the main set value storage area 1041 is "2", whether the obtained jackpot random number matches any of the above 99 winning values corresponding to the set value "2". Based on whether or not, it is determined whether or not to execute the jackpot game. Further, when the set value stored in the main set value storage area 1041 is "3", whether the acquired jackpot random number matches any one of the above 110 winning values corresponding to the set value "3" Based on whether or not, it is determined whether or not to execute the jackpot game.

In the present embodiment, the possible range of the jackpot random numbers is 19800 from "0" to "19799" in both the low-probability state and the high-probability state. Therefore, the jackpot probability is 1/220 (=90/19800) when the low probability state and the setting value "1" are set, and when the low probability state and the setting value "2" are set. The jackpot probability is 1/200 (=99/19800) when the (See FIGS. 13 and 14(A)).

Further, as illustrated in FIG. 14A, the main ROM 102 stores 720 winning values as jackpot random number winning values for the setting value "1" (low setting) in the high probability state. 792 winning values are stored as the winning values of the jackpot random numbers for the set value "2" (medium setting) in the high probability state, and the jackpot random numbers are stored for the setting value "3" (high setting) in the high probability state. 880 winning values are stored as winning values.

Therefore, the jackpot probability when the high probability state and the set value "1" is set is 1/27.5 (=720/19800), and the high probability state and the set value "2" is The jackpot probability when set is 1/25 (=792/19800), and the jackpot probability when it is in a high probability state and the set value "3" is set is 1/22.5 (=880). /19800) (see FIGS. 13 and 14(A)).

<Regarding processing based on pattern random numbers>
When the main CPU 101 determines that a jackpot game is to be executed, the symbol random number obtained together with the jackpot random number used for the determination matches which random number among the random numbers set in advance for each type of jackpot. to determine the type of jackpot.

(Types of jackpots related to the first special symbol determination)
As illustrated in FIG. 14(B), in this embodiment, there are three types of "10R probability variable jackpot", "5R probability variable jackpot", and "5R normal jackpot" as the types of jackpots by winning the first starting gate. prepared. Here, the ``10R probability variable jackpot'' (10R probability variable) is a jackpot in which the game is controlled in the ``variable probability game state'' until the next jackpot after the jackpot game of 10 long open round games is executed. The "5R probability variable jackpot" (5R probability variable) is a jackpot in which the game is controlled in the "variable probability game state" until the next jackpot after the jackpot game of five long open round games is executed. "5R normal jackpot" (5R normal) is a jackpot in which the game is controlled in a "time-saving game state" until 80 special symbol determinations are performed after a jackpot game that performs 5 long open round games is executed. is.

As illustrated in FIG. 14(B), in this embodiment, when the low base state ("normal game state" in this embodiment), the game ball is acquired in response to winning the first start port 11 A main ROM 102 stores a random number value for determining the type of jackpot according to the winning of the first starting port when the given jackpot random number coincides with the winning value and results in a jackpot. Specifically, 40 random numbers are stored for the jackpot symbol X1 indicating the 10R probability variation, 200 random numbers are stored for the jackpot symbol X2 indicating the 5R probability variation, and 5R. 160 random numbers are stored for the jackpot symbol X3 indicating normal.

In this embodiment, the possible range of the symbol random number is set to "0" to "399" regardless of whether the base state is the low base state or the high base state. Therefore, when the main CPU 101 determines a jackpot according to the winning of the first starting gate, the ratio of determining the type of the jackpot to the 10R variable probability jackpot is 10% (=40/400×100), and the 5R variable probability jackpot. 50% (=200/400×100), and the ratio to determine the 5R normal jackpot is 40% (=160/400×100).

In other words, when the determination result of the first special symbol determination is "big win", the first special symbol display 41 stops displaying the big winning symbol X1 at a rate of 10% as the first special symbol, and 50% of the first special symbol. The jackpot pattern X2 is stop-displayed at a rate of 40%, and the jackpot pattern X3 is stop-displayed at a rate of 40%.

(Types of jackpots related to second special symbol determination)
As illustrated in FIG. 14 (C), in the present embodiment, as the types of jackpots by the second starting gate winning, similar to the types of jackpots by the first starting gate winning, "10R probability variable jackpot", "5R probability variable There are three types of jackpots, ie, 5R normal jackpots.

As illustrated in FIG. 14 (C), in this embodiment, the game ball wins the second start port 12 when in a high base state (in this embodiment, "probability variable gaming state" or "time-saving gaming state") When the jackpot random number obtained in response to the winning coincides with the winning value and results in a jackpot, the main ROM 102 stores a random value for determining the type of jackpot according to the winning of the second starting opening. there is Specifically, 200 random numbers are stored for the jackpot symbol Y1 indicating the 10R probability variation, 40 random numbers are stored for the jackpot symbol Y2 indicating the 5R probability variation, and 5R. 160 random numbers are stored for the jackpot symbol Y3 indicating normal.

Therefore, when the main CPU 101 determines a jackpot according to the winning of the second starting opening, the ratio of determining the type of the jackpot to the 10R variable probability jackpot is 50% (=200/400×100), and the 5R variable probability jackpot. 10% (=40/400×100), and the ratio to determine the 5R normal jackpot is 40% (=160/400×100).

In other words, when the determination result of the second special symbol determination is "big win", the second special symbol display device 42 stops displaying the big winning symbol Y1 at a rate of 50% as the second special symbol, and 10%. The jackpot pattern Y2 is stop-displayed at a rate of 40%, and the jackpot pattern Y3 is stop-displayed at a rate of 40%.

<Processing based on reach random numbers>
When the main CPU 101 determines not to execute a jackpot game, the reach random numbers obtained together with the jackpot random numbers and pattern random numbers used for the determination are divided into random values corresponding to the reach effect and random values corresponding to the non reach effect. Based on which random value of the numerical value matches, it is determined whether to perform a ready-to-win performance or to perform a non-reachable performance.

As exemplified in FIG. 14(D), in the present embodiment, when the determination result of the special symbol determination is "losing", the main random value is for determining whether or not to perform the reach presence effect. It is stored in ROM 102 . Specifically, as random numbers to be compared with the ready-to-win random numbers, 40 random numbers are stored for the ready-to-reach effect, and 360 random numbers are stored for the no-reach effect.

In this embodiment, the possible range of the reach random number acquired in response to the winning of the game ball in the first starting port 11 or the second starting port 12 is set to "0" to "399". For this reason, the ratio determined to perform the effect with reach is 10% (=40/400×100), and the percentage determined to perform the effect without reach is 90% (=360/400×100). is.

When the main CPU 101 determines to carry out the ready-to-win effect based on the ready-to-win random numbers, the effect control board 130 selects the variable effect pattern of decorative symbols for performing the ready-to-win effect as the variable pattern of the special symbols. Choose a variation pattern. Conversely, when it is determined to carry out the non-reach performance based on the reach random number, the variable performance pattern of decorative symbols in which the ready-to-win performance is not performed is selected in the performance control board 130 as the variation pattern of the special symbols. Choose a variation pattern.

In addition, the following can be said from the notation of FIG. 14 explained so far.
That is, while the jackpot probability in the low-probability state and the high-probability state changes according to the set value stored in the set value main storage area 1041, the game is controlled in the "probability variable gaming state" after the jackpot game ends. It can be said that the probability variable ratio, which is a ratio, does not change depending on the setting value stored in the main setting value storage area 1041 .

Similarly, while the jackpot probability in the low-probability state and the high-probability state changes according to the set value stored in the set value main storage area 1041, the jackpot patterns X1 to X3 and the jackpot patterns Y1 to Y3 are selected respectively. It can be said that the ratio to be set does not change depending on the setting value stored in the main setting value storage area 1041 .

Similarly, the ratio of selecting the jackpot pattern X3 (see FIG. 14(B)) indicating the 5R normal jackpot, and the jackpot pattern Y3 (see FIG. 14(C)) indicating the 5R normal jackpot ) is selected does not change depending on the set value stored in the set value main storage area 1041, so the number of time reductions after the jackpot game is completed (80 times in this embodiment: see FIG. 12 ) does not change depending on the setting.

This is because, as shown in FIGS. 14B and 14C, the set values stored in the set value main storage area 1041 do not change the number of random numbers to be compared with the symbol random numbers. it is obvious.

[Description of special pattern variation pattern]
Next, with reference to FIG. 15, a variation pattern of special symbols will be described. Here, FIG. 15 is an explanatory diagram for explaining the variation pattern table used for selecting the variation pattern.

When a game ball wins in the first starting port 11 (or the second starting port 12), a fluctuation pattern random number is acquired together with the above-described jackpot random number, symbol random number, and reach random number. This variation pattern random number is a random number used in the variation pattern selection process for selecting the variation pattern of the special symbol.

(Regarding selection of variation pattern at the time of jackpot)
When the main CPU 101 determines that the game is a big win based on the big win random number, the main CPU 101 refers to the big win variation pattern table (see FIG. 15A) stored in the main ROM 102 and selects a special symbol variation pattern.

As illustrated in FIG. 15A, in the big hit variation pattern table, variation pattern random numbers and special symbol variation patterns are associated with each other. The possible range of the acquired variation pattern random numbers is set to "0" to "399" in this embodiment. In the jackpot variation pattern table, different random numbers are associated with six variation patterns, ie, first to sixth variation patterns with different variation times.

When the main CPU 101 determines that it is a jackpot, the variation pattern random number obtained together with the jackpot random number or the like is associated with each of the first to sixth variation patterns in the jackpot variation pattern table. Any one variation pattern is selected based on whether it matches the random value. For example, when the acquired variation pattern random number matches the random value corresponding to the first variation pattern, the first variation pattern is selected, and the acquired variation pattern random number matches the random value corresponding to the fourth variation pattern In that case, select the fourth variation pattern.

As illustrated in FIG. 15(A), in the jackpot variation pattern table in this embodiment, 8 random numbers are associated with the first variation pattern, and 32 with respect to the second variation pattern. Random values are associated, 60 random values are associated with the third variation pattern, 80 random values are associated with the fourth variation pattern, and 100 are associated with the fifth variation pattern. , and 120 random numbers are associated with the sixth variation pattern.

Therefore, when the determination result of the special symbol determination is a big hit, the first variation pattern with a variation time of 30 seconds is selected at a rate of 2% (= 8/400 x 100), and the variation time is 45 seconds. A certain second variation pattern is selected at a rate of 8% (= 32/400 x 100), and a third variation pattern with a variation time of 60 seconds is selected at a rate of 15% (= 60/400 x 100), The fourth variation pattern with a variation time of 70 seconds is selected at a rate of 20% (= 80/400 x 100), and the fifth variation pattern with a variation time of 90 seconds is selected at 25% (= 100/400 x 100). , and the sixth variation pattern whose variation time is 120 seconds is selected at a rate of 30% (=120/400×100).

(Regarding the selection of the variation pattern when performing a reach effect at the time of loss)
When the main CPU 101 determines that there is a loss based on the jackpot random number, and determines that the reach effect is to be performed based on the reach random number acquired together with the jackpot random number, the main CPU 101 determines that the reach effect is performed based on the hit random number. The variation pattern of the special symbol is selected with reference to the variation pattern table (see FIG. 15(B)).

As illustrated in FIG. 15(B), in the reach variation pattern table, different random numbers correspond to each of the six variation patterns of the seventh variation pattern to the twelfth variation pattern with different variation times. attached.

When the main CPU 101 determines that it is a loser based on the acquired random numbers for the jackpot, and determines that the effect with reach is performed based on the acquired random numbers, the variation pattern random number acquired together with these random numbers Any one variation pattern is selected based on which random number values associated with each of the seventh variation pattern to the twelfth variation pattern in the variation pattern table match. For example, when the acquired variation pattern random number matches the random value corresponding to the 8th variation pattern, select the 8th variation pattern, and the acquired variation pattern random number matches the random value corresponding to the 11th variation pattern In this case, the 11th variation pattern is selected.

As illustrated in FIG. 15 (B), in the losing variation pattern table in this embodiment, 140 random numbers are associated with the seventh variation pattern, and 100 with respect to the eighth variation pattern. Random values are associated, 80 random values are associated with the 9th variation pattern, 40 random values are associated with the 10th variation pattern, and 28 with respect to the 11th variation pattern. , and 12 random numbers are associated with the 12th variation pattern.

Therefore, when it is determined that the determination result of the special symbol determination is a loss, and it is determined that the reach presence effect is performed, the seventh variation pattern with a variation time of 30 seconds is 35% (= 140/400 x 100). The eighth variation pattern with a variation time of 45 seconds is selected at a rate of 25% (=100/400×100), and the ninth variation pattern with a variation time of 60 seconds is selected at a rate of 20% (=80 / 400 × 100), the 10th variation pattern with a variation time of 70 seconds is selected at a rate of 10% (= 40/400 x 100), and the 11th variation pattern with a variation time of 90 seconds is selected at a rate of 7% (=28/400×100), and the twelfth variation pattern whose variation time is 120 seconds is selected at a rate of 3% (=12/400×100).

(Regarding the selection of the variation pattern when performing a no-reach effect at the time of loss)
When the main CPU 101 determines that there is a loss based on the jackpot random number and determines that a no-reach effect is to be performed based on the reach random number acquired together with the jackpot random number, the main CPU 101 determines that the win-win effect stored in the main ROM 102 is performed. A variation pattern of special symbols is selected with reference to the variation pattern table (see FIG. 15(C)).

In the change pattern table for losing (see FIG. 15(C)), whether it is in a low base state or a high base state, the number of pending special symbol determinations when the variable display of this special symbol is started, It is associated with the variation pattern of the special symbol.

When the current state is the low base state, the main CPU 101 determines the special symbol (basically the first special symbol determination) when starting the variable display of the special symbol (basically the first special symbol). When the number of reservations is '0' or '1', the thirteenth variation pattern in which the variation time of the special symbol is 13 seconds is selected, and when the number of reservations is '2', the variation time is 8 seconds. is selected, and when the number of reservations is "3", the 15th variation pattern whose variation time is 4 seconds is selected.

On the other hand, when the current state is the high base state, the main CPU 101 determines the special symbol (basically the second special symbol) when starting the variable display of the special symbol (basically the second special symbol). ) is "0" or "1", select the 16th variation pattern in which the variation time of the special symbol is 6 seconds, and if the number of retention is "2", the variation time is The 17th variation pattern which is 4 seconds is selected, and the 18th variation pattern whose variation time is 2 seconds is selected when the number of reservations is "3".

From the description so far based on FIGS. 15A to 15C, the following can be said.
That is, in the gaming machine 1 of the present embodiment, when the determination result of the special symbol determination is a loss and it is determined that the non-reach effect is performed, the reach effect is performed as the variation pattern of the special symbol. A variation pattern with a short variation time is selected (see FIG. 15(C)). On the other hand, when the determination result of the special symbol determination is a big win, it is difficult to select the variation pattern of the special symbol whose variation time is relatively short, and conversely, the variation pattern of the special symbol whose variation time is relatively long is selected. (See FIG. 15A). In addition, when it is determined that the determination result of the special symbol determination is a failure and it is determined that the reach presence effect is performed, the variation pattern of the special symbol whose variation time is relatively short is likely to be selected, and conversely, the variation time is relative. It is difficult to select a fluctuation pattern of special symbols that are relatively long (see FIG. 15(B)).
From these things, it can be said that the longer the fluctuation time of the special symbols, the higher the reliability of the big win (the possibility of executing the big win game).

15, in the gaming machine 1 of the present embodiment, the number of random numbers associated with each variation pattern is determined by the set value stored in the main set value storage area 1041. Since there is no change, it can be said that there is a feature that the selection ratio of each variation pattern does not change depending on the setting related to the jackpot probability.

In another embodiment, in addition to the variation pattern random number and the special symbol variation pattern, the big hit variation pattern table and the reach variation pattern table are further associated with the number of pending special symbol determination at the start of the variation. You may use the fluctuation pattern table provided.

In addition, in this embodiment, when various random numbers are acquired according to the winning of the game ball to the first starting port 11, and when various random numbers are acquired according to the winning of the game ball to the second starting port 12 , the case of using the same variation pattern table (variation pattern table for jackpot and variation pattern table for reach) will be described, but in another embodiment, the variation pattern table to be used is changed according to the winning start opening. good too.

[Screen configuration example of liquid crystal screen 5 in normal game state]
FIG. 16 is a screen diagram illustrating the screen configuration of the liquid crystal screen 5 in the normal game state. On the liquid crystal screen 5 when the game is being controlled in the normal game state, as illustrated in FIG.

During the variable display of the special symbols, the decorative symbols displayed in the decorative symbol display area 50 and the like may not be completely stationary and may continue to move slightly as if shaking on the spot. On the other hand, when the special symbols are stopped and displayed, the decorative symbols are completely stationary. For this reason, in the following explanation, the state in which the decorative pattern is completely stationary is called "real stop", and the state in which the decorative pattern does not stop completely and continues to move slightly on the spot is called "pseudo stop". A clear distinction shall be made between the two.

<Decorative Design Display Area 50 and Decorative Designs>
The decorative design display area 50 is a display area in which a decorative design for notifying the determination result of the special design determination is displayed. When the special symbols are stopped, the decorative symbol display area 50 displays, for example, a part of the decorative symbol row consisting of a numerical row in which the numbers 1 to 9 are continuously written vertically from the bottom to the top. are stopped so that three are lined up in the horizontal direction. In this state, for example, when a game ball wins in the first starting port 11, the first special symbol determination is executed, and accordingly, the variable display of the first special symbol and the variable display of the decorative symbol are started. Then, at the end of the variable display of the first special symbol, the three decorative symbols are stopped in a pseudo manner in which the determination result of the first special symbol determination is shown, and the first special symbol to notify the determination result of the first special symbol determination. is stopped and displayed, the above-mentioned three decorative symbols are actually stopped.

<Holding icon display area 51>
The pending icon display area 51 is an area where a pending icon indicating that the first special symbol determination is pending is displayed. In the gaming machine 1, when the game ball wins the first start port 11 in a situation such as during the variable display of the special symbols or during the jackpot game, when the special symbol determination and the variable display of the special symbols cannot be started immediately, the first special The right to determine the symbol is reserved up to a predetermined number (four in this embodiment).

Thus, when the right of the first special symbol determination is reserved, in the first reservation area 51, the same number of reservation icons as the number of reservations of the first special symbol determination indicated by the first special symbol reservation display 43 are displayed. be done. FIG. 16 illustrates a state in which four pending icons are displayed in the pending icon display area 51 in order to suggest that the number of pending first special symbol determination is the maximum "4". In FIG. 16, each pending icon is assigned a number in order to express the order in which the pending icons are displayed in an easy-to-understand manner.

When the game is controlled in the normal game state, basically no game balls enter the second starting port 12, and therefore the right to judge the second special symbol is not reserved. Therefore, the suspension icon relating to the second special symbol determination is not displayed on the liquid crystal screen 5, and the display area for displaying the suspension icon is not formed.

(About icon change effect)
In the gaming machine 1 of the present embodiment, the hold icon is normally displayed as a white hold icon. On the other hand, when the suspended icon is displayed in the suspended icon display area 51, an icon change effect may be performed in which the color of the suspended icon changes. When this icon change effect is performed, the white pending icon changes to a pending icon of colors such as blue, green, red, gold, and rainbow colors that suggest the reliability of the big win. Colors other than white exemplified here are arranged in descending order of jackpot reliability. A rainbow color can only be selected if it results in a "jackpot". Gold and red colors are likely to be selected in the case of a big win, but are less likely to be selected in the case of a loss, and are likely to be selected when the variation time of the special symbols is set to a relatively long time. Green is likely to be selected when a "big hit" or "losing" is set to a medium variation time of the special symbol. The blue color is likely to be selected when it is "losing" or when it is "losing" and the fluctuation time of the special symbol is set to a relatively short time.

Here, the case where the icon change effect is performed once has been described as an example. In some cases, the icon change effect is performed a plurality of times for one reserved icon.
Also, here, the case where the color of the pending icon that was white when the display of the pending icon was started changed to another display color was explained, but the display color of the newly displayed pending icon was changed from the beginning. , and an icon change effect may be performed for this reserved icon.

Up to this point, the icon change effect performed for the suspended icon displayed in the suspended icon display area 51 has been described. There is also Further, after the icon change effect is performed for the suspended icon displayed in the suspended icon display area 51, when the suspended icon is moved to the area 52 and displayed as the icon, the icon In some cases, an icon change effect targeting is performed.

(About mode transition effect)
In the gaming machine 1 of the present embodiment, when the game is controlled in the normal game state, there is a case where a mode transition effect for shifting the effect mode is performed based on the result of preliminary determination described later. In this embodiment, as the production mode in the normal game state, a plurality of production modes such as a normal mode, a chance mode, and an intense heat zone are prepared. When these production modes are compared, the following can be said. That is, when comparing the normal mode, the chance mode, and the intense heat zone, the type of background image displayed on the liquid crystal screen 5, the display mode of decorative patterns, the type of effect sound output from the speaker 24, etc. different from each other. In addition, the chance mode has higher jackpot reliability than the normal mode, and the super heat zone has higher jackpot reliability than the chance mode.

FIG. 16 illustrates a state in which characters "chance mode" are displayed on the upper left of the liquid crystal screen 5 in order to notify that the production mode has shifted to the chance mode.

In the gaming machine 1 of the present embodiment, when the first special symbol determination for whether or not to execute the jackpot game is executed, the variable display of the first special symbol and the variable display of the decorative symbol are started. Prior to the variation display (hereinafter referred to as "the variation"), using the same random number value as used for the first special symbol determination, a preliminary determination process for determining whether or not to execute a jackpot game is performed. . Then, based on the result of this preliminary determination process, it is determined whether or not to execute the mode transition effect, and in what transition pattern the effect mode is to be shifted in the case of executing the mode transition effect. When this mode transition effect is performed, the effect mode changes before the change starts, the effect mode changes during the change, or the effect occurs both before the start of the change and during the change. Mode shifts.

The transition patterns of the mode transition effect include, for example, the following.
For example, before the change is started, there is a case where a mode transition effect in which the effect mode shifts from the normal mode to the chance mode is performed, and the effect in the chance mode is performed during the change. Also, for example, before the change starts, there is a case where a mode transition effect is performed in which the effect mode shifts from the normal mode to the intense heat zone, and during the change, the effect in the intense heat zone is performed.
Also, for example, before the change starts, the production mode shifts from the normal mode to the chance mode, and at the start of the change (or in the middle of the change), the mode shifts from the chance mode to the intense heat zone. A production is performed, and a production in the intense heat zone may be performed during the change.

(Regarding advance judgment)
In the gaming machine 1 of the present embodiment, when the right to determine the first special symbol is reserved, the main CPU 101 makes a preliminary determination as to whether or not to execute a big winning game before performing the first special symbol determination. . Specifically, based on the jackpot random number obtained according to the winning of the game ball to the first start port 11, if the first special symbol determination is performed, whether it will be determined as "jackpot" Determine in advance whether or not Also, based on the variation pattern random number acquired together with the jackpot random number, which variation pattern is selected as the variation pattern of the first special symbol that is variably displayed according to the execution of the first special symbol determination. It is also determined in advance whether or not The icon change effect described above is performed based on the result of this preliminary determination.

On the other hand, when the game is controlled in the probability variable game state or the time-saving game state, the game ball is likely to enter the second starting port 12, and the right to determine the second special symbol is likely to be reserved. Therefore, when the game is controlled in these gaming states, a pending icon display area separate from the pending icon display area 51 is formed, and the pending icon relating to the second special symbol determination is displayed in the pending icon display area. be done. Although detailed explanation is omitted, the icon change effect is performed for the pending icon related to the second special symbol determination in the same manner as the pending icon related to the first special symbol determination displayed in the pending icon display area 51. It is possible. In this case, based on the preliminary determination result related to the suspension of the second special symbol determination, whether or not to perform the icon change effect, and in the case of performing the icon change effect, what kind of effect pattern etc. are determined. It will be.

<Regarding the area 52>
The area 52 is an area for displaying the icon as a variation suggestive image suggesting that the special symbol is displayed in a variable manner. When the first special symbol determination is executed, the icon is displayed in the area 52 with the start of the variable display of the first special symbol, for example, at the timing when the first special symbol is stopped and displayed. is erased from The erasing timing of the icon is not limited to this, and the icon may be erased during the variable display of the first special symbol.

In addition, the first special symbol determination corresponding to the earliest pending icon displayed in the pending icon display area 51 (the pending icon including the number "1" closest to the area 52: see FIG. 16) is executed. Then, with the start of the variable display of the first special symbol, the pending icon shifts to the area 52 and is displayed as the icon. At that time, if other suspended icons are displayed in the suspended icon display area 51 , those suspended icons are shifted in the direction of approaching the area 52 within the suspended icon display area 51 .

[Flow of production accompanying the variable display of the first special symbol]
FIG. 17 is an explanatory diagram illustrating the flow of the ready-to-win effect. When the first special symbol determination is executed, the first special symbol is variably displayed and then stop-displayed in a mode showing the determination result of the first special symbol determination. On the other hand, on the liquid crystal screen 5, along with the variable display of the first special symbol, the variable display of the decorative design in the decorative design display area 50 (see FIG. 16) is started. The start of the variable display of this decorative pattern is as described above with reference to FIG.

When the determination result of the first special symbol determination is "losing", three decorative symbols (e.g., "368") that indicate losing are displayed in the decorative symbol display area 50 without establishing a reach during the variable display of the first special symbol. After pseudo-stopping the first special symbol that indicates a loss, a win-lose notification effect (here, a loss notification effect) that actually stops these three decorative symbols may be performed. (See FIG. 17(B)).

On the other hand, when the determination result of the first special symbol determination is "big win", and when the determination result of the first special symbol determination is "losing", it is decided to perform the reach effect (based on the reach random number). If so, during the variable display of the first special symbol, the same left symbol and right symbol stop on the active line in a simulated manner to establish a reach. When ready-to-win is established in this way, the same decorative pattern as the ready-to-win pattern (left and right patterns) stops as a middle pattern on the effective line, and the player's expectations for matching patterns are increased. A reach performance is performed.

In this embodiment, four kinds of ready-to-win effects of normal reach, SP ready-to-win, SPSP ready-to-win, and story ready-to-win are prepared as ready-to-win effects that can be executed with the variable display of the first special symbol (see FIG. 17).

Normal reach (see FIG. 17(D)) is a reach effect with relatively low jackpot reliability (for example, jackpot reliability: about 2%). When the ready-to-win state develops to the normal ready-to-win state, the scroll speed of the middle pattern row, which has been scrolled at high speed between the two ready-to-win patterns (left and right patterns), gradually decreases.

Here, the determination result of the first special symbol determination is "losing", for example, the seventh variation pattern (see FIG. 15 (B)) having a variation time of 30 seconds at the start of the variation display of the first special symbol If it is selected, a decorative pattern different from the ready-to-win pattern as a middle pattern is pseudo-stopped on the effective line, and then three decorative patterns (for example, reach-losing numbers such as "434") on the effective line are actually stopped. An effect (here, a loss notification effect: see FIG. 17(B)) is performed.

On the other hand, the determination result of the first special symbol determination is "jackpot", for example, the first variation pattern (see FIG. 15 (A)) whose variation time is 30 seconds at the start of the variation display of the first special symbol is selected. If it is, the same decorative pattern as the ready-to-win pattern is pseudo-stopped on the active line as a medium pattern, and then three decorative patterns (for example, doubles such as "444") on the active line are stopped. (Here, a hit notification effect: see FIG. 17(B)) is performed.

On the other hand, when a variation pattern with a relatively long variation time of the first special symbol is selected, the same decorative symbol as the ready-to-win pattern is displayed on the effective line without performing the above-mentioned hit notification effect or loss notification effect in normal reach. The scrolling display of the middle pattern row continues even after passing, and develops into SP reach, SPSP reach, or story reach.

SP Reach and SPSP Reach are configured, for example, as a battle production in which one's own character fights an enemy character. In the second half, the fighting enemy characters are common. That is, for example, when a battle with enemy character A is developed in SP reach in the first half of the battle, a battle with the same enemy character A is developed in SP reach in the latter half of the battle.

When SP reach and SP reach are compared, SP SP reach has higher hit reliability than SP reach, and hit and lose are reported at the end of SP reach compared to the case where hit and lose are reported at the end of SP reach. In the case where the player wins, it is easier to be notified of the jackpot.

In the gaming machine 1 of the present embodiment, the normal reach (see FIG. 17(D)) develops into the SP reach (see FIG. 17(E)) in the first half of the battle, and the hit/loss of FIG. A notification effect (hit notification effect or loss notification effect) may be performed.

In addition, there are cases where normal reach develops into SPSP reach via SP reach, and cases where normal reach develops directly into SPSP reach without going through SP reach. 17(B) win/lose notification effect (hit notification effect or loss notification effect) is performed.

On the other hand, story reach (see FIG. 17(G)) is an effect in which a specific story is developed on the liquid crystal screen 5 and whether or not the ending of the story becomes a predetermined ending indicates whether or not the player has won a big hit. It is configured. In the present embodiment, when four types of ready-to-win productions are compared, story ready-to-win jackpot reliability is the highest, and normal ready-to-win is directly developed into story-to-win.

The type of ready-to-win effect and the way of developing the ready-to-win effect illustrated in FIG. 17 are merely examples, and other types of ready-to-win effect and the way of developing the ready-to-win effect may be used.

[About the zebra effect]
FIG. 18 is a screen diagram for explaining the zebra effect. In the gaming machine 1 of the present embodiment, various advance notice effects suggesting the degree of reliability of the big win are performed while the liquid crystal screen 5 is performing a variable effect using decorative symbols. An effect (see FIG. 18) may be executed. This zebra effect is an advance notice effect that suggests that the reliability of the big win is relatively high by displaying a predetermined zebra effect image 55 including a zebra pattern on the liquid crystal screen 5 .

[Control Regarding Zebra Effect in Low Probability State]
Hereinafter, control regarding the zebra effect in the low probability state will be described with reference to FIGS. 19A, 20A and 20B. Here, FIG. 19A is an explanatory diagram for explaining the execution ratio (execution probability), appearance rate, and reliability of the zebra effect in the low-probability state. FIGS. 20A and 20B are explanatory diagrams for explaining a zebra effect determination table for determining whether or not to execute a zebra effect in a low probability state.

In the gaming machine 1 of the present embodiment, in the low probability state, the jackpot probability is 1/220 when the setting value is set to "1" (low setting), and the setting value is "2" (medium setting). is set to 1/200, and the jackpot probability is 1/180 when the set value is set to "3" (high setting). This is as described above with reference to FIGS. 13 and 14(A).

(Processing of main CPU 101 in low probability state)
The main CPU 101 of the game control board 100 executes the first special symbol determination based on the fact that the game ball has entered the first starting port 11 in the low probability state (for example, normal game state). Then, the main CPU 101 includes symbol setting information indicating the determination result of the jackpot determination process for determining whether or not to execute the jackpot game, and the settings stored in the set value main storage area 1041 (see FIG. 9). A variation start command related to the first special symbol determination that does not contain a value is transmitted to the effect control board 130 .

When the game is controlled in the low probability state (in this embodiment, the “normal game state” or the “time-saving game state”), the main CPU 101 sets a pattern indicating the determination result of whether or not to execute the jackpot game. While transmitting information, it does not transmit the setting value (information that can specify the current jackpot probability) stored in the setting value main storage area 1041 .

(Processing of sub CPU 131 in low probability state)
On the other hand, the sub CPU131 of the effect control board 130, when receiving the variation start command related to the first special symbol determination from the game control board 100, to the design setting information included in the received variation start command Based on this, it is determined whether or not to execute the zebra effect. It should be noted that the sub CPU 131 repeatedly executes random number update processing at a predetermined cycle while the gaming machine 1 is running, and the zebra effect random number appropriately updated by this random number update processing fluctuates from the game control board 100. Get the value when the start command is received. Then, when the received variation start command includes setting information indicating one of the jackpot patterns X1 to X3 (see FIG. 14(B)), the low probability state stored in the sub ROM 132 ・Whether or not to execute the zebra effect is determined by referring to the big win zebra effect determination table (see FIG. 20(A)).

In the low-probability state/big win zebra effect determination table (see FIG. 20A), different random numbers are associated with each of non-zebra effect and with zebra effect. The sub CPU 131 refers to the low-probability state/big win zebra effect determination table, and determines whether or not the acquired zebra effect random number matches any of the random numbers associated with the presence of the zebra effect. Decide whether to execute

(Zebra effect execution ratio at the time of jackpot in low probability state)
In this embodiment, the possible range of the zebra effect random number acquired by the sub CPU 131 is set to "0" to "99999" (see FIG. 20(A)). In the low-probability state/big win zebra effect determination table, 50000 random numbers are associated with each of the non-zebra effect and the presence of the zebra effect. Therefore, the ratio of selection without zebra effect and the ratio of selection with zebra effect are both 50% (=50000/100000×100).

Thus, in the gaming machine 1 of the present embodiment, when the determination result of the first special symbol determination is a big hit in the low probability state, the set value main storage area 1041 (see FIG. 9) of the game control board 100 ), the execution ratio of the zebra effect is preset to 50% (see FIG. 19A).

On the other hand, when the determination result of the first special symbol determination is a big hit in the low probability state, the appearance rate of the zebra effect in each setting is as follows. In the following explanation, the expected value for the appearance of a zebra effect that accompanies a big win per variation is called the "appearance rate of a zebra effect at the time of a big win", and the expected value for the appearance of a zebra effect that accompanies a loss per variation is called " The expected value for the appearance of the zebra effect per variation regardless of whether it is a big win or not is called the "total appearance rate".

(Zebra effect appearance rate at the time of jackpot in low probability state)
That is, as exemplified in FIG. 19A, when the setting value is set to “1” (low setting), the jackpot probability in the low probability state is 1/220, and the zebra effect at the jackpot Since the execution ratio is 50%, the zebra effect appearance rate at the time of the big win when the setting value is set to "1" is about 0.227% (≈ 1/220 x 0.5 x 100). be.
Further, as illustrated in FIG. 19A, when the set value is set to "2" (middle setting), the probability of a big win in the low probability state is 1/200, and the zebra effect at the time of a big win. Since the execution ratio is 50%, the zebra effect appearance rate at the time of the big win when the setting value is set to "2" is about 0.250% (= 1/200 x 0.5 x 100). be.
In addition, as illustrated in FIG. 19A, when the set value is set to "3" (high setting), the probability of a big win in the low probability state is 1/180, and the zebra effect at the time of a big win. Since the execution ratio is 50%, the zebra effect appearance rate at the time of the big win when the setting value is set to "3" is about 0.278% (≈ 1/180 x 0.5 x 100). be.

On the other hand, when the setting value is set to "1" (low setting) in the low probability state, the probability of winning is 219/220 (=1-1/220) because the probability of big hit is 1/220. is.
In addition, when the setting value is set to "2" (medium setting) in the low probability state, the probability of winning is 1/200, so the probability of losing is 199/200 (= 1-1/200). is.
Also, if the set value is set to "3" (high setting) in the low probability state, the probability of winning is 1/180, so the probability of losing is 179/180 (= 1-1/180). is.

When the variation start command received from the game control board 100 includes setting information indicating a losing pattern, the sub CPU 131 stores a low-probability state/losing zebra effect determination table stored in the sub ROM 132 (Fig. 20 (B) ))) to determine whether or not to execute the zebra effect.

In the low-probability state/losing zebra effect determination table (see FIG. 20B), different random numbers are associated with the no zebra effect and the with the zebra effect. The sub CPU 131 refers to the low-probability/losing zebra effect determination table, and determines whether or not the acquired zebra effect random number matches any of the random numbers associated with the zebra effect. Decide whether to execute

(Zebra effect execution ratio when losing in low probability state)
As described above, the possible range of the zebra effect random number acquired by the sub CPU 131 is “0” to “99999”. On the other hand, in the low-probability/losing zebra effect determination table, 99773 random numbers are associated with no zebra effect, and 227 random numbers are associated with the zebra effect. . Therefore, the ratio of selecting the presence of the zebra effect is 0.227% (=227/100000×100).

Thus, in the gaming machine 1 of the present embodiment, when the determination result of the first special symbol determination is lost in the low probability state, the set value main storage area 1041 (see FIG. 9) of the game control board 100 ), the execution ratio of the zebra effect is preset to 0.227% (see FIG. 19A).
In addition, when the determination result of the first special symbol determination is lost in the low probability state, the appearance rate of the zebra effect in each setting is as follows.

(Zebra effect appearance rate when losing in low probability state)
That is, as illustrated in FIG. 19A, when the setting value is set to "1" (low setting), the probability of losing in the low probability state is 219/220, and the zebra effect at the time of losing Since the execution ratio is 0.227%, the appearance rate of the zebra effect when the set value is set to "1" is approximately 0.226% (≈ 219/220 x 0.227%). is.
Also, as illustrated in FIG. 19A, when the setting value is set to "2" (medium setting), the probability of losing in the low probability state is 199/200, and the zebra effect at the time of losing Since the execution ratio is 0.227%, the appearance rate of the zebra effect when the set value is set to "2" is approximately 0.226% (≈199/200 x 0.227%). is.
Further, as illustrated in FIG. 19A, when the setting value is set to "3" (high setting), the probability of losing in the low probability state is 179/180, and the zebra effect at the time of losing Since the execution ratio is 0.227%, the appearance rate of the zebra effect when the set value is set to "3" is approximately 0.226% (≒179/180*0.227%). is.

(Comprehensive appearance rate and jackpot reliability of zebra production in low probability state)
The overall appearance rate of the zebra effect for each setting in the low probability state (appearance rate that sums the appearance rate at the time of the big hit and the appearance rate at the time of the loss) and the reliability of the big hit are as follows. That is, as illustrated in FIG. 19A, when the setting value is set to "1" (low setting) in the low probability state, the zebra effect appearance rate at the time of the big win is 0.227%. The zebra effect appearance rate at the time of losing is 0.226%. Therefore, the total appearance rate of the zebra effect when the set value is set to "1" (low setting) in the low probability state is approximately 0.453% (=0.227+0.226). Therefore, the reliability of the big win of the zebra effect when the set value is set to "1" in the low probability state is approximately 50.11% (≈0.227/0.453×100).

Further, as illustrated in FIG. 19A, when the setting value is set to "2" (middle setting) in the low probability state, the zebra effect appearance rate at the time of the big win is 0.250%. The zebra effect appearance rate at the time of losing is 0.226%. Therefore, the total appearance rate of the zebra effect when the set value is set to "2" (medium setting) in the low probability state is about 0.476% (=0.250+0.226). Therefore, the reliability of the big hit of the zebra effect when the set value is set to "2" in the low probability state is approximately 52.52% (≈0.250/0.476×100).

Further, as illustrated in FIG. 19A, when the setting value is set to "3" (high setting) in the low probability state, the zebra effect appearance rate at the time of the big win is 0.278%. The zebra effect appearance rate at the time of losing is 0.226%. Therefore, the total appearance rate of the zebra effect when the set value is set to "3" (high setting) in the low probability state is approximately 0.504% (=0.278+0.226). Therefore, the reliability of the big win of the zebra effect when the set value is set to "3" in the low probability state is approximately 55.16% (≈0.278/0.504×100).

(Features of zebra effect in low probability state)
The zebra effect in the low probability state has the following features.
In this embodiment, the sub CPU 131, when the game is controlled in a low probability state, issues a variation start command including setting information of symbols indicating a jackpot pattern (information indicating that a jackpot game is determined to be executed). When it is received, the zebra effect is executed at a 50% execution rate regardless of which of the set values "1" to "3" stored in the main set value storage area 1041 (see FIG. 19 ( A)). That is, when the game is controlled in the low probability state, the execution ratio of the zebra effect at the time of the big win is fixed to 50% regardless of the setting of the big win probability.

Further, the sub CPU 131 receives a variation start command including setting information of symbols indicating a losing symbol (information indicating that it is determined not to execute a jackpot game) while the game is being controlled in a low probability state. 19 ( A)). That is, when the game is controlled in the low probability state, the execution ratio of the zebra effect at the time of losing is fixed to 0.227% regardless of the setting of the jackpot probability.

Thus, in this embodiment, when the game is controlled in the low-probability state, the main CPU 101 does not transmit the set value stored in the main set value storage area 1041 to the effect control board 130, The CPU 131 executes the zebra effect at a fixed execution rate both at the time of a big win and at the time of a loss, without being based on the set values stored in the main set value storage area 1041 .

[Problems caused by sending setting values]
By the way, if the configuration of transmitting the set values from the game control board 100 to the effect control board 130 is easily adopted, the effect control board 130 cannot control the execution of the zebra effect based on the set values. As a result, there is a risk that an overt setting suggestion effect will be incorporated.

To explain this problem with an extreme example, for example, for the set value “1” (low setting) and the set value “2” (medium setting) in the low probability state, the zebra effect execution ratio at the time of the big win is set to 0%, for example, and for the set value "3" (high setting) in the low probability state, if the zebra effect execution ratio at the time of the big win is set to 50%, in the low probability state In the case of a big win, since the zebra effect is not executed unless the set value is "3", there is a possibility that this zebra effect functions as a setting suggestion effect that clearly suggests the high setting.
Then, such an overt setting-suggesting effect may excessively arouse the gambling spirit of the player, and as a result, may lead to the encouragement of the player's immersion in the game.

On the other hand, in the gaming machine 1 of the present embodiment, a configuration is adopted in which the set value is not transmitted from the game control board 100 to the effect control board 130 in the low probability state. Therefore, as is clear from the descriptions in FIGS. 20A and 20B, it is not necessary to prepare a zebra effect determination table for each setting, and the zebra effect is executed by switching the zebra effect determination table based on the setting. can't decide whether to do it or not. In the gaming machine 1 of the present embodiment, the zebra effect appearance rate at the time of the big win and the zebra effect appearance rate at the time of the loss are fixed regardless of the setting in the low probability state. Therefore, as illustrated in FIG. 19A, although there is a slight setting difference in the zebra performance jackpot reliability due to the setting difference in the jackpot probability in the low probability state, the gaming machine 1 To completely prevent a manufacturer from intentionally incorporating an overtly suggestive setting effect, and as a result, easily and easily solve the problem of encouraging a player's immersion in a game by arousing the gambling spirit of the player. It can be suppressed effectively.

[Problems caused by not transmitting set values to the production control board 130]
By the way, when the jackpot probability in the low-probability state differs depending on the setting as in the present embodiment, the execution ratio of the zebra effect at the time of the big win (or at the time of losing) is set as described above so that the setting is not suggested by the zebra effect. It is preferable to keep it constant (see FIG. 18(A)). With this configuration, as described above, there is no need to send the setting value from the game control board 100 to the effect control board 130, and it is possible to suppress execution of an overt setting suggesting effect by effects such as a zebra effect. .
Therefore, the game machine 1 can be configured as a game machine that does not have the performance to make the player become excessively absorbed in the game, and it is possible to effectively suppress the player's addiction to the game.

However, since the jackpot probability in the low-probability state differs depending on the setting, even if the selection rate of the zebra effect is fixed, there is a problem that the jackpot reliability will vary slightly.

[Problem Solution]
In order to correct the setting difference of this jackpot reliability, make the jackpot probability in the low probability state the same for all setting values, and eliminate the setting difference in the jackpot probability in the low probability state. It is conceivable to fix the appearance rate of the zebra effect by changing the execution ratio of the zebra effect.

Therefore, in the gaming machine 1 of the present embodiment, the main CPU 101 does not transmit the set value to the effect control board 130 in the low probability state, while the main CPU 101 transmits the set value to the effect control board 130 in the high probability state. In the high probability state, the sub CPU 131 changes the execution ratio of the zebra effect (both at the time of the big win and at the time of losing) based on the set value to fix the appearance rate of the zebra effect, resulting in a high probability. In the state, there is no setting difference in the big win reliability of the zebra effect, or the setting difference in the big win reliability is small.

In this way, only in the high probability state of the low probability state and the high probability state, a configuration is adopted in which the set value is sent from the game control board 100 to the effect control board 130 . As a result, it is possible to moderately suppress the possibility of the setting suggestion by the zebra effect, compared to the case where the setting value is sent in both the low-probability state and the high-probability state. The same thing can be said when compared with the case where the setting value is not sent from the game control board 100 to the effect control board 130 in both the low probability state and the high probability state.

[Control Regarding Zebra Effect in High Probability State]
Hereinafter, with reference to FIGS. 19B, 20C and 20D, the control regarding the zebra effect in the high-probability state will be described. Here, FIG. 19B is an explanatory diagram for explaining the execution ratio, appearance rate, and reliability of the zebra effect in the high-probability state. FIGS. 20C and 20D are explanatory diagrams for explaining a zebra effect determination table for determining whether or not to execute a zebra effect in a high probability state.

In the gaming machine 1 of the present embodiment, in the high probability state, the jackpot probability is 1/27.5 when the setting value is set to "1" (low setting), and the setting value is "2" (middle setting). setting) is set to 1/25, and the jackpot probability is 1/22.5 when the set value is set to "3" (high setting). This is as described above with reference to FIGS. 13 and 14(A).

(Processing of main CPU 101 in high probability state)
The main CPU 101 of the game control board 100 generates a second special symbol based on the fact that the game ball has entered the second start port 12 when the high probability state (corresponding to this is the "variable probability game state" in the present embodiment). carry out the judgment. Then, the main CPU 101 stores the symbol setting information indicating the determination result of the jackpot determination process for determining whether or not to execute the jackpot game, and the set value stored in the set value main storage area 1041 (see FIG. 9). A variation start command related to the second special symbol determination including is transmitted to the effect control board 130 .

In addition, in the present embodiment, in the high probability state, by including both the setting information and the setting value of the pattern in the variation start command, the information indicating the judgment result of the jackpot judgment process and the set jackpot probability can be specified. The following describes the case of transmitting together with a setting value that is On the other hand, for example, a set value is transmitted to the effect control board 130 when the state is shifted from a low probability state to a high probability state, and information indicating the determination result of the jackpot determination process is included and the set value is not included. 2 By transmitting the variation start command related to the special symbol determination, the information indicating the determination result of the big hit determination process and the setting value may be transmitted separately.

In this way, when the game is controlled in the high probability state, the main CPU 101 transmits the symbol setting information indicating whether or not to execute the jackpot game, and stores the setting information in the main setting value storage area 1041. Sends the set value that is set.

(Processing of sub CPU 131 in high probability state)
On the other hand, the sub CPU 131 of the effect control board 130 receives from the game control board 100 the variation start command related to the second special symbol determination including the set value and the information indicating the determination result of the big hit determination process. Then, based on the pattern setting information included in the received variation start command, it is determined whether or not to execute the zebra effect.
The sub CPU 131 acquires the zebra effect random number at the time of receiving the variation start command from the game control board 100 in the same manner as in the low probability state. Then, when the received variation start command includes setting information indicating one of the jackpot patterns Y1 to Y3 (see FIG. 14(C)), the high probability state stored in the sub ROM 132 ・It is determined whether or not to execute the zebra effect by referring to the jackpot zebra effect determination table (see FIG. 20(C)).

In the high-probability state/big win zebra effect determination table (see FIG. 20C), different random numbers are associated with each set value without zebra effect and with zebra effect. The sub CPU 131 refers to the high-probability state/jackpot zebra effect determination table, and the acquired zebra effect random number is associated with the current set value (the set value received from the game control board 100) with the zebra effect present. Whether or not to execute the zebra effect is determined based on whether or not there is a match with any of the random numbers.

(Zebra effect execution ratio at the time of jackpot in high probability state)
The possible range of the zebra effect random number acquired by the sub CPU 131 is “0” to “99999” as described above even in the high probability state. In the high-probability state/jackpot zebra effect determination table (see FIG. 20(C)), set values, presence/absence of zebra effects, and random numbers to be compared with zebra effect random numbers are associated with each other. As exemplified in FIG. 20(C), with respect to the set value “1”, 50000 random numbers are associated with both without zebra effect and with zebra effect. Therefore, when a variation start command including the set value "1" is received, the zebra effect is selected at a rate of 50% (=50000/100000×100) (FIGS. 20(C) and See FIG. 19(B)).

As for the set value "2", 54550 random numbers are associated with no zebra effect, and 45450 random numbers are associated with the zebra effect. Therefore, when a variation start command including the set value “2” is received, the zebra effect is selected at a rate of 45.45% (=45450/100000×100) (Fig. 20 (C ) and FIG. 19(B)).

As for the set value "3", 59090 random numbers are associated with no zebra effect, and 40910 random numbers are associated with the zebra effect. Therefore, when a variation start command including the set value "3" is received, the zebra effect is selected at a rate of 40.91% (=40910/100000×100) (FIG. 20 (C ) and FIG. 19(B)).

Thus, in the gaming machine 1 of the present embodiment, when the determination result of the second special symbol determination is a big hit in the high probability state, the set value main storage area 1041 (see FIG. 9) of the game control board 100 ), the execution ratio of the zebra effect is varied according to the set value stored in the memory.
In addition, when the determination result of the second special symbol determination is a big hit in the high probability state, the appearance rate of the zebra effect in each setting is as follows.

(Zebra effect appearance rate at the time of jackpot in high probability state)
That is, as illustrated in FIG. 19B, when the setting value is set to "1" (low setting), the probability of a big hit in the high probability state is 1/27.5, and the zebra Since the performance execution ratio is 50%, the zebra effect appearance rate at the time of the big win when the set value is set to "1" is about 1.818% (≈ 1/27.5 x 0.5 × 100).
Further, as illustrated in FIG. 19B, when the set value is set to "2" (medium setting), the probability of a big win in the high probability state is 1/25, and the zebra effect at the time of a big win. Since the execution ratio is 45.45%, the zebra effect appearance rate at the time of the big win when the set value is set to "2" is 1.818% (= 1/25 x 0.4545 x 100). is.
Further, as illustrated in FIG. 19B, when the set value is set to "3" (high setting), the probability of a big win in the high probability state is 1/22.5, and the zebra Since the performance execution ratio is 40.91%, the zebra effect appearance rate at the time of the big win when the set value is set to "3" is about 1.818% (≈ 1/22.5 x 0 .4091×100).

In this way, by changing the execution ratio of the zebra effect according to the set value at the time of the big win in the high probability state, the appearance rate of the zebra effect at the time of the big win is fixed to about 1.818% regardless of the set value. can do.

On the other hand, if the setting value is set to "1" (low setting) in the high probability state, the probability of winning is 1/27.5, so the probability of losing is 26.5/27.5 (= 1-1/27.5).
Also, if the setting value is set to "2" (medium setting) in the high probability state, the probability of winning is 1/25, so the probability of losing is 24/25 (=1-1/25). is.
Also, when the setting value is set to "3" (high setting) in the high probability state, the probability of winning is 1/22.5, so the probability of losing is 21.5/22.5 (= 1-1/22.5).

When the variation start command received from the game control board 100 includes setting information and a setting value indicating a losing pattern, the sub CPU 131 stores a high-probability state/losing zebra effect determination table (Fig. 20(D)) to determine whether or not to execute the zebra effect.

In the high-probability state/losing zebra effect determination table (see FIG. 20(D)), different random numbers are associated with each of the setting values without the zebra effect and with the zebra effect. The sub CPU 131 refers to the high-probability state/losing zebra effect determination table, and the acquired zebra effect random number is associated with the current set value (the set value received from the game control board 100) with the zebra effect present. Whether or not to execute the zebra effect is determined based on whether or not there is a match with any of the random numbers.

(Percentage of execution of zebra effect when losing in high probability state)
In the high-probability state/losing zebra effect determination table (see FIG. 20(D)), set values, presence/absence of zebra effects, and random numbers to be compared with zebra effect random numbers are associated with each other. As exemplified in FIG. 20(D), with respect to the set value “1”, 98182 random numbers are associated with no zebra effect, and 1818 random numbers are associated with zebra effect. It is Therefore, when a variation start command including the set value "1" is received, the zebra effect is selected at a rate of 1.818% (=1818/100000×100) (Fig. 20 (D ) and FIG. 19(B)).

As for the set value “2”, 98175 random numbers are associated with no zebra effect, and 1825 random numbers are associated with zebra effect. Therefore, when a variable start command including the set value "2" is received, the zebra effect is selected at a rate of 1.825% (=1825/100000*100) (Fig. 20 (C ) and FIG. 19(B)).

As for the set value “3”, 98167 random numbers are associated with no zebra effect, and 1833 random numbers are associated with zebra effect. Therefore, when a variable start command including the set value "3" is received, the zebra effect is selected at a rate of 1.833% (=1833/100000*100) (Fig. 20 (C ) and FIG. 19(B)).

Thus, in the gaming machine 1 of the present embodiment, when the determination result of the second special symbol determination is lost in the high probability state, the set value main storage area 1041 (see FIG. 9) of the game control board 100 ), the execution ratio of the zebra effect is varied according to the set value stored in the memory.
In addition, when the determination result of the second special symbol determination is lost in the high probability state, the appearance rate of the zebra effect in each setting is as follows.

(Zebra effect appearance rate when losing in high probability state)
That is, as illustrated in FIG. 19B, when the setting value is set to "1" (low setting), the probability of losing in the high probability state is 26.5/27.5, and when losing is 1.818%, the zebra effect appearance rate when the set value is set to "1" is about 1.752% (≈ 26.5/27 .5×0.01818×100).
Also, as illustrated in FIG. 19B, when the setting value is set to "2" (medium setting), the probability of losing in the high probability state is 24/25, and the zebra effect at the time of losing Since the execution ratio is 1.825%, the appearance rate of the zebra effect when the set value is set to "2" is 1.752% (=24/25*0.01825*100). is.
Further, as illustrated in FIG. 19B, when the setting value is set to "3" (high setting), the probability of losing in the high probability state is 21.5/22.5, and when losing Since the execution ratio of the zebra effect is 1.833%, the zebra effect appearance rate at the time of failure when the setting value is set to "3" is about 1.752% (≒ 21.5/22 .5×0.01833×100).

In this way, by changing the execution ratio of the zebra effect according to the set value in the event of a failure in a high-probability state, the appearance rate of the zebra effect at the time of failure is fixed at about 1.818% regardless of the set value. can do.

(Comprehensive appearance rate and jackpot reliability of zebra effects in high probability state)
The overall appearance rate and jackpot reliability of the zebra effect for each setting in the high probability state are as follows. That is, as illustrated in FIG. 19B, when the setting value is set to "1" (low setting) in the high probability state, the zebra effect appearance rate at the time of the big win is 1.818%. The zebra effect appearance rate at the time of losing is 1.752%. Therefore, the total appearance rate of the zebra effect when the setting value is set to "1" (low setting) in the high probability state is 3.57% (=1.818+1.752). Therefore, the reliability of the big win of the zebra effect when the set value is set to "1" in the high probability state is approximately 50.92% (≈1.818/3.57×100).

Further, as illustrated in FIG. 19B, when the set value is set to "2" (medium setting) in the high probability state, the zebra effect appearance rate at the time of the big win is 1.818%. The zebra effect appearance rate at the time of losing is 1.752%. Therefore, the total appearance rate of the zebra effect when the set value is set to "2" (medium setting) in the high probability state is 3.57% (=1.818+1.752). Therefore, the reliability of the big win of the zebra effect when the setting value is set to "2" in the high probability state is approximately 50.92% (≈1.818/3.57×100).

Further, as illustrated in FIG. 19B, when the set value is set to "3" (high setting) in the high probability state, the zebra effect appearance rate at the time of the big win is 1.818%. The zebra effect appearance rate at the time of losing is 1.752%. Therefore, the total appearance rate of the zebra effect when the set value is set to "3" (high setting) in the high probability state is 3.57% (=1.818+1.752). Therefore, the reliability of the big win of the zebra effect when the set value is set to "3" in the high probability state is approximately 50.92% (≈1.818/3.57×100).

(Features of zebra effect in high probability state)
The zebra effect in the high-probability state has the following features.
In this embodiment, the sub CPU 131, when the game is controlled in a high probability state, issues a variation start command including setting information (information indicating that a jackpot game is determined to be executed) of a symbol indicating a jackpot symbol. When it is received, the zebra effect is executed at an execution ratio corresponding to the big win probability specified from the setting value stored in the main setting value storage area 1041. - 特許庁Specifically, as shown in FIG. 19B, when the set value "1" is stored, the zebra effect is executed at a rate of 50%, and when the set value "2" is stored. If there is, the zebra effect is executed at an execution rate of 45.45%, and if the set value "3" is stored, the zebra effect is executed at an execution rate of 40.91%.
As a result, the appearance rate of the zebra effect at the time of the big win is fixed to 1.818% regardless of the probability of the big win.

Further, the sub CPU 131 receives a variation start command including setting information (information indicating that it is determined not to execute a jackpot game) of a symbol indicating a losing symbol when the game is controlled in a high-probability state. In this case, the zebra effect is executed at an execution ratio corresponding to the jackpot probability specified from the set value stored in the set value main storage area 1041 . Specifically, as shown in FIG. 19B, when the set value "1" is stored, the zebra effect is executed at an execution rate of 1.818%, and the set value "2" is stored. If so, the zebra effect is executed at an execution rate of 1.825%, and if the set value "3" is stored, the zebra effect is executed at an execution rate of 1.833%.
As a result, the appearance rate of the zebra effect at the time of losing is fixed at 1.752% regardless of the probability of a big win.

Thus, in this embodiment, when the game is controlled in the high probability state, the main CPU 101 transmits the set value stored in the main set value storage area 1041 to the effect control board 130, and the sub CPU 131 is designed to execute the zebra effect at an execution ratio according to the set value stored in the set value main storage area 1041 both at the time of the big win and at the time of the loss.

Further, in this embodiment, when the game is controlled in the high probability state, the total appearance rate of the zebra effect is fixed at 3.57% regardless of the setting. Since the appearance rate of the zebra effect at the time of the big win is fixed regardless of the setting, the reliability of the big win of the zebra effect is fixed at 50.92% regardless of the probability of the big win.

As described above, in the gaming machine 1 of the present embodiment, the zebra effect appearance rate at the time of the big win in the high probability state, the zebra effect appearance rate at the time of losing, and the reliability of the zebra effect big win are fixed regardless of the settings. It is possible to easily suppress the zebra effect performed when a game is controlled in a high-probability state from functioning as an overt setting-suggestion effect.

[Regarding normal mode]
In the gaming machine 1 of the present embodiment, when the power recovery process in the power recovery mode described above based on FIG. It becomes possible.

[Timer interrupt processing by game control board 100]
FIG. 21 is a flow chart showing an example of timer interrupt processing executed in the game control board 100. As shown in FIG. During the game control board 100, during the first RAM clear mode, during the setting change mode, during the second RAM clear mode, during the setting confirmation mode, during the power recovery mode, during the normal operation except for special cases such as power failure, A series of processes illustrated in 21 are repeatedly executed at fixed time intervals (for example, 4 milliseconds). The processing of the game control board 100, which will be explained based on the flowcharts of FIG.

First, the main CPU 101 executes a random number update process for updating various random numbers including jackpot random numbers, symbol random numbers, reach random numbers, variation pattern random numbers, and normal symbol random numbers (step S1).

The jackpot random numbers, pattern random numbers, reach random numbers, and variation pattern random numbers are as described above. The normal symbol random number is a random number for determining whether or not to open the second starting port 12 . A jackpot random number, a symbol random number, a reach random number, a fluctuation pattern random number, and a normal symbol random number are incremented by "1" each time the process of step S1 is performed. A loop counter, for example, is used as the counter for performing the process of step S1, and each random number is reset to "0" and updated after reaching a preset maximum value.

Following the processing of step S1, the main CPU 101 executes switch processing including processing of acquiring various random numbers in response to input of detection signals from each switch (step S2). This switch processing will be described later in detail with reference to FIG.

Following the processing of step S2, the main CPU 101 executes special symbol determination, causes the first special symbol display 41 or the second special symbol display 42 to variably display the special symbol, and then determines the result of the special symbol determination. A special design process including a process of stopping and displaying a special design showing is executed (step S3). This special symbol processing will be described in detail later based on FIG.

Following the process of step S3, the main CPU 101 executes normal symbol determination, causes the normal symbol display 45 to variably display the normal symbol, and then stops and displays the normal symbol indicating the result of the normal symbol determination. A normal design process is executed (step S4).

Following the processing of step S4, the main CPU 101 performs the electric tulip processing of operating the electric tulip 17 via the electric tulip control unit 113 when it is determined to open the second starting port 12 as a result of the normal symbol determination. (step S5).

Following the processing of step S5, the main CPU 101 performs a large winning prize opening control process for opening the large winning prize opening 13 by controlling the large winning prize opening control section 116 when it is determined in the processing of step S3 that there is a big win. Execute (step S6). By executing this big winning opening opening control process, a jackpot game including five long opening round games or a jackpot game including ten long opening round games is performed.

Following the processing of step S6, the main CPU 101 executes prize ball processing for controlling payout of prize balls according to winning of game balls (step S7). Specifically, when a detection signal from the first starting port switch 111, the second starting port switch 112, the large winning port switch 115, or the normal winning port switch 117 is input, the game ball is determined according to the winning location. A payout control board is instructed to pay out a predetermined number of prize balls, and the number of prize balls to be paid out is managed based on information from the payout control board.

It should be noted that the main CPU 101 also executes the following processing in this step S7. Specifically, every time a detection signal is input from the count switch 110 in the low base state, the total number G stored in the main RAM 103 (indicating the total number of game balls launched into the game area 10) is changed to " 1” Execute the first update process to update to the added value.
In addition, every time a detection signal is input from the first starting port switch 111 in the low base state, the second update process updates the total number of prize balls H stored in the main RAM 103 by adding "4". to run.
Also, every time a detection signal is input from the normal winning opening switch 117 in the low base state, a third updating process is executed to update the stored total number of prize balls F to a value obtained by adding "3".
Further, when any one of the first to third update processes is performed, the above-described base value B is recalculated, and the calculated base value B is displayed blinking on the performance indicator 215. Execute.

Following the processing of step S7, the main CPU 101 transmits various commands set (stored) in the main RAM 103 in the processing steps before step S7 and information necessary for determining the content of the effect to the effect control board 130. Processing is executed (step S8).

[Switch processing by game control board 100]
FIG. 22 is a detailed flowchart of the switch processing in step S2 of FIG. Following the processing of step S1, the main CPU 101 monitors whether or not a detection signal is input from the first starting port switch 111, as illustrated in FIG. For random numbers (jackpot random numbers, pattern random numbers, reach random numbers, and fluctuation pattern random numbers), the first starter switch processing including the processing of acquiring the value at the time when the detection signal from the first starter switch 111 is input is executed. (step S21). This first start opening switch process will be described later in detail with reference to FIG.

Next, the main CPU 101 monitors whether or not a detection signal is input from the second starter switch 112, and the detection signal from the second starter switch 112 is detected for various random numbers appropriately updated by the process of step S1. A second start opening switch process including a process of acquiring a value at the time of input is executed (step S22). This second start opening switch process will be described later in detail with reference to FIG.

Then, the main CPU 101 monitors the presence or absence of the input of the detection signal from the gate switch 114, and the value at the time when the detection signal from the gate switch 114 is input for the normal symbol random number appropriately updated by the process of step S1. is executed (step S23).

[First start opening switch processing by game control board 100]
FIG. 23 is a detailed flowchart of the first start opening switch process in step S21 of FIG. As exemplified in FIG. 23, the main CPU 101 receives a detection signal from the first starter switch 111 (specifically, when the first starter switch 111 is "ON") following the random number update process in step S1. It is determined whether or not the first starting port switch 111 has been turned "ON" (step S210). Here, when it is determined that the first starting port switch 111 has turned "ON" (step S210: YES), the number U1 of pending first special symbol determination stored in the main RAM 103 is stored in the main ROM 102. It is determined whether or not it is less than the maximum pending number Umax1 ("4" in this embodiment) of the first special symbol determination (step S211).

When the main CPU 101 determines that the number of reservations U1 is less than the maximum number of reservations Umax1 (step S211: YES), it updates the value of the number of reservations U1 by adding "1" (step S212) to the first special symbol. A jackpot random number, a pattern random number, a reach random number, and a variation pattern random number are obtained as information to be used for determination, and these random numbers are associated and stored in the main RAM 103 (steps S213 to S216).

In this way, various acquisition information such as a jackpot random number is acquired in accordance with the establishment of the acquisition condition that the first starting port switch 111 is turned "ON" while the number U1 of reservations is less than the maximum number Umax1 of reservations.
In addition, when various random numbers are acquired in a situation where the first special symbol determination and the variable display of the first special symbol can be executed immediately, these random numbers are stored in the determination storage area 1030 (see FIG. 9 (A)). When various random numbers are obtained in a situation where they are directly stored and cannot be executed immediately, these random numbers are stored in any of the first reserved storage area 1031 to fourth reserved storage area 1034 (see FIG. 9A). Stored.

Following the processing of step S216, the main CPU 101 determines whether or not the current state is the high base state (step S217). A time saving game flag is stored in the main RAM 103 . This time-saving game flag is set to "OFF" when controlling the electric tulip 17 in a state in which it is difficult for the game ball to enter the second starting port 12, and conversely, the game ball is likely to enter the second starting port 12. This flag is set to "ON" when controlling the electric tulip 17 to the state. In step S217, the main CPU 101 determines whether or not the current state is the high base state based on whether or not the time saving game flag stored in the main RAM 103 is set to "ON".

When the main CPU 101 determines that the current state is not the high base state (step S217: NO), that is, when the time saving game flag is set to "OFF", the main CPU 101 executes preliminary determination processing (step S218). Specifically, prior to the jackpot determination processing (see FIG. 27) and variation pattern selection processing (see FIG. 28) described later, based on the information acquired by the processing of steps S213 to S216, whether or not the jackpot Along with pre-determining whether or not, pre-determination for pre-determining the variation pattern of the special symbol actually selected when the first special symbol determination is performed is performed. This advance determination processing will be described later in detail with reference to FIG. 25 .

When the main CPU 101 executes the process of step S218, or determines that it is in the high base state (the time saving game flag is set to "ON") (step S217: YES), the first special symbol determination is performed. Such pending command is set in the main RAM 103 (step S219). This pending command is a command for notifying that the first special symbol determination has been suspended, and is transmitted to the effect control board 130 by the transmitting process of step S8.

In addition, when the process of step S219 is performed following the process of step S218, the pending|holding command containing the prior determination information obtained by the process of step S218 is transmitted to the production|presentation control board 130. FIG.

[Second start opening switch processing by game control board 100]
FIG. 24 is a detailed flowchart of the second start opening switch process in step S22 of FIG. As illustrated in FIG. 24, following the first starter switch process in step S21, the main CPU 101 receives a detection signal from the second starter switch 112 (specifically, when the second starter switch 112 is "ON"). is input, it is determined whether or not the second starting port switch 112 is "ON" (step S220).

When the main CPU 101 determines that the second starting port switch 112 is turned "ON" (step S220: YES), the second special symbol determination pending number U2 stored in the main RAM 103 is stored in the main ROM 102. It is determined whether or not it is less than the maximum pending number Umax2 ("4" in this embodiment) of the second special symbol determination (step S221).

When the main CPU 101 determines that the number of reservations U2 is less than the maximum number of reservations Umax2 (step S221: YES), it updates the value of the number of reservations U2 by adding "1" (step S222) to the second special symbol. A jackpot random number, a pattern random number, a reach random number, and a variation pattern random number are obtained as information used for determination, and these random numbers are associated and stored in the main RAM 103 (steps S223 to S226).

In addition, when various random numbers are acquired in a situation where the second special symbol determination and the variable display of the second special symbol can be executed immediately, these random numbers are stored in the determination storage area 1030 (see FIG. 9 (A)). When various random numbers are obtained in a situation where they are directly stored and cannot be executed immediately, these random numbers are stored in one of the first reserved storage area 1035 to fourth reserved storage area 1038 (see FIG. 9A). Stored.

Following the process of step S226, the main CPU 101 determines whether the current state is the high base state (step S227), similarly to the process of step S217. Here, when it is determined that the current state is the high base state (step S227: YES), that is, when the time saving game flag is set to "ON", a preliminary determination process is executed (step S228). This advance determination processing will be described later in detail with reference to FIG. 25 .

When the main CPU 101 executes the process of step S228, or determines that it is not in the high base state (the time saving game flag is set to "OFF") (step S227: NO), the second special symbol determination is performed. Such pending command is set in the main RAM 103 (step S229). This pending command is a command for notifying that the second special symbol determination has been suspended, and is transmitted to the effect control board 130 by the transmitting process of step S8.

In addition, when the process of step S229 is performed following the process of step S228, the pending|holding command containing the prior determination information obtained by the process of step S228 is transmitted to the production|presentation control board 130. FIG.

[Preliminary determination processing by the game control board 100]
Hereinafter, the prior determination processing executed by the game control board 100 will be described with reference to FIG. Here, FIG. 25 is a detailed flowchart of the preliminary determination processing in steps S218 and S228 of FIGS.

If the main CPU 101 determines in the processing of step S217 in FIG. 23 that the high base state is not in effect, or if it determines in the processing of step S227 in FIG. S2180). Specifically, based on the setting values stored in the main setting value storage area 1041, it specifies which one of "1" to "3" the current setting value is set to.

After the process of step S2180, the main CPU 101 executes a big win determination process (step S2181). Specifically, when the low probability state (normal game state or time saving game state in this embodiment), the low probability jackpot random number table (see FIG. 14A) is read from the main ROM 102 and the main RAM 103 set to On the other hand, when it is in a high probability state (probability variable gaming state in this embodiment), the high probability jackpot random number table (see FIG. 14A) is read from the main ROM 102 and set in the main RAM 103 . 23 (or step S223 in FIG. 24) matches any of the winning values stored in the jackpot random number table set in the main RAM 103. Based on this, it is determined whether or not it will be determined as a big hit at the start of the fluctuation.

When the main CPU 101 sets the low-probability jackpot random number table (see FIG. 14A), whether or not the obtained jackpot random number matches any winning value associated with the current set value. Based on, it is determined whether or not it will be determined as a big hit at the start of the fluctuation. In the low-probability jackpot random number table, as illustrated in FIG. is '1', it is determined whether or not a big win is determined at the start of the fluctuation based on whether the obtained big win random number matches with any of the 90 winning values.

Also, 99 winning values are associated with the setting value "2" (see FIG. 14A), and if the setting value specified in step S2180 is "2", the acquired Based on whether or not the jackpot random number coincides with any one of the 99 winning values, it is determined whether or not it will be determined as a jackpot at the start of the variation. Also, 110 winning values are associated with the setting value "3" (see FIG. 14A), and if the setting value specified in step S2180 is "3", the acquired Based on whether or not the jackpot random number coincides with any one of the above 110 winning values, it is determined whether or not it will be determined as a jackpot at the start of the variation.

On the other hand, when the main CPU 101 sets the high-probability jackpot random number table (see FIG. 14A), the main CPU 101 determines whether the obtained jackpot random number matches any winning value associated with the current set value. Based on whether or not, it is determined whether or not it will be determined as a big win at the start of the variation. In the high-probability jackpot random number table, as illustrated in FIG. is "1", it is determined whether or not it will be determined as a big win at the start of the fluctuation based on whether the obtained big win random number matches with any of the above 720 winning values.

Also, 792 winning values are associated with the setting value "2" (see FIG. 14A), and if the setting value specified in step S2180 is "2", the acquired Based on whether or not the jackpot random number coincides with any one of the 792 winning values, it is determined whether or not it will be determined as a jackpot at the start of the variation. Also, 880 winning values are associated with the set value "3" (see FIG. 14A), and if the set value specified in step S2180 is "3", the acquired Based on whether or not the jackpot random number coincides with any one of the above 880 winning values, it is determined whether or not it will be determined as a jackpot at the start of the variation.

Next, the main CPU 101 determines whether or not it is determined to be a big win at the start of the variation based on the determination result of step S2181 (step S2182). Here, if it is determined that it is a big hit at the start of the fluctuation (step S2182: YES), the big hit fluctuation pattern table (see FIG. 15A) is read from the main ROM 102 and set in the main RAM 103 ( step S2183).

On the other hand, when the main CPU 101 determines that it is not a big hit at the start of the variation (step S2182: NO), it determines whether or not the ready-to-win effect is performed during the variation (step S2184). Specifically, the reach random number obtained together with the jackpot random number used in the jackpot determination process in step S2181 matches the hit value of the reach random number stored in the main ROM 102 (see FIG. 14(D)). Based on whether or not, it is determined whether or not the ready-to-win effect is performed during the variation.

When the main CPU 101 determines that the ready-to-win effect will be performed (step S2184: YES), it reads the ready-to-win variation pattern table (see FIG. 15B) from the main ROM 102 and sets it in the main RAM 103 (step S2185).

By the way, for example, if the determination result of the special symbol determination is "losing" and the reach effect is not performed during the variation, the special symbol variation pattern is based on the number of suspensions of the special symbol determination at the start of the variation. It is determined. Then, the number of pending special symbol determinations may differ between before and after the suspended special symbol determination is digested. Therefore, the special symbol variation pattern acquired before the special symbol determination is digested may differ from the special symbol variation pattern selected when the special symbol determination is actually digested. That is, there is a case where an accurate special symbol variation pattern cannot be acquired prior to the special symbol determination for the right of the special symbol determination in which the ready-to-win effect is not performed during the variation.

Therefore, when it is determined that the ready-to-win effect is not performed (step S2184: NO), the process proceeds to step S2187 without performing the fluctuation pattern random number determination process of step S2186 described later.

When the main CPU 101 sets the big hit variation pattern table or the ready-to-win variation pattern table, the main CPU 101 executes variation pattern random number determination processing (step S2186). Specifically, the variation pattern random number acquired at the time of the starting opening winning along with the jackpot random number used in the processing of step S2181 is selected from among the random values stipulated in the variation pattern table set in the main RAM 103. Based on which random number value matches, the special symbol variation pattern to be selected in the special symbol determination performed at the start of the variation is specified.

When the main CPU 101 executes the process of step S2186 or determines that the ready-to-win effect is not performed (step S2184: NO), the main CPU 101 generates advance determination information and stores it in the main RAM 103 (step S2187). Note that the area in which this advance determination information is stored is as described above with reference to FIG.

[Special symbol processing by game control board 100]
Next, details of the special symbol processing executed by the game control board 100 will be described with reference to FIG. Here, FIG. 26 is a detailed flowchart of the special symbol processing in step S3 of FIG.

As illustrated in FIG. 26, the main CPU 101 determines whether or not the big win game is in progress based on whether or not the big win game flag stored in the main RAM 103 is set to "ON" ( step S301). This jackpot game flag is a flag indicating whether or not a jackpot game is being executed, and is set to "ON" at the start of the jackpot game, and set to "OFF" at the end of the jackpot game. Here, when it is determined that the jackpot game is in progress (step S301: YES), the process proceeds to the normal symbol process of step S4.

When the main CPU 101 determines that the jackpot game is not being performed (step S301: NO), the main CPU 101 determines whether or not the special symbols are being variably displayed (step S302). Here, if it is determined that the special symbols are not displayed in a variable display (step S302: NO), it is determined whether or not the second special symbol determination pending number U2 stored in the main RAM 103 is "1" or more. (step S303). Here, when it is determined that the number of reservations U2 is "1" or more (step S303: YES), the number of reservations U2 is updated to a value obtained by subtracting "1" (step S304).

When the main CPU 101 determines that the number of reservations U2 is not "1" or more (step S303: NO), whether or not the number of reservations U1 of the first special symbol determination stored in the main RAM 103 is "1" or more. (step S305). Here, when it is determined that the number of reservations U1 is "1" or more (step S305: YES), the number of reservations U1 is updated to a value obtained by subtracting "1" (step S306).

Following the processing of step S304 or the processing of step S306, the main CPU 101 executes shift processing on the reserved storage area of the main RAM 103 (step S308). Specifically, the main CPU 101, when executing the shift process following the process of step S304, is stored in the reserved storage areas 1035 to 1038 (see FIG. 9A) for second special symbol determination. The earliest acquired information is shifted to the determination storage area 1030, and the remaining acquired information is shifted to the determination storage area 1030 side. Also, when the shift process is executed following the process of step S306, the earliest acquisition information stored in the reserved storage areas 1031 to 1034 for the first special symbol determination (see FIG. 9(A)) is Along with shifting to the determination storage area 1030, the remaining acquired information is shifted to the determination storage area 1030 side.

Following the process of step S308, the main CPU 101 executes the big win determination process based on the random number stored in the determination storage area 1030 (step S309). By executing this jackpot determination process, it is determined whether or not a jackpot has occurred, and when it is determined that a jackpot has occurred, the type of jackpot is determined. Then, special symbol setting information indicating the results of these processes is set in the main RAM 103 . This jackpot determination process will be described later in detail with reference to FIG.

Following the process of step S309, the main CPU 101 executes a variation pattern selection process for selecting a variation pattern of special symbols (step S310). This variation pattern selection process will be described later in detail with reference to FIG.

Following the process of step S310, the main CPU 101 determines whether or not the current state is a high probability state based on whether or not the variable probability game flag stored in the main RAM 103 is set to "ON". Determine (step S311). Here, the probability variation gaming flag is a flag indicating whether the probability of being determined to be a big hit in the special symbol determination is a high probability state or not, and when controlling the game in the probability variation gaming state " It is set to "ON", and is set to "OFF" when controlling the game in the normal game state or the time-saving game state.

When the main CPU 101 determines that the current state is not the high-probability state (step S311: NO), that is, when the current state is the low-probability state, the main CPU 101 performs the setting as described above with reference to FIG. In order not to transmit the setting value stored in the value storage area 1041, a change start command that does not include the setting value is set in the main RAM 103 (step S312).

On the other hand, when the main CPU 101 determines that the current state is the high-probability state (step S311: YES), as described above with reference to FIG. In order to transmit the setting value, a change start command including the setting value is set in the main RAM 103 (step S313).

In addition, even if the processing of step S312 or the processing of step S313 is executed, the setting information of the special symbol set in the processing of step S309, the setting information of this special symbol is the first special symbol. Information indicating whether it is related to the determination or the second special symbol determination, setting information of the variation pattern set in the process of step S310, variation start command including information on the game state of the gaming machine 1 is set in the main RAM 103 .

This variation start command is a command for instructing the start of an effect associated with the variable display of the special symbol, and is transmitted to the effect control board 130 by the transmission process of step S8. As a result, the variable display of decorative patterns on the liquid crystal screen 5 and the like are started.

Following the processing of step S312 or step S313, the main CPU 101 starts variable display of special symbols based on the setting information of the variation pattern included in the variation start command set in the processing of step S312 or step S313. (Step S314). At that time, when the processing after step S309 is performed in a state in which the acquisition information (random number) related to the first special symbol determination is stored in the determination storage area 1030, the first special symbol display 41 displays the first Start variable display of special symbols. On the other hand, when the processing after step S309 is performed in a state where the acquisition information (random number) related to the second special symbol determination is stored, the second special symbol display device 42 starts the variable display of the second special symbol. do.

Next, the main CPU 101 starts measuring the fluctuation time, which is the elapsed time after the start of the fluctuation display in step S314 (step S315).

When the main CPU 101 executes the process of step S315, or determines that the special symbol is being changed and displayed (step S302: YES), the main CPU 101 selects by the process of step S310 from the start of measurement of the change time in step S315. It is determined whether or not the variation time corresponding to the variation pattern has passed (step S316). Here, when it is determined that the fluctuation time has not passed (step S316: NO), the process proceeds to the normal design process of step S4.

When the main CPU 101 determines that the fluctuation time has passed (step S316: YES), the special symbol indicating the determination result of the special symbol determination is stopped and displayed on the first special symbol display 41 or the second special symbol display 42. A pattern confirmation command for notifying that the game has been played is set in the main RAM 103 (step S317). This symbol determination command is transmitted to the effect control board 130 by the transmission process of step S8. As a result, a process of stopping and displaying the decorative symbols that have been variably displayed on the liquid crystal screen 5 in a manner that indicates the determination result of the special symbol determination is performed.

Following the process of step S317, the main CPU 101 ends the variable display of the special symbols started in the process of step S314 (step S318). Specifically, the special symbol (big win symbol or losing symbol) set in the process of step S309 is stopped and displayed on the special symbol display device which has been variably displaying the special symbol. It should be noted that the stop display of this special symbol is continued until at least a predetermined symbol fixing time (for example, 1 second) elapses.

In this way, the main CPU 101 variably displays the special symbols on the first special symbol display 41 or the second special symbol display 42, and then displays the special symbol indicating the determination result of the big win determination process on the first special symbol display 41. Alternatively, the second special symbol display 42 is stopped and displayed.

Following the process of step S318, the main CPU 101 resets the variation time that started to be measured in the process of step S315 (step S319), and performs stop processing including a process of starting a jackpot game in the case of a jackpot. Execute (step S320). This in-stop process will be described later in detail with reference to FIG.

[Big hit determination processing by game control board 100]
FIG. 27 is a detailed flowchart of the big hit determination process in step S309 of FIG. Following the shift process in step S308, main CPU 101 first identifies the current set value (step S3090), similarly to the process in step S2180 of FIG. Next, a big hit determination is executed based on the big hit random number stored in the determination storage area 1030 (see FIG. 9A) (step S3091). Specifically, when it is in a low probability state, the jackpot random number table for low probability (see FIG. 14 (A)) is read from the main ROM 102 and set in the main RAM 103, and when it is in a high probability state, A high-probability jackpot random number table (see FIG. 14A) is read from the main ROM 102 and set in the main RAM 103 . Then, based on whether or not the jackpot random number stored in the determination storage area 1030 matches with any of the winning values stored in the jackpot random number table set in the main RAM 103, it is determined as a jackpot at the start of the variation. determine whether or not

When the main CPU 101 sets the low-probability jackpot random number table (see FIG. 14A), the jackpot random numbers stored in the determination storage area 1030 correspond to the current set values specified in the process of step S3090. It is determined whether or not it will be determined as a big win at the start of the fluctuation based on whether or not it matches with any of the attached winning values. When the specified current set value is "1", the jackpot random numbers stored in the determination storage area 1030 are selected from 90 winning values associated with the set value "1" (see FIG. 14A). ), it is determined whether or not it is a jackpot. In addition, when the specified current set value is "2", the jackpot random numbers stored in the determination storage area 1030 are 99 winning values associated with the set value "2" (Fig. 14 (A ) See)), it is determined whether or not it is a big hit based on whether or not it matches. In addition, when the specified current set value is "3", the jackpot random numbers stored in the determination storage area 1030 are 110 winning values associated with the set value "3" (Fig. 14 (A ) See)), it is determined whether or not it is a big hit based on whether or not it matches.

On the other hand, when the high-probability jackpot random number table (see FIG. 14A) is set, the main CPU 101 similarly determines that the jackpot random number stored in the determination storage area 1030 is currently specified in step S3090. Based on whether or not it matches with any of the winning values associated with the set values of , it is determined whether or not it will be determined as a big win at the start of the variation. If the specified current setting value is "1", the jackpot random numbers stored in the determination storage area 1030 are selected from 720 winning values associated with the setting value "1" (see FIG. 14A). ), it is determined whether or not it is a jackpot. In addition, when the specified current set value is "2", the jackpot random numbers stored in the determination storage area 1030 are 792 winning values associated with the set value "2" (Fig. 14 (A ) See)), it is determined whether or not it is a big hit based on whether or not it matches. In addition, when the specified current set value is "3", the jackpot random numbers stored in the determination storage area 1030 are 880 winning values associated with the set value "3" (Fig. 14 (A ) See)), it is determined whether or not it is a big hit based on whether or not it matches.

In this way, the main CPU 101 stores in the determination storage area 1030 the acquired information such as the jackpot random number acquired when the game ball enters the first start port 11 or the second start port 12. When the conditions are established, it is determined whether or not to execute a big win game advantageous to the player based on the big win random number and the current set value.

Following the processing of step S3091, the main CPU 101 determines whether or not the determination result of the big win determination is a big win (step S3092). Here, when it is determined that it is a big win (step S3092: YES), the kind of big win is determined by referring to the symbol determination table for the big win stored in the main ROM 102 (step S3093).

Specifically, when the symbol random number stored in the determination storage area 1030 together with the jackpot random number used for the jackpot determination in step S3091 relates to the first special symbol determination, the symbol random number is , the type of jackpot is determined based on which random number values stipulated in the symbol determination table (see FIG. 14(B)) for the first start opening prize match. For example, when the symbol random number related to the first special symbol determination stored in the determination storage area 1030 matches any one of the 40 random numbers associated with the jackpot symbol X1, the type of jackpot is determined. Decide on "10R probability change". On the other hand, if it relates to the second special symbol determination, the symbol random number matches with any random number defined in the symbol determination table for the second starting opening winning (see FIG. 14(C)). determines the type of jackpot. For example, when the symbol random number related to the second special symbol determination stored in the determination storage area 1030 matches one of the 160 random numbers associated with the jackpot symbol Y3, the type of jackpot is determined. Decide on "5R normal".

Then, the main CPU 101 sets, in the main RAM 103, the setting information of the jackpot symbol corresponding to the determined jackpot type (step S3094). For example, when the type of jackpot related to the first special symbol determination is "10R probability variation", the setting information of the jackpot symbol X1 is set in the main RAM103. Further, for example, when the kind of jackpot related to the second special symbol determination is “5R normal”, the setting information of the jackpot symbol Y3 is set in the main RAM 103 . As a result, the jackpot pattern set here during the process of step S318 is stopped and displayed on the first special pattern display device 41 or the second special pattern display device 42, and a jackpot game corresponding to the special pattern is performed. will be taken.

On the other hand, when the main CPU 101 determines that it is not a big win (step S3092: NO), it sets the setting information of the losing symbol in the main RAM 103 (step S3095). As a result, the lost symbol set here during the process of step S318 is stopped and displayed on the first special symbol display 41 or the second special symbol display . In this case, the jackpot game is not performed.

[Variation pattern selection processing by game control board 100]
FIG. 28 is a detailed flowchart of the variation pattern selection process in step S310 of FIG. After executing the big win determination process in step S309 of FIG. 26, the main CPU 101 determines whether or not the determination result in step S3091 is a big win (step S3101). Here, if it is determined to be a big win (step S3101: YES), the big win variation pattern table (see FIG. 15A) is read from the main ROM 102 and set in the main RAM 103 (step S3102).

On the other hand, when the main CPU 101 determines that it is not a big hit (step S3101: NO), the reach random number stored in the determination storage area 1030 is replaced with the reach random number winning value stored in the main ROM 102 (FIG. 14 (D )), it is determined whether or not to perform a ready-to-win effect that makes the player expect a big win (step S3103). Here, if it is determined that the ready-to-win effect is performed (step S3103: YES), the ready-to-win variation pattern table (see FIG. 15B) is read from the main ROM 102 and set in the main RAM 103 (step S3104). Conversely, if it is determined that the ready-to-win effect is not performed (step S3103: NO), the change pattern table for losing (see FIG. 15C) is read from the main ROM 102 and set in the main RAM 103 (step S3105).

Subsequently, the main CPU 101 refers to the fluctuation pattern table set in the main RAM 103 by the process of step S3102, the process of step S3104, or the process of step S3105, and executes the fluctuation pattern random number determination process (step S3106). Specifically, when the big hit variation pattern table or the reach variation pattern table is set in the main RAM 103, the variation pattern corresponding to the variation pattern random number stored in the determination storage area 1030 is Select one variation pattern by reading from the pattern table.

Also, when the fluctuation pattern table for losing is set in the main RAM 103, the number of pending special symbol determination is specified based on the number of pending storage areas in which various information is stored immediately before the shift processing of step S308 is performed. , A variation pattern is selected by reading a variation pattern corresponding to the specified pending number and the presence or absence of the current time saving from the variation pattern table for loss.

By selecting the special symbol variation pattern in this manner, the special symbol variation time is inevitably determined.

When the variation pattern is selected, the main CPU 101 sets the setting information of the selected variation pattern in the main RAM 103 (step S3107). This variation pattern setting information is included in the variation start command and transmitted to the effect control board 130 together with the pattern setting information set in the main RAM 103 by the jackpot determination process in step S309 described above.

[Stopping process by game control board 100]
FIG. 29 is a detailed flowchart of the stop processing in step S320 of FIG. After resetting the variation time by the process of step S319, the main CPU 101 determines whether or not it is a big win, as illustrated in FIG. 29 (step S3201). Here, if it is determined to be a jackpot (step S3201: YES), the jackpot game flag stored in the main RAM 103 is set to "ON" (step S3202), and the time saving game flag also stored in the main RAM 103 is set. And the probability variation game flag is set to "OFF" (step S3203).

In addition, in the gaming machine 1 of the present embodiment, the game state is controlled by setting the time saving game flag and the probability variation game flag. That is, when controlling the gaming state to the "probability variation gaming state", both the probability variation gaming flag and the time saving gaming flag are set to "ON", and when controlling the gaming state to the "time saving gaming state" the probability variation gaming flag is set to "OFF" and the time saving game flag is set to "ON", and both the probability variable game flag and the time saving game flag are set to "OFF" when controlling the game state to "normal game state" be.

Following the processing of step S3203, the main CPU 101 sets an opening command to the main RAM 103 for notifying that the jackpot game will start (step S3204). This opening command includes information such as the type of jackpot and the opening pattern of the jackpot 13 during the jackpot game, and is transmitted to the effect control board 130 by the transmission process of step S8.

On the other hand, when the main CPU 101 determines that it is not a big hit (step S3201: NO), it determines whether or not the time saving game flag is set to "ON" (step S3206). Here, if it is determined that the time saving game flag is set to "ON" (step S3206: YES), the remaining time saving game count J stored in the main RAM 103 is updated to a value obtained by subtracting "1" (step S3207). This time-saving game residual number J indicates the remaining number of times special symbol determination is executed in the time-saving state (high base state).

Following the process of step S3207, the main CPU 101 determines whether or not the remaining time saving game count J is "0" (step S3208). Here, when it is determined that the time saving game residual number J is "0" (step S3208: YES), the time saving game flag is set to "OFF" (step S3209). As a result, the electric chewing support function is no longer provided.

When the main CPU 101 executes the process of step S3209, when it determines that the time saving game flag is not "ON" (step S3206: NO), or when it determines that the remaining time saving game number J is not "0" ( Step S3208: NO), it is determined whether or not the variable probability game flag is set to "ON" (step S3211).

When the main CPU 101 determines that the variable probability game flag is set to "ON" (step S3211: YES), the main CPU 101 updates the high probability game residual count K stored in the main RAM 103 by subtracting "1". (Step S3212). This high-probability game residual number K indicates the remaining number of times the special symbol determination is executed in the high-probability state.

Following the process of step S3212, the main CPU 101 determines whether or not the high-probability game remaining number K is "0" (step S3213). Here, when it is determined that the high probability game residual number K is "0" (step S3213: YES), the probability variation game flag is set to "OFF" (step S3214). As a result, special symbol determination is performed in a low probability state.

When the processing of this step S3214 is performed, if it is determined that the probability variation gaming flag is not "ON" (step S3211: NO), if it is determined that the high probability game residual number K is not "0" ( Step S3213: NO), or when the processing of step S3214 is performed, the processing proceeds to the normal design processing of step S4.

[Game state setting processing by game control board 100]
Next, with reference to FIG. 30, the game state setting process executed at the end of the jackpot game will be described. Here, FIG. 30 is a detailed flowchart of the game state setting process performed at the end of the jackpot game. When the jackpot game ends, the main CPU 101 determines that the jackpot that triggered the current jackpot game is a variable probability jackpot (in this embodiment, “10R variable probability” or "5R probability change": It is determined whether it is (see FIG. 14 (C) and (D)) (step S601). Here, when it is determined that it is not a variable probability jackpot (step S601: NO), the process proceeds to step S606, which will be described later.

When the main CPU 101 determines that it is a variable probability jackpot (step S601: YES), it sets the variable probability game flag to "ON" (step S602), and sets the high probability game residual number K to, for example, "10000" (step S603), the time saving game flag is set to "ON" (step S604), and the time saving game remaining number J is set to "10000" (step S605). By performing the processing of these steps S602 to S605, the probability variation gaming state continues until the special symbol determination is performed 10,000 times after the jackpot game ends. That is, substantially, the probability variation gaming state will continue until the next big hit.

On the other hand, when the main CPU 101 determines that it is not a variable probability jackpot (step S601: NO), it sets the time saving game flag to "ON" (step S606), and sets the remaining time saving game count J to "80" (step S606). S607). By performing the processing of steps S606 and S607 in this way, if a big hit does not occur on the way after the end of the big win game, the time-saving game state continues until the special symbol determination is performed 80 times. Become.

[Timer interrupt processing by production control board 130]
When the gaming machine 1 is activated, the sub CPU 131 of the effect control board 130 sets a CTC cycle, which is a cycle for performing timer interrupt processing, which will be described later. Then, the sub CPU 131 repeats the random number update process for updating the effect random number or the like used for determining the contents of the effect at a predetermined cycle shorter than the CTC cycle. That is, while the gaming machine 1 is running, the sub CPU 131 repeats the random number update process at predetermined intervals and repeats the timer interrupt process at the CTC intervals.

Hereinafter, timer interrupt processing executed in the effect control board 130 will be described with reference to FIG. Here, FIG. 31 is a flow chart showing an example of timer interrupt processing executed in the effect control board 130. As shown in FIG. The sub CPU 131 repeats a series of processes illustrated in FIG. 31 at regular time intervals (for example, 4 milliseconds) in the same manner as the timer interrupt process performed by the game control board 100 . In addition, the process performed by the production|presentation control board 130 demonstrated based on the flowchart after FIG. 31 is performed according to the command which sub CPU131 issues based on the program memorize|stored in sub ROM132.

The sub CPU 131 first executes a command reception process including a process of performing a process according to the command when a command is received from the game control board 100 (step S50). This command reception processing will be described later in detail with reference to FIG.

Following the processing of step S50, the sub CPU 131 executes command transmission processing (step S70). Specifically, the command set in the sub-RAM 133 by the process of step S50 is transmitted to the image sound control board 140 (and the lamp control board 150). By executing this command transmission process, the image sound control board 140 is instructed to execute effects such as image display and sound output, and the lamp control board 150 is instructed to execute effects such as lighting of various lamps. instructed.

Then, the sub CPU 131 executes data transfer processing (step S90). Specifically, since data relating to image sound control is transmitted from the image sound control unit 140 , the data is transferred to the lamp control unit 150 . As a result, the lamp control unit 150 controls the performance by the performance medium such as the board lamp 25, the frame lamp 37, the performance accessory 7, etc. so as to synchronize with the performance performed by the liquid crystal screen 5 and the speaker 24.

[Command reception processing by effect control unit 130]
FIG. 32 is a detailed flowchart of command reception processing in step S50 of FIG. As illustrated in FIG. 32, the sub CPU 131 first determines whether or not a command transmitted from the game control board 100 is received (step S51). Here, if it is determined that the command has not been received (step S51: NO), the process proceeds to step S70.

When the sub CPU 131 determines that it has received a command from the game control board 100 (step S51: YES), the command is step S219 (see FIG. 23) or step S229 (see FIG. 24) according to game control It is determined whether or not it is a hold command transmitted from the board 100 (step S52).

When the sub CPU 131 determines that the received command is a pending command (step S52: YES), it executes pending command reception processing (step S53). This pending command reception process will be described later in detail with reference to FIG.

On the other hand, when the sub CPU 131 determines that the received command is not the pending command (step S52: NO), the received command is the game control board 100 according to the processing of step S312 shown in FIG. 26 or the processing of step S313. (step S55). Here, when it is determined that the received command is a variation start command (step S55: YES), a variation start command reception process is executed (step S56). This fluctuation start command reception processing will be described later in detail with reference to FIG.

When the sub CPU 131 determines that the received command is not the variation start command (step S55: NO), the received command determines the symbol transmitted from the game control board 100 according to the process of step S317 (see FIG. 26). It is determined whether or not it is a command (step S58). When the sub CPU 131 determines that it is a symbol confirmation command (step S58: YES), the sub CPU 131 terminates the variation display of the decorative symbols and stops and displays the decorative symbols indicating the determination result of the special symbol determination executed at the start of the symbol variation. A variable effect end command instructing execution of processing is set in the sub-RAM 133 (step S59).

By transmitting this fluctuation effect end command to the image sound control unit 140 and the lamp control unit 150 by the process of step S70, the special symbol indicating the determination result of the first special symbol determination (or the second special symbol determination) Along with being stopped and displayed on the 1 special symbol display device 41 (or the second special symbol display device 42), a decorative symbol indicating the determination result of the first special symbol determination (or the second special symbol determination) is displayed on the liquid crystal screen 5. Stop display (actual stop) is performed.

When the sub CPU 131 determines that the received command is not the pattern confirmation command (step S58: NO), the received command is the opening command transmitted from the game control board 100 in accordance with the process of step S3204 (see FIG. 29). It is determined whether or not (step S60). When the sub CPU 131 determines that it is an opening command (step S60: YES), it sets an opening effect start command for instructing execution of an opening effect during the opening period of the jackpot game in the sub RAM 133 (step S61).

The opening effect is started by transmitting this opening effect start command to the image sound control unit 140 and the lamp control unit 150 by the process of step S70.

On the other hand, if it is determined that the received command is not the opening command (step S60: NO), processing according to another command is executed (step S62). For example, if the received command is an operation command transmitted from the lamp control board 150, it is determined whether the effect button 26 or the effect key 27 has been operated based on the operation command. If it has been operated, it specifies which key has been operated and sets an operation notification command for notifying it in the sub-RAM 133 .

[Pending command reception processing by production control board 130]
FIG. 33 is a detailed flowchart of the pending command reception process in step S53 of FIG. When the sub CPU 131 determines that the received command is a pending command (step S52: YES), as illustrated in FIG. updated to the new value (step S531). Specifically, when the hold command related to the first special symbol determination is received, the number of reserves of the first special symbol determination is updated to a value obtained by adding "1", and the hold command related to the second special symbol determination is received. When it does, it updates to the value which added "1" to the number of reservations of the 2nd special design decision.

Next, the sub CPU 131 determines whether or not the received pending command includes the prior determination information (step S532), and if it determines that the prior determination information is not included (step S532: NO). , an icon display command is set (step S533).

This icon display command is a command to display a pending icon indicating that the special symbol determination has been suspended, and is transmitted to the image sound control board 140 and the lamp control board 150 by the command transmission process of step S70. This icon display command includes winning start opening information, and the supervising CPU 141 of the image sound control board 140 determines, for example, which of the first special symbol determination and the second special symbol determination has been suspended. A pending icon is displayed in the corresponding display area (if the first special symbol determination is pending, the pending icon display area 51: see FIG. 16).

It should be noted that if the received pending command does not contain the pre-determination information, it is not possible to perform the pre-reading effect based on the result of the pre-determination such as the above-described icon change effect. Therefore, when the processing of step S533 is performed, the suspension icon in the normal display mode (white suspension icon in this embodiment) is displayed, and the icon change effect is not performed.

On the other hand, if the sub CPU 131 determines that the received pending command contains the prior determination information (step S532: YES), the sub CPU 131 stores the prior determination information in a predetermined area of the sub RAM 133 (step S534).

Next, the sub CPU 131 executes an icon change effect lottery (step S535). Specifically, first, an icon change effect random number is obtained and stored in the sub-RAM 133 . This icon change effect random number is incremented by "1" each time the random number update process described above is performed, and the sub CPU 131 acquires the count value at the time of receiving the hold command as the icon change effect random number. Whether or not to execute the icon change effect is determined based on whether or not it matches with any of the random numbers relating to the icon change effect random numbers stored in advance in the sub ROM 132 .

It should be noted that, in the present embodiment, when receiving a hold command containing advance determination information indicating that it will be a big hit, the icon It is easier to decide to execute the change production. Also, when the variation time of the variation pattern of the special symbols specified based on the advance determination information is relatively long, it is easier to decide to execute the icon change effect than when it is relatively short.

The sub CPU 131 determines whether or not to execute the icon change effect based on the lottery result of step S535 (step S536). A drawing lottery is performed to select one of the plurality of icon change performance patterns, and the selected icon change performance pattern is set in a sub-RAM 133 (step S537).

It should be noted that here, the case where the lottery for determining whether or not to execute the icon change effect and the lottery for selecting the effect pattern of the icon change effect are separate lotteries has been described as an example, but the icon change effect is executed. It may be determined by one lottery whether or not the icon change effect is to be executed and, if executed, in what effect pattern the icon change effect is to be executed.

When the sub CPU 131 executes the process of step S537 or determines not to execute the icon change effect (step S536: NO), the sub CPU 131 determines that the received hold command is It is determined whether or not it relates to the suspension of the first special symbol determination (step S539). Here, when it is determined that it is not related to the suspension of the first special symbol determination (step S539: NO), the process proceeds to step S543 to be described later.

When the sub CPU 131 determines that the received hold command is related to the hold of the first special symbol determination (step S539: YES), the mode transition effect lottery is executed (step S540). Specifically, based on the pre-determination information stored in the sub-RAM 133 in the process of step S534, it is determined whether or not the pre-determination information is the pre-determination information indicating a big hit. Here, when it is determined that it is the advance determination information indicating a big win, a big win mode transition pattern selection table (not shown) stored in the sub ROM 132 is read out and set in the sub RAM 133 . On the other hand, when it is determined that it is not the advance determination information indicating a big hit (it is the advance determination information indicating a loss), a mode transition pattern selection table for losing (not shown) stored in the sub ROM 132 is read out and the sub RAM 133 set to

It should be noted that these mode transition pattern selection tables are tables for determining whether or not to execute the mode transition effect, and in what transition pattern the effect mode is to be shifted in the case of executing the mode transition effect. . Although detailed description is omitted, the former mode transition pattern table is characterized in that the mode transition effect is more likely to be executed than the latter mode transition pattern table. Also, in the comparison when executing the mode transition effect, the former mode transition pattern table is compared to the latter mode transition pattern table. mode).

The sub CPU 131 obtains, for example, the count value at the time of receiving the pending command as the mode transition effect random number, which is added by "1" each time the random number update process described above is performed. Then, in step S540, one mode transition pattern is selected by reading the mode transition pattern corresponding to this mode transition effect random number from the mode transition pattern selection table set in the sub-RAM 133. FIG. In addition, in the mode transition pattern selection table, multiple random numbers are associated with no mode transition effect, and if the mode transition effect random number matches one of these random values, the mode transition effect will be performed. Decided not to run.

The sub CPU 131 determines whether or not to execute the mode transition effect based on the lottery result of step S540 (step S541). Here, if it is determined to execute the mode transition effect (step S541: YES), the mode transition pattern selected by the mode transition effect lottery in step S540 is set in a predetermined area of the sub RAM 133 as setting information for the mode transition effect ( step S542).

When the sub CPU 131 executes the process of step S542 or determines not to execute the mode transition effect (step S541: NO), the sub CPU 131 sets the icon display command in the sub RAM 133 (step S543).

When the process of step S537 is executed, an icon display command including an icon change effect pattern is set in step S543, and this icon display command is transmitted to the image sound control board 140 and the image sound control board 140 by the command transmission process of step S70. By transmitting to the lamp control board 150, an icon change effect is performed.

Well, if the process of step S542 has been executed, an icon display command including a mode transition pattern is set in step S543, and this icon display command is transmitted by the command transmission process of step S70 to the image sound control board 140 and the lamp control board. By transmitting to the substrate 150, a mode transition effect is performed.

[Variation start command reception processing by production control board 130]
FIG. 34 is a detailed flowchart of the fluctuation start command reception process in step S56 of FIG. When the sub CPU 131 determines that the command received from the game control board 100 is the variation start command (step S55: YES), it executes a series of processes illustrated in FIG.

That is, the sub CPU 131 acquires the value at the time when the variation start command is received from the game control board 100 and stores it in the sub RAM 133 regarding the performance random number appropriately updated by the random number update process described above (step S561). Next, it is determined whether or not a set value is included in the received fluctuation start command (step S562). (step S563).

In the gaming machine 1 of this embodiment, when the variation start command not including the set value set in the process of step S312 in FIG. There is a case where the variation start command including the set value is transmitted from the game control board 100, and when the latter variation start command is transmitted, the processing of the above step S563 is executed, and the former variation start command is transmitted. If so, the process proceeds to step S564, which will be described later, without executing the process of step S563.

By the way, the setting change operation for setting the set value related to the jackpot probability to any one of "1" to "3" is performed, for example, before the opening of the hall in which the gaming machine 1 is installed. It is preferable not to perform this setting change operation until the store closes. In this way, by preventing the setting change operation from being performed while the hall is open, a game disadvantageous to one player is played and a game advantageous to another player is played. It is possible to prevent problems such as

On the other hand, for example, although the set value is set to "1" by the setting change operation before opening the hall, an illegal player uses some device to change the set value in the set value main storage area 1041. is changed to "3", there is a possibility that the illegal player will gain an unfair advantage.

Therefore, in order to prevent such problems from occurring, it is conceivable to employ the following configuration and processing, for example. Specifically, in the game control board 100, the main CPU 101 shifts to the power recovery mode after the operation of the switch 32 for turning the power back on in the second RAM clear mode (see FIG. 10), immediately after the set value A setting change end command including the setting value stored in this storage area 1041 is transmitted to the effect control board 130 . On the other hand, when the sub CPU 131 receives the setting change end command, the sub CPU 131 stores the setting value included in the setting change end command in a predetermined area of the sub RAM 133 as the normal setting value.

When the sub CPU 131 determines that the received variation start command includes a set value (step S562: YES), the set value matches the normal set value pre-stored in the sub RAM 133. Determine whether or not Here, if it is determined that the set value matches the regular set value, the process of step S563 described above is executed, and the set value included in the variation start command is stored in a predetermined area of the sub-RAM 133 . On the other hand, if it is determined that the value does not match the normal set value, the process of step S563 is not executed, and an error notification process is executed to notify that there is a possibility that an illegal operation has been performed. Specifically, for example, an error message "A setting error has occurred" is displayed on the liquid crystal screen 5, and an error command is set in the sub-RAM 133 to instruct execution of a process of outputting a predetermined error sound from the speaker 24. Then, this error command is transmitted to the image sound control board 140 (and the lamp control board 150) by the command transmission processing of step S70.

Thus, when the setting change process is completed, the set value (regular set value) is sent from the game control board 100 to the effect control board 130, and the sub CPU 131 receives the variation start command including the set value. In addition, by judging whether or not the setting value matches the regular setting value and executing error notification processing according to the judgment result, it is possible to detect the possibility that an unauthorized setting change operation has been performed. It is possible for the hall clerk to grasp easily.

In the present embodiment, an example will be described in which the sub CPU 131 performs effect control related to the zebra effect in the high probability state based on the set value included in the variation start command. In contrast, in another embodiment, when the setting change operation is completed, the main CPU 101 transmits a setting change end command including the setting values stored in the main setting value storage area 1041, while at the same time Even in this state, a change start command that does not include a setting value is transmitted, the sub CPU 131 holds the setting value included in the setting change end command in the sub RAM 133, and the held setting value is changed. , the effect control of the zebra effect in the high-probability state may be executed.

Returning to the description of FIG. 34, when the sub CPU 131 executes the process of step S563 or determines that the set value is not included in the fluctuation start command (step S562: NO), the sub CPU 131 analyzes the received fluctuation start command. (step S564).

In this variation start command, as described above, the symbol setting information indicating the determination result of the big hit determination process, and whether the symbol setting information relates to the first special symbol determination or the second special symbol determination Winning start opening information indicating whether or not it is a thing, setting information of the variation pattern of the special symbol, information indicating the game state of the gaming machine 1, and the like are included. Therefore, by analyzing the fluctuation start command, it is possible to specify the type and result of the special symbol determination. In other words, it is possible to specify whether it is a big win or a loss, and if it is a big win, what kind of big win it is. Further, by specifying whether or not the variation pattern is a variation pattern for losing based on the setting information of the variation pattern, it is possible to determine whether it is necessary to perform the effect with reach or the effect without reach. . Also, based on the setting information of the variation pattern, it is possible to specify the variation time of the special symbol. Also, the current game state of the gaming machine 1 can be specified based on the information indicating the game state.

After analyzing the fluctuation start command, the sub CPU 131 executes a fluctuation production pattern setting process for setting a fluctuation production pattern of the fluctuation production accompanying the fluctuation display of the special symbols based on the analysis result (step S565). By executing this variable effect pattern selection setting, the variation mode of the decorative pattern, the presence or absence of the reach effect, the presence or absence of the pseudo-continuous effect, the type of the decorative pattern constituting the reach pattern, the type and content of the reach effect, and the pseudo-continuous effect , the type of decoration pattern to be stopped and displayed, etc. are determined. This variation effect pattern setting process will be described later in detail with reference to FIG.

Subsequently, the sub CPU 131 executes a notice effect pattern setting process for setting various notice effects to be executed when the decorative symbols are variably displayed according to the variable effect pattern set in the process of step S565 (step S566). By executing the process of step S566, it is determined whether or not to execute the advance notice effect such as the zebra effect, and in what kind of effect pattern it is executed in the case of executing the advance notice effect. be. This advance notice effect pattern setting process will be described later in detail with reference to FIG.

Next, the sub CPU 131 sub-submits a variable effect start command for instructing the start of the variable effect in the variable effect pattern set in the processing of step S565 and the start of the notice effect in the notice effect pattern set in the process of step S566. It is set in the RAM 133 (step S567).

This variable effect start command includes information indicating the variable effect pattern set by the process of step S565 and information indicating the notice effect pattern set by the process of step S566, and command transmission process of step S70. is sent to the image sound control board 140 and the lamp control board 150 by. As a result, the variable effect and the advance notice effect for which the effect pattern is determined in the effect control board 130 are realized by the image sound control board 140 and the lamp control board 150 .

Following the process of step S567, the sub CPU 131 subtracts "1" from the pending number stored in the sub RAM 133 (step S568). Specifically, when the variation start command received from the game control board 100 notifies the start of the symbol variation related to the first special symbol determination, subtract "1" from the pending number of the first special symbol determination. updated to the specified value. On the other hand, when the received variation start command notifies the start of the symbol variation related to the second special symbol determination, the number of pending of the second special symbol determination is updated to a value obtained by subtracting "1".

[Variation production pattern selection processing by production control board 130]
FIG. 35 is a detailed flowchart of the variable effect pattern setting process in step S565 of FIG. Following the process of step S564, the sub CPU 131 sets a decorative symbol to be finally stopped (mainly stopped) on the liquid crystal screen 5 following the stop display of the first special symbol (or second special symbol) (step S5651). Specifically, based on the symbol setting information included in the variation start command received from the game control board 100, at the end of the symbol variation, whether a special symbol indicating a big win is stopped or displayed, or a special symbol indicating a loss is displayed. Specifies whether the symbol is to be statically displayed. Then, when it is specified that the special pattern indicating the big win is to be stopped and displayed, a decorative pattern (for example, a decorative pattern showing doubles) for notifying the big win is set as the decorative pattern to be permanently stopped to indicate a failure. When it is specified that the special pattern is stopped and displayed, a decorative pattern is set for informing of the failure. In addition, when setting the decorative pattern for notifying the loss, if the loss is notified after performing the reach production, the reach loss eyes are set as the decorative pattern for notifying the loss, and the reach production is performed. In the case of informing of a loss without any, a loose stitch is set as a decorative pattern for informing of a loss.

Next, the sub CPU 131 determines whether or not it is necessary to perform a ready-to-win effect accompanying the variable display of the special symbol this time, based on the setting information of the variation pattern of the special symbol included in the received variation start command. is determined (step S5652). Here, when it is judged that there is no need to perform the production with reach (step S5652: NO), the variation production pattern of production without reach is set (step S5653). For example, any one corresponding to the production random number obtained in the process of step S561 from the no-reach variable production pattern selection table in which a plurality of types of variable production patterns of the non-reach production are associated with each variation pattern of the special symbol A variable performance pattern is read, and information indicating the variable performance pattern is set in a sub-RAM 133. - 特許庁

On the other hand, when the sub CPU 131 determines that it is necessary to perform a ready-to-win effect (step S5652: YES), it sets a variable effect pattern for the ready-to-win effect (step S5654). For example, for each combination of the determination result of the special symbol determination and the variation pattern of the special symbol, from the variable effect pattern selection table for with reach, in which a plurality of types of variable effect patterns of the effect with reach are associated, step S561 Any one variation performance pattern corresponding to the performance random number acquired in the process is read, and information indicating the variation performance pattern is set in the sub-RAM 133. - 特許庁

By performing the processing of this step S5653 or step S5654, it is possible to determine with what kind of variation pattern the decorative symbols are variably displayed, which reach performance is performed when the reach performance is performed, and which reach performance is developed when the reach performance is developed. Whether or not to develop the ready-to-win effect in such a flow is determined.

The sub CPU 131 determines whether or not the mode transition pattern is set in the sub RAM 133 as a result of the processing of step S541 (see FIG. 33) (step S5655). Here, when it is determined that the mode transition pattern is not set (step S5655: NO), a series of fluctuation effect pattern selection processing is terminated, and the process proceeds to the notice effect pattern selection processing of step S566. In this case, since the mode transition effect is not performed, the variation effect is performed in the normal mode in this variation.

On the other hand, when the sub CPU 131 determines that the mode transition pattern is set (step S5655: YES), it sets the setting information regarding the mode transition effect (step S5656). For example, if a mode transition pattern is set that indicates that the normal mode will transition to a hot zone, the background image can be changed from the normal mode background image to the hot zone background image, or the speaker The setting information necessary for changing the variable effect sound output from 24 from the variable effect sound corresponding to the normal mode to the variable effect sound corresponding to the intense heat zone is generated, and the setting information is stored in the sub RAM 133. set.

[Variation production pattern selection processing by production control board 130]
FIG. 36 is a detailed flowchart of the advance notice effect pattern setting process in step S566 of FIG. The sub CPU 131 executes the following process following the variable effect pattern setting process in step S565. That is, the sub CPU 131 acquires the value at the time when the variation start command is received from the game control board 100 and stores it in the sub RAM 133 regarding the zebra effect random number appropriately updated by the random number update process described above (step S5661). Next, the sub CPU 131 determines whether or not the current state is the high probability state (step S5662). Specifically, for example, based on the information indicating the game state received from the game control board 100, it is determined whether or not the current state is the high probability state (step S5662).

By the way, in the gaming machine 1 of the present embodiment, when the game is controlled in the high probability state, the variation start command including the set value is transmitted from the game control board 100, while the game is started in the low probability state. If it is controlled, a variation start command that does not include the set value is transmitted from the game control board 100 (see FIG. 26).

Therefore, when the sub CPU 131 determines that the current state is not the high probability state (step S5662: NO), that is, when it determines that the game is controlled in the low probability state, the sub CPU 131 receives from the game control board 100 Since the set value is not included in the received variation start command, the current set value stored in the set value main storage area 1041 cannot be identified. In this way, in a state where the setting value cannot be specified in the low probability state, the following processing is performed.

That is, when the sub CPU 131 determines that the current state is not the high probability state (step S5662: NO), the current special symbol determination ( Here, it is determined whether or not the determination result of the first special symbol determination) is "big hit" (step S5663). Here, when it is determined that the determination result of the special symbol determination this time is "big win" (step S5663: YES), the low probability state/big win zebra effect determination table (see FIG. 20A) is read from the sub ROM 132. It is read out and set in the sub-RAM 133 (step S5664). Conversely, if it is determined that the determination result of the special symbol determination this time is not a "big hit" (step S5663: NO), that is, if it is "losing", the low probability state/losing zebra effect determination table ( 20B) is read and set in the sub-RAM 133 (step S5665).

On the other hand, if it is determined that the current state is a high probability state (step S5662: YES), that is, if the game is controlled in a high probability state, the variation start command including the set value from the game control board 100 In response to the transmission, the process of step S563 (see FIG. 34) for storing this setting value in the sub-RAM 133 has already been performed. In this case, the sub CPU 131 performs the following processing.

In other words, when the sub CPU 131 determines that the current state is the high probability state (step S5662: YES), similar to the process of step S5663, the determination of this special symbol determination (here, the first special symbol determination) It is determined whether or not the result is a "jackpot" (step S5667). Here, when it is determined that the determination result of the special symbol determination this time is "big win" (step S5667: YES), the high probability state/big win zebra effect determination table (see FIG. 20(C)) is read from the sub ROM 132. It is read out and set in the sub-RAM 133 (step S5668). Conversely, if it is determined that the determination result of the special symbol determination this time is not a "big hit" (step S5667: NO), that is, if it is "losing", the high probability state/losing zebra effect determination table ( 20(D)) is read out and set in the sub-RAM 133 (step S5669).

Thus, when one of the four types of zebra effect determination tables is set in the sub RAM 133, the sub CPU 131 determines whether or not to execute the zebra effect (step S5671). Here, when the low probability state/jackpot zebra effect determination table (see FIG. 20A) or the low probability state/losing zebra effect determination table (see FIG. 20B) is set, the sub CPU 131 A zebra effect is executed based on whether or not the zebra effect random number acquired and stored in the processing of step S5661 matches any of the random numbers associated with zebra effect in the set zebra effect determination table. Determine whether to execute or not. This determination process is as described above with reference to FIGS. 20A and 20B.

On the other hand, when the high probability state/jackpot zebra effect determination table (see FIG. 20(C)) or the high probability state/losing zebra effect determination table (see FIG. 20(D)) is set, the sub CPU 131 Whether or not to execute the zebra effect based on whether or not the zebra effect random number acquired and stored in the processing of step S5661 matches any of the random values associated with the current set value with the zebra effect present judge. This determination processing is as described above with reference to FIGS. 20C and 20D.

Then, when determining to execute the zebra effect (step S5671: YES), the sub CPU 131 sets setting information for executing the zebra effect in the sub RAM 133 (step S5672).

When the sub CPU 131 executes the process of step S5672, or determines not to execute the zebra effect (step S5671: NO), for example, the sub CPU 131 sets an effect pattern of another notice effect such as a step-up effect or a speech notice effect. A pattern setting process is executed (step S5673).

[Timer Interrupt Processing by Image Sound Control Board 140]
Next, timer interrupt processing executed in the image sound control board 140 will be described with reference to FIG. Here, FIG. 37 is a flow chart showing an example of timer interrupt processing executed in the image sound control board 140. As shown in FIG. The image sound control board 140 repeatedly executes a series of processes illustrated in FIG. 37 at regular time intervals (for example, 33 milliseconds) during normal operation except for special cases such as power-on and power-off. .

First, the overall CPU 141 executes image output control processing for controlling image display on the liquid crystal screen 5 based on the command received from the effect control board 130 (step S41). This image output control processing will be described later in detail with reference to FIG.

Following the processing of step S41, the general CPU 141 executes sound output control processing for outputting various sounds from the speaker 24 in synchronization with or asynchronously with the screen display performed on the liquid crystal screen 5 (step S42). ).

Following the processing of step S42, the overall CPU 141 executes data transmission control processing (step S43). Specifically, data relating to image sound control performed in the image sound control board 140 is transmitted to the effect control board 130 . In response to this, the effect control board 130 transfers the data received from the image sound control board 140 to the lamp control board 150 . Thereby, the frame lamp 25, the board lamp 37, the production accessories 7, etc. are controlled so as to synchronize with the production performed by the liquid crystal screen 5 and the speaker 24. FIG.

[Image Output Control Processing by Image Sound Control Board 140]
FIG. 38 is a detailed flowchart of image output control processing in step S41 of FIG. The overall CPU 141 first determines whether or not a command transmitted from the effect control board 130 is received (step S411). Here, if it is determined that the command has not been received (step S411: NO), the process proceeds to step S42.

On the other hand, when the overall CPU 141 determines that it has received a command from the effect control board 130 (step S411: YES), it sets the setting information included in the command to the control RAM 143 (step S412). Next, the supervising CPU 141 determines how various effects images should be displayed on the liquid crystal screen 5 based on the set setting information, and creates and controls a display list for controlling the drawing processing of the VDP 144. RAM 143 (step S413), and the display list is set in the display list storage area (step S414).

Here, the display list consists of a group of commands for instructing the execution of drawing in units of frames. It includes various parameters such as angle and transmittance. The display list storage area is provided in a VRAM having an SRAM capable of writing and reading image data at high speed. Executes the drawing process of the displayed image.

[About other game flows]
In the present embodiment, a case where the gaming machine 1 is a so-called variable probability loop type gaming machine will be described as an example, but the gaming machine 1 is not limited to this, and the high probability state (ST : special time) may be a so-called ST machine. When the game machine 1 is configured as an ST machine, it is conceivable to control the game in the following flow.

FIG. 39 is an explanatory diagram for explaining another flow of the game. When the game ball struck left in the normal game state wins the first starting port 11, the first special symbol determination is executed. Here, when it is determined to execute a jackpot game, the first special pattern display device 41 variably displays the first special pattern, and then the jackpot pattern is stop-displayed as the first special pattern. As this jackpot pattern, while preparing a probability variation pattern indicating that it is a probability variation jackpot, by not preparing a normal pattern indicating that it is a normal jackpot, all the jackpots related to the first special pattern determination are prepared. It becomes a probability variable jackpot (see FIG. 39 (A)), and after the jackpot game corresponding to this probability variable jackpot is completed, the game is controlled in a probability variable game state until, for example, 25 special symbol determinations are executed (Fig. 39(B)).

When shifting to this variable probability game state, the player makes a "right shot" aiming at the gate 16 and the second starting port 12. - 特許庁Since this variable probability gaming state is a high base state in which the game ball is likely to enter the second starting port 12, basically, when the game is controlled in the variable probability gaming state, the second special symbol determination is executed. will be

In this variable probability game state, when the player wins the big hit related to the second special symbol determination within 25 rotations, the variable probability symbol as the big winning symbol is stopped and displayed on the second special symbol display device 42, and the big win is achieved. After the game is over, the game is controlled again in the variable probability game state (see FIGS. 39(C) and (B)).

On the other hand, if the player can not hit the jackpot within 25 rotations in the variable probability game state, the state changes from the variable probability game state to the time-saving game state (see FIG. 39(D)). In this way, when shifting to the time-saving gaming state, if the player can draw a jackpot (all probability variable jackpots) within 55 rotations, after the jackpot game ends, the state shifts to the probability variable gaming state again (Fig. 39 (E) and ( B)).

On the other hand, if the player cannot hit the jackpot within 55 spins in the time-saving game state, the game state shifts from the time-saving game state to the normal game state (see FIG. 39(F)).

It should be noted that, here, was described as an example of the case of shifting to the probability variation gaming state if the jackpot is not drawn within 25 rotations during the probability variation gaming state, but if the jackpot is not drawn within 25 rotations, from the probability variation gaming state The game state may be shifted to the normal game state.

[Problems when configured as an ST machine]
By the way, when the gaming machine 1 of the present embodiment is configured as the ST machine as described above, the following problems are considered to occur. That is, as shown in FIG. 13, when the ratio of the jackpot probability in the high-probability state and the jackpot probability in the low-probability state is fixed regardless of the setting, the jackpot probability in the high-probability state varies depending on the setting. For example, in the example shown in FIG. 13, in the high probability state, the jackpot probability for the setting value "1" (low setting) is 1/27.5, and the jackpot probability for the setting value "2" (medium setting) is 1. /25, and the jackpot probability for the set value "3" (high setting) is 1/22.5.

The probability variable continuation rate in the ST machine can be calculated based on the jackpot probability in the high probability state and the ST number, which is the number of fluctuations in which the high probability state continues, as described above Set the jackpot probability in the high probability state In a configuration with a difference, there is a possibility that the probability variable continuation rate will differ for each setting.

[Solutions for the above problems]
Therefore, in order to solve the above problem when configured as a ST machine, the ratio of the jackpot probability in the high probability state and the jackpot probability in the low probability state is changed according to the setting, so that the probability is high regardless of the setting The jackpot probability in a state may be fixed (see FIG. 40).

FIG. 40 is an explanatory diagram for explaining another setting related to the probability of a big win. As illustrated in FIG. 40, when the jackpot probability in the low probability state for the set value "1" (low setting) is 1/220, by setting the ratio to 8 times, the high probability for the set value "1" Assume that the jackpot probability in the state is 1/27.5 (=1/220×8). Also, if the jackpot probability in the low probability state for the set value "2" (medium setting) is 1/200, by setting the ratio to about 7.25 times, the jackpot probability in the high probability state for the set value "2" is about 1/27.5 (≈1/200×7.25). If the jackpot probability in the low probability state for the set value “3” (high setting) is 1/180, by setting the ratio to about 6.55 times, the jackpot probability in the high probability state for the set value “3” is about 1/27.5 (≈1/180×6.55).

In this way, by varying the ratio depending on the setting, it is possible to substantially eliminate the setting difference of the big win probability in the high probability state. In addition, FIG. 40 shows an example in which there is a slight setting difference in the jackpot probability in the high probability state for the convenience of the range that the jackpot random number can take, but the range that the jackpot random number can take and the low probability for each setting By devising the jackpot probability in each state and the ratio for each setting, the jackpot probability in the high-probability state of each setting may be completely matched.

[Modification example]
Note that FIG. 19B shows a configuration (first configuration) in which the jackpot probability in the high-probability state differs depending on the setting, and a configuration (second configuration) in which the execution ratio of the zebra effect varies depending on the setting. The appearance rate and reliability of the zebra effect when combined are illustrated.
On the other hand, the gaming machine 1 in which the first configuration is changed to a configuration (third configuration) in which the jackpot probability in the high-probability state is fixed regardless of the setting as described above with reference to FIG. Realization is also possible.

Hereinafter, the effect control of the zebra effect in the gaming machine 1 combining the second configuration and the third configuration will be described with reference to FIG. Here, FIG. 41 is an explanatory diagram for explaining other execution ratios, appearance ratios, and reliability levels of the zebra effect.

As illustrated in FIGS. 40 and 41, when the above configuration 3 is applied, the jackpot probability in the high probability state for the setting value "1" (low setting) and the high probability state for the setting value "2" (medium setting) , and the jackpot probability in the high-probability state with respect to the setting value "3" (high setting) are both 1/27.5.

Here, the set value "1" is stored in the set value main storage area 1041, and the sub CPU 131, based on the set value "1" included in the variation start command received in the high probability state, For example, if the zebra effect is executed at an execution rate of 40% at the time of the big win, the zebra effect appearance rate at the time of the big win is about 1.455% (≈ 1/27.5 x 0.4 x 100) ( See Figure 41).
In addition, the set value "2" is stored in the set value main storage area 1041, and the sub CPU 131, based on the set value "2" included in the fluctuation start command received in the high probability state, For example, if the zebra effect is executed at an execution rate of 50%, the zebra effect appearance rate at the time of the big win is about 1.818% (≈ 1/27.5 x 0.5 x 100) (Fig. 41).
In addition, the set value "3" is stored in the set value main storage area 1041, and the sub CPU 131, based on the set value "3" included in the fluctuation start command received in the high probability state, For example, if the zebra effect is executed at an execution rate of 60%, the zebra effect appearance rate at the time of the big win is about 2.182% (≈ 1/27.5 x 0.6 x 100) (Fig. 41).

On the other hand, if the jackpot probability is 1/27.5 regardless of the setting value, the probability of losing in the high probability state is 26.5/27.5 (=1-1/27 .5).

Here, the set value "1" is stored in the set value main storage area 1041, and the sub CPU 131, based on the set value "1" included in the variation start command received in the high probability state, For example, if the zebra effect is executed at an execution rate of 1.90% at the time of failure, the zebra effect appearance rate at the time of failure is about 1.831% (≈ 26.5 / 27.5 x 0.019 x 100 ) (see FIG. 41).
In addition, the set value "2" is stored in the set value main storage area 1041, and the sub CPU 131, based on the set value "2" included in the fluctuation start command received in the high probability state, For example, if the zebra effect is executed at an execution rate of 1.80%, the zebra effect appearance rate at the time of failure is about 1.735% (≈26.5/27.5 x 0.018 x 100). (See FIG. 41).
In addition, the set value "3" is stored in the set value main storage area 1041, and the sub CPU 131, based on the set value "3" included in the variation start command received in the high probability state, For example, if the zebra effect is executed at an execution rate of 1.70%, the zebra effect appearance rate at the time of failure is about 1.638% (≈26.5/27.5 x 0.017 x 100). (See FIG. 41).

In this way, when the set value is set to "1" in the high probability state, the zebra effect appearance rate at the time of the big win is 1.455%, and the zebra effect appearance rate at the time of the loss is 1.831%. , the total appearance rate of the zebra effect is 3.286% (=1.455+1.831), and in this case, the reliability of the big win of the zebra effect is about 44.28% (≈1.455/3. 286×100).
Also, when the set value is set to "2" in the high probability state, the zebra effect appearance rate at the time of the big win is 1.818%, and the zebra effect appearance rate at the time of the loss is 1.735%. Therefore, the overall appearance rate of the zebra effect is 3.553% (= 1.818 + 1.735), and in this case, the reliability of the big hit of the zebra effect is about 51.17% (≈ 1.818/3.553 x 100).
Also, when the set value is set to "3" in the high probability state, the zebra effect appearance rate at the time of the big win is 2.182%, and the zebra effect appearance rate at the time of the loss is 1.638%. Therefore, the overall appearance rate of the zebra effect is 3.820% (=2.182+1.638), and in this case, the reliability of the zebra effect is about 57.12% (≈2.182/3.820× 100).

As explained so far, the jackpot probability in the high-probability state is fixed regardless of the setting. By controlling the execution ratio of the zebra effect to be low, the higher the setting is, the higher the reliability of the zebra effect may be (see FIG. 41).

[Regarding productions targeted for production control]
In addition, in the present embodiment, production control (see FIG. 20 (A)) not based on the setting related to the jackpot determination probability and production control (see FIG. 20 (B) and FIG. 41) based on the setting related to the jackpot determination probability Target Although the case where the effect is a zebra effect has been described as an example, the effect that is the target of these effect control is not limited to the zebra effect, for example, a step-up effect or other advance notice effects such as dialogue notice may be In addition, the effects that are the targets of these effects control are not limited to the advance notice effects. It can be a performance.

[Action and effect of the present embodiment]
Thus, according to the gaming machine 1 of the present embodiment, as illustrated in FIG. 19(A), in the low probability state, the setting value related to the jackpot probability is transferred from the game control board 100 to the effect control board 130. It is not transmitted, and the execution ratio of the zebra effect at the time of the big win and the execution ratio of the zebra effect at the time of losing are fixed regardless of the setting. Therefore, as described above, it is possible to prevent the zebra effect from functioning as an overt setting suggestive effect and excessively arousing the gambling spirit of the player, and as a result, effectively immersing the player in the game. can be suppressed.

In addition, in the gaming machine 1 of the present embodiment, in the high probability state, the game control board 100 transmits a set value related to the big win probability to the effect control board 130, and the execution ratio of the zebra effect at the time of the big win and the The execution ratio of the zebra effect differs depending on the setting of the jackpot probability (see FIG. 19(B) and FIG. 41).

In this way, when the execution ratio of the zebra effect is changed depending on the setting, for example, as shown in FIG. In addition to lowering it, by increasing the execution ratio of the zebra effect at the time of losing, it is possible to eliminate the setting difference in the overall appearance rate and reliability of the zebra effect, and as a result, the zebra effect can suggest settings related to the probability of a big win. It is possible to effectively suppress the connection.

Further, when the execution ratio of the zebra effect is changed depending on the setting, as shown in FIG. By lowering the execution ratio of the zebra effect at time, it is possible to create a setting difference in the overall appearance rate and reliability of the zebra effect, and as a result, to effectively improve the interest of the zebra effect.

[Modification]
In addition, the present invention is not limited to the above-described embodiments, and may be, for example, in the following forms. That is, in the above embodiment, the case where the determination result of the special symbol determination is "big hit" or "losing" has been described, but the determination result of the special symbol determination is "big hit", "small hit", or "losing". It may be configured as follows. Incidentally, the small win may be a win in which a short opening round game is performed in which the big winning opening 13 is opened for a short period of time compared to the long opening round game, or a big winning opening including the V area is opened. Alternatively, it may be a hit that causes a so-called double hit on the condition that the game ball has passed through the V area.
In this way, when a part of the determination result of the special symbol determination is "small win", while changing the big win probability according to the setting, the configuration is adopted such that the small win probability does not change even if the setting changes. is preferred.

Further, in the above embodiment, the case where the present invention is applied to a so-called type 1 pachinko game machine has been described, but the present invention can be applied to other game machines such as a type 1 type and 2 types mixed type pachinko game machine. may

Further, the configuration of the gaming machine 1 and the operation mode of each member described in the above embodiment are merely examples, and it is needless to say that the present invention can be realized with other configurations and operation modes. In addition, the order of processing, set values, thresholds used for determination, etc. in the flowcharts described above are merely examples, and the present invention can be implemented with other orders and values without departing from the scope of the present invention. Needless to say. The screen diagrams and the like exemplified in the above embodiment are merely examples, and may be in other forms.

1 gaming machine 3 inner frame 4 display device 5 liquid crystal display device (liquid crystal screen)
6 outer frame 10 game area 11 first starting opening 12 second starting opening 13 big winning opening 14 normal winning opening 24 speaker 31 door opening switch 32 power switch 55 zebra effect image 100 game control board 101 main CPU
102 Main ROM
103 Main RAM
110 count switch 111 first start switch 112 second start switch 113 electric tulip control section 114 gate switch 115 large winning opening switch 116 large winning opening control section 117 normal winning opening switch 130 effect control board 131 sub CPU
132 sub ROMs
133 sub-RAM
134 RTCs
140 image sound control board 141 general CPU
142 control ROM
143 control RAM
144 VDP
145 Acoustic DSP
210 board case 211 reset cover 212 reset pin 213 setting cover 215 performance indicator 216 RAM clear switch 217 setting key switch 218 setting key insertion part 219 setting change pin 222 switching button 1039 game state storage area 1040 setting value temporary storage area 1041 setting value Main storage area 1042 Performance display storage area

Claims (1)

A gaming machine comprising a game control unit for controlling a game and an effect control unit for controlling an effect,
The game control unit is
Determination means for determining whether or not to execute a special game advantageous to the player;
A setting means for setting a set value indicating that the determination probability that the special game is to be executed by the determination means is one of a plurality of probabilities in response to a predetermined operation using the operation means;
setting value transmission means for transmitting the setting value set by the setting means at least when the setting by the setting means is completed;
a judgment result transmission means capable of transmitting the judgment result of the judgment means,
The production control unit is
capable of receiving the setting value transmitted by the setting value transmitting means and the determination result of the determining means transmitted by the determination result transmitting means;
It is possible to control the effect according to the determination result of the determination means without being based on the set value,
The gaming machine is characterized in that the possibility of executing the special game according to one of the effects is varied by a set value set by the setting means.

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