JP2020162763A - Game machine - Google Patents

Abstract

To detect a fraudulent act at an early stage.SOLUTION: A game machine is set to a game executable state in which a player can play a game or to a game inexecutable state in which the player cannot play a game. An error detection part can detect an error even when the game machine is set to the game inexecutable state.SELECTED DRAWING: Figure 25

Description

The present invention relates to a game machine.

Conventionally, when an abnormality (error) occurs in a game machine, the game ball is controlled so as not to be fired to stop the game (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2016-163631

As described above, in a gaming machine in which a game is stopped due to an error, there is a demand for the development of a technique capable of early detection that a fraudulent act has been performed while the game is stopped.

In order to solve the above problems, the gaming machine of the present invention detects an error and a state management means for setting a game-enabled state in which the player can play or a game-incapable state in which the player cannot play. The error detection unit includes an error detection unit, and the error detection unit can detect the error even when the game is set to the non-gaming state by the state management means.

Also, based on the input of the setting change operation, the setting change unit that executes the setting change process that sets any of the setting values provided in multiple stages as the registered setting value, and the setting based on the input of the setting confirmation operation. The state management means including a main control unit including a setting confirmation unit for executing a setting confirmation process for displaying the registered setting value, and a storage means for storing the history of the error detected by the error detection unit. Makes the game impossible state when at least one of the setting change process and the setting confirmation process is executed in the main control unit, and the storage means changes the setting in the main control unit. Even when at least one of the process and the setting confirmation process is executed and the error is detected by the error detection unit, the history of the error may be stored.

According to the present invention, it is possible to detect at an early stage that a fraudulent act has been committed.

It is a perspective view of the game machine which shows the state which the door is opened. It is a front view of a game machine. It is a front view of a game board. It is a figure for demonstrating the 2nd prize opening. It is a block diagram of a game machine. This is an address map of the memory area used by the main CPU. It is a figure explaining the jackpot determination random number determination table for special 1. It is a figure explaining the jackpot determination random number determination table for special 2. It is a figure explaining the hit symbol random number determination table. It is a figure explaining the reach group determination random number determination table. It is a figure explaining the reach mode determination random number determination table. It is a figure explaining the fluctuation pattern random number determination table. It is a figure explaining the fluctuation time determination table. It is a figure explaining the 1st special electric accessory actuating ram set table. It is a figure explaining the 2nd special electric accessory actuating ram set table. It is a figure explaining the opening / closing mode of the 2nd prize opening and the opening / closing mode of a specific area by a movable member. It is a figure explaining the game state setting table for setting the game state after the end of a big role game. It is a figure explaining the hit determination random number determination table. (A) is a diagram for explaining a normal symbol fluctuation time data table, and (b) is a diagram for explaining an open / close control pattern table. It is a figure explaining the game machine state flag. It is a 1st flowchart explaining the CPU initialization process in a main control board. It is a 2nd flowchart explaining the CPU initialization process in the main control board. It is a flowchart explaining the subcommand group set processing in a main control board. It is a flowchart explaining the evacuation process at the time of power-off in a main control board. It is a flowchart explaining the timer interrupt processing in a main control board. It is a flowchart explaining the setting-related processing in a main control board. It is a flowchart explaining the state management process in a main control board. It is a flowchart explaining the game machine state flag setting process in the main control board. It is a flowchart explaining the switch management process in a main control board. It is a flowchart explaining the gate passing process in a main control board. It is a flowchart explaining the 1st start port passage processing in a main control board. It is a flowchart explaining the 2nd start port passage processing in a main control board. It is a flowchart explaining the special symbol random number acquisition process in a main control board. It is a flowchart explaining the specific area passing process in a main control board. It is a figure explaining the special game management phase. It is a flowchart explaining the special game management process in a main control board. It is a flowchart explaining the special symbol change waiting process in a main control board. It is a flowchart explaining the special symbol hit detection process in a main control board. It is a flowchart explaining the special symbol variation number determination process in a main control board. It is a flowchart explaining the process during special symbol change in a main control board. It is a flowchart explaining the special symbol stop symbol display processing in a main control board. It is a flowchart explaining the big prize opening opening preprocessing in a main control board. It is a flowchart explaining the big prize opening opening / closing switching process in a main control board. It is a flowchart explaining the big prize opening opening control process in a main control board. It is a flowchart explaining the big prize opening closing effective processing in a main control board. It is a flowchart explaining the big prize opening end wait processing in a main control board. It is a figure explaining a normal game management phase. It is a flowchart explaining the normal game management process in a main control board. It is a flowchart explaining the normal symbol change waiting process in a main control board. It is a flowchart explaining the process during ordinary symbol change in a main control board. It is a flowchart explaining the normal symbol stop symbol display processing in a main control board. It is a flowchart explaining the processing before opening the winning opening of a normal electric accessory in a main control board. It is a flowchart explaining the ordinary electric accessory winning opening opening / closing switching process in a main control board. It is a flowchart explaining the ordinary electric accessory winning opening opening control process in a main control board. It is a flowchart explaining the normal electric accessory winning opening closing effective processing in a main control board. It is a flowchart explaining the ordinary electric accessory winning opening end weight processing in a main control board. (A) is a diagram for explaining an example of a setting confirmation screen, (b) is a diagram for explaining an example of an administrator menu screen, and (c) is a diagram for explaining an example of a standby screen. (D) is a diagram for explaining an example of the staff menu screen. (A) is a diagram for explaining setting change history information, and (b) is a diagram for explaining error history information. It is a flowchart explaining the sub-CPU initialization process in a sub-control board. It is a flowchart explaining the subtimer interrupt processing in a sub-control board. It is a flowchart explaining the command reception process in a sub-control board. It is a flowchart explaining operation input process in a sub-control board.

A preferred embodiment of the present invention will be described in detail below with reference to the accompanying drawings. The dimensions, materials, other specific numerical values, and the like shown in such an embodiment are merely examples for facilitating the understanding of the invention, and do not limit the present invention unless otherwise specified. In the present specification and drawings, elements having substantially the same function and configuration are designated by the same reference numerals to omit duplicate description, and elements not directly related to the present invention are not shown. To do.

In order to facilitate understanding of the embodiments of the present invention, first, the mechanical configuration and the electrical configuration of the game machine will be briefly described, and then specific processing on each substrate will be described.

FIG. 1 is a perspective view of the game machine 100 of the present embodiment, showing a state in which the door is opened. As shown in the figure, the game machine 100 includes an outer frame 102 in which a surrounding space is formed by four sides assembled in a substantially rectangular shape, an inner frame 104 that is openably and closably attached to the outer frame 102 by a hinge mechanism, and the like. The middle frame 104 is provided with a front frame 106 that is openably and closably attached by a hinge mechanism.

Similar to the outer frame 102, the middle frame 104 has a surrounding space formed by four sides assembled in a substantially rectangular shape, and the game board 108 is held in the surrounding space. Further, the front frame 106 holds a transparent plate 110 made of glass or resin. When the middle frame 104 and the front frame 106 are closed with respect to the outer frame 102, the game board 108 and the transmission plate 110 face each other substantially in parallel while maintaining a predetermined interval, and from the front side of the game machine 100. , The game board 108 becomes visible through the transparent plate 110.

FIG. 2 is a front view of the game machine 100, and FIG. 3 is a front view of the game board 108. However, FIG. 2 shows a state in which the game board 108 has been removed. As shown in FIG. 2, an operation handle 112 projecting to the front side of the game machine 100 is provided at the lower part of the front frame 106. The operation handle 112 is provided so that the player can rotate the operation handle 112, and when the player rotates the operation handle 112 to perform a firing operation, the strength corresponding to the rotation angle of the operation handle 112 is not shown. A game ball is launched by the launch mechanism. As shown in FIG. 3, the game ball launched in this way rises between the rails 114a and 114b provided on the game board 108 and is guided to the game area 116.

The game area 116 is a space formed at a distance between the game board 108 and the transmission plate 110, and is an area in which the game ball can flow down or roll. A large number of nails and windmills are provided on the game board 108, and the game ball guided to the game area 116 collides with the nails and the windmill so as to flow down and roll in an irregular direction.

The game area 116 includes a first game area 116a and a second game area 116b in which the degree of entry of the game ball differs from each other according to the firing intensity of the firing mechanism. The first game area 116a is located on the left side of the game area 116 as seen from the player facing the game machine 100, and the second game area 116b is the game area 116 as seen from the player facing the game machine 100. It is located on the right side of. Since the rails 114a and 114b are on the left side of the game area 116, the game ball launched by the firing mechanism with a firing intensity lower than the predetermined strength enters the first game area 116a and is launched with a firing strength equal to or higher than the predetermined strength. The resulting game ball enters the second game area 116b.

Further, the game area 116 is provided with a general winning opening 118, a first starting port 120, and a second starting port 122 into which a game ball can enter, and these general winning openings 118, the first starting port 120, and the first 2 When a game ball enters the starting port 122, a predetermined prize ball is paid out to the player. The number of prize balls may be any number as long as it is one or more, and the number of prize balls to be paid out at each of the general winning opening 118, the first starting port 120, and the second starting port 122 may be different. , The same number of prize balls may be set. At this time, it is also possible to set the number of prize balls that the game ball enters and pays out to the first starting port 120 to be smaller than the number of prize balls that the game ball enters and pays out to the second starting port 122. is there.

As will be described in detail later, when a game ball enters the first starting port 120 or the second starting port 122, a lottery is made to determine any one of the plurality of special symbols provided in advance. Is done. Each special symbol is associated with whether or not a small hit game, which is advantageous for the player, can be executed. Therefore, when the game ball enters the first start port 120 or the second start port 122, the player obtains a predetermined prize ball and at the same time obtains an opportunity to acquire the right to receive a predetermined game profit. Become.

The first starting port 120 is provided inside the accessory device X provided on the game board 108. The accessory device X is provided with an introduction port 138 that opens vertically upward, so that only the game balls that flow down the first game area 116a enter the accessory device X from the introduction port 138 at a predetermined ratio. It is configured in. However, the game ball flowing down the second game area 116b may be configured to enter the accessory device X from the introduction port 138.

In the accessory device X, a constantly movable body 144 that constantly reciprocates in the left-right direction during the game is provided. Further, in the accessory device X, a plurality of rolling paths through which the game ball passes are provided between the introduction port 138 and the constantly movable body 144, and the inside of the accessory device X is provided from the introduction port 138. The game ball that enters the ball is distributed to one of the rolling paths. Each rolling path is configured so that the game ball can be discharged onto the constantly movable body 144, but as described above, since the constantly movable body 144 moves in the left-right direction, it remains as it is depending on the fall timing of the game ball. It falls downward and is discharged to the outside from the accessory device X.

The constantly movable body 144 is formed in a dish shape, and a through hole penetrating in the vertical direction is formed in the center thereof. The game ball that has fallen on the constantly movable body 144 from the rolling path stays on the constantly movable body 144 and then falls downward from the through hole. Here, the first starting port 120 is provided below the constantly movable body 144, and is formed on the constantly movable body 144 when the constantly movable body 144 is located substantially in the center in the width direction of the game machine 100. The through hole and the first starting port 120 face each other in the vertical direction. Therefore, the game ball that stays on the movable body 144 at all times enters the first starting port 120 at the timing of falling from the through hole. Of the game balls that entered the accessory device X from the introduction port 138, all the game balls that did not enter the first start port 120 are discharged from below the accessory device X to the game area 116. The Rukoto. Here, the probability that the game ball that has entered the accessory device X will enter the first starting port 120 is set to about 1/20.

Further, the second starting port 122 is located in the second game area 116b, and only the game ball flowing down the second game area 116b can enter the ball, or the game that has entered the second game area 116b. The ball is arranged at a position where it is easier to enter than the game ball that has entered the first game area 116a. The second starting port 122 is configured by a variable starting winning device having a movable piece 122b, so that the ease of entry of the game ball into the second starting port 122 is variable. Specifically, the second starting port 122 is provided so that the movable piece 122b can be opened and closed, and when the movable piece 122b is in the closed state, it is impossible for the game ball to enter the second starting port 122. It has become difficult.

On the other hand, when the game ball passes through the gate 124 provided in the second game area 116b, a lottery of a normal symbol described later is performed, and when the winning is won by this lottery, the movable piece 122b is in an open state for a predetermined time. Is controlled by. In this way, when the movable piece 122b is opened, the movable piece 122b functions as a saucer for guiding the game ball to the second starting port 122, and the game ball can easily enter the second starting port 122.

Further, only the game ball flowing down the second game area 116b can enter the second game area 116b, or the game ball that has entered the second game area 116b is the first game area 116a. The first big winning opening 126 and the second big winning opening 128 are provided at positions where it is easier to enter than the game ball that has entered. In the following, the first large winning opening 126 and the second large winning opening 128 may be collectively referred to as a large winning opening.

FIG. 4 is a diagram for explaining the second large winning opening 128. The second game area 116b is provided with a structure 129 that projects toward the front side of the game board 108. An opening is formed in the upper part of this structure 129, and this opening serves as a second large winning opening 128. A movable piece 128b is provided on the upper part of the structure 129, and normally, as shown in FIG. 4A, the movable piece 128b is maintained in a closed state in which the second special winning opening 128 is closed. ..

The movable piece 128b protrudes into the game area 116 where the game ball rolls and flows down so as to face above the game machine 100. Therefore, when the movable piece 128b is maintained in the closed state, the game ball flowing down the game area 116 (second game area 116b) falls on the movable piece 128b. Here, the movable piece 128b maintained in the closed state is inclined so that the left side of the game machine 100 is slightly lower than the right side. Therefore, when the movable piece 128b is in the closed state, as shown by the arrow in FIG. 4A, the game ball that has fallen on the movable piece 128b slowly rolls on the movable piece 128b from right to left. It will move.

Then, when the small hit game described later is executed, the movable piece 128b shifts to an open state in which the second large winning opening 128 is opened. Here, as shown in FIGS. 4A and 4B, the movable piece 128b is arranged in the front-rear direction (front and back) of the game machine 100 from a hole formed in the game board 108 by an actuator (solenoid) (not shown). Infested in the direction). Normally, the actuator is maintained in a non-energized state, the movable piece 128b is held at a position protruding toward the front side from the hole of the game board 108, and the second special winning opening 128 is closed. Then, when the actuator is energized, as shown in FIG. 4B, the movable piece 128b is held at a position immersed in the back side of the hole of the game board 108, and the second large winning opening 128 is opened. To. In this way, in the state where the second big winning opening 128 is opened, the game ball enters the second big winning opening 128.

A lead-out path 128d is provided inside the second major winning opening 128, and the game ball that has entered the second major winning opening 128 is guided to the lead-out path 128d in the second major winning opening 128. It is tilted so that it can be caught. The lead-out path 128d is provided with a specific area 140b and a non-specific area 140c formed of holes through which the game ball can pass, and the game ball that has entered the second special winning opening 128 is in the specific area 140b and non-specific area 140b. It is configured to pass through any of the specific areas 140c and be discharged to the back side of the game board 108.

The second special winning opening 128 is provided with a movable member 142 that opens and closes the specific area 140b and the non-specific area 140c. The movable member 142 is switched between a state in which the game ball can enter the specific area 140b and a state in which the game ball cannot enter the specific area 140b by its movement (sliding). More specifically, when the movable member 142 is displaced to the position shown in FIG. 4C, the non-specific area 140c is blocked by the movable member 142, and the game ball can pass through the specific area 140b. On the other hand, when the movable member 142 is displaced to the position shown in FIG. 4D, the specific area 140b is blocked by the movable member 142, and the game ball can pass through the non-specific area 140c. As will be described in detail later, when the game ball enters the specific area 140b in the small hit game, it becomes a big hit (two kinds of big hits), and the above-mentioned big role game is started.

Returning to FIG. 3, at the bottom of the game area 116, all of the general winning openings 118, the first starting opening 120, the second starting opening 122, the first major winning opening 126, and the second major winning opening 128 are entered. A discharge port 130 is provided to discharge the unplayed game ball from the game area 116 to the back side of the game board 108.

Then, as shown in FIGS. 2 and 3, the game machine 100 includes an effect display device 200 composed of a liquid crystal display device and an effect accessory device 202 composed of a movable device as effect devices for producing an effect while the game is in progress. An effect lighting device 204 composed of lamps controlled by various lighting modes and emission colors, an audio output device 206 composed of speakers, and an effect button 208 that accepts a player's operation are provided.

The effect display device 200 includes an effect display unit 200a including an image display unit for displaying an image. The effect display unit 200a is arranged so as to be visible from the front side of the game machine 100 in the upper center of the game board 108. Images for various effects are displayed on the effect display unit 200a.

The effect accessory device 202 operates in accordance with the image displayed on the effect display unit 200a to give the player a sense of expectation.

The effect lighting device 204 is provided on the effect accessory device 202, the game board 108, and the like, and various lighting controls are performed according to the image and the like displayed on the effect display unit 200a.

The sound output device 206 is provided at the upper position of the front frame 106 and the lowest position of the outer frame 102, and various sounds are directed toward the front side of the game machine 100 according to the image displayed on the effect display unit 200a and the like. Is output.

The effect button 208 is composed of a button that accepts a player's pressing operation, is provided at a substantially central position in the width direction of the game machine 100, and is provided at a position below the transparent plate 110. This effect button 208 is activated according to an image or the like displayed on the effect display unit 200a, and when a player's operation is received within the operation effective time, various effects are generated according to the operation. Will be executed.

The cross key 209 is composed of four buttons, an upper button, a lower button, a left button, and a right button, which accept the player's pressing operation, and is provided in the vicinity of the effect button 208. The effect button 208 and the cross key 209 may be used when making various settings.

Reference numeral 132 in the figure is an upper plate on which the prize ball paid out from the game machine 100 and the game ball rented from the game ball lending device are guided. When the upper plate 132 is filled with the game ball, the game ball becomes It will be guided to the lower plate 134. Further, on the bottom surface of the lower plate 134, a ball extraction hole (not shown) for discharging the game ball from the lower plate 134 is formed. This ball pulling hole is normally closed by an opening / closing plate (not shown), but when the ball pulling knob 134a is pushed in, the opening / closing plate slides integrally with the ball pulling knob 134a, and the ball pulling hole It is possible to discharge the game ball below the lower plate 134.

Further, as shown in FIG. 3, on the game board 108, the first special symbol display 160 and the second special symbol display 160 and the second special symbol display are located outside the game area 116 and at a position visible to the player. 162, a first special symbol hold indicator 164, a second special symbol hold indicator 166, a normal symbol indicator 168, a normal symbol hold indicator 170, and a right-handed notification indicator 172 are provided. Each of these indicators 160 to 172 is a device for displaying various situations related to the game, and the details thereof will be described later.

(Internal configuration of control means)
FIG. 5 is a block diagram of the game machine 100. The main control board 300 controls the basic operation of the game. The main control board 300 includes a main CPU 300a, a main ROM 300b, and a main RAM 300c. Based on the input signals from each detection switch and timer, the main CPU 300a reads the program stored in the main ROM 300b and performs arithmetic processing, directly controls each device and display, or produces the result of arithmetic processing. Send commands to other boards accordingly. The main RAM 300c functions as a data work area during arithmetic processing of the main CPU 300a.

The game machine 100 of the present embodiment is started mainly by a special game started by entering the game ball into the first starting port 120 or the second starting port 122 and by passing the game ball through the gate 124. It is roughly divided into ordinary games. The main ROM 300b of the main control board 300 stores various programs for advancing special games and normal games, as well as data and tables required for various games.

The main control board 300 has a general winning opening detection switch 118s for detecting that a game ball has entered the general winning opening 118, and a first starting port for detecting that a game ball has entered the first starting port 120. Detection switch 120s, 2nd start port detection switch 122s for detecting that a game ball has entered the 2nd start port 122, gate detection switch 124s for detecting that a game ball has passed through the gate 124, 1st grand prize opening First big winning opening detection switch 126s that detects that a game ball has entered 126, second big winning opening detection switch 128s that detects that a game ball has entered the second big winning opening 128, introduction port 138 The effect switch 138s for detecting that the game ball has passed, the specific area detection switch 140s for detecting that the game ball has entered the specific area 140b, and the out ball detection switch 130s for detecting the game ball discharged from the game area 116. Is connected, and a detection signal is input to the main control board 300 from each of these detection switches.

A merging passage is provided on the back surface of the game board 108, and the general winning opening 118, the first starting opening 120, the second starting opening 122, the first large winning opening 126, and the second major winning opening 128 are entered, respectively. The ball is configured so that the ball and the game ball guided from the discharge port 130 to the back side merge at the confluence passage and are guided to the equipment of the game hall. The out-ball detection switch 130s is provided in the confluence passage, and all the game balls discharged from the game area 116, in other words, all the game balls fired in the game area 116 are detected by the out-ball detection switch 130s. Detected.

Further, on the main control board 300, the ordinary electric accessory solenoid 122c that operates the movable piece 122b of the second starting port 122 and the first special winning opening solenoid 126c that operates the opening / closing door 126b that opens and closes the first winning opening 126c. , The second prize opening solenoid 128c that operates the movable piece 128b that opens and closes the second prize opening 128, the constantly movable body motor 144c that operates the constantly movable body 144, and the movable member provided in the second prize opening 128. A movable member drive solenoid 142c that moves 142 is connected, and the main control board 300 controls opening and closing of the second starting port 122, the first winning opening 126, the second winning opening 128, and the specific area 140b. In addition, the movable body 144 is constantly controlled to move.

Further, the main control board 300 includes a first special symbol display 160, a second special symbol display 162, a first special symbol hold indicator 164, a second special symbol hold indicator 166, a normal symbol display 168, and a normal symbol display. The symbol hold indicator 170 and the right-handed notification indicator 172 are connected to each other, and the display control of each of these indicators is performed by the main control board 300.

Further, the gaming machine 100 has an abnormality such as a radio wave detection sensor for detecting radio waves, a magnetic detection sensor for detecting magnetism, a vibration sensor for detecting vibration, a door opening sensor for detecting an open state of the middle frame 104 and the front frame 106, and the like. Alternatively, a plurality of abnormality detection sensors 174 for detecting the possibility of fraud are provided, and each abnormality detection sensor 174 is configured to input an abnormality detection signal to the main control board 300.

Further, a setting change switch 180s is provided on the back surface of the game board 108. The setting change switch 180s is configured to be accessible by a dedicated key. The operation of changing and confirming the set value is possible on condition that the setting change switch 180s is turned on. As will be described in detail later, in the game machine 100 of the present embodiment, any one of the six levels of set values having different degrees of advantage is stored as a registered set value in the set value buffer, and the game is played according to the stored registered set value. Progresses.

Further, a RAM clear button is provided on the back surface of the game board 108 so that it can be pressed, and the operation of pressing the RAM clear button is detected by the RAM clear switch 182s. The RAM clear switch 182s is connected to the main control board 300, and a RAM clear operation signal is input from the RAM clear switch 182s to the main control board 300. When the RAM clear operation signal is input from the RAM clear switch 182s when the power is turned on, the main CPU 300a clears the main RAM 300c.

A performance display monitor 184 is provided on the back surface of the game board 108. The main control board 300 displays the registered set value and the base ratio on the performance display monitor 184.

Further, the payout control board 310 and the sub control board 330 are connected to the main control board 300.

The payout control board 310 controls for launching the game ball and controls for paying out the prize ball. The payout control board 310 also includes a CPU, a ROM, and a RAM, and is connected to the main control board 300 so as to be able to communicate in both directions. A game information output terminal board 312 is connected to the payout control board 310, and various information on the game progress output from the main control board 300 is transmitted via the payout control board 310 and the game information output terminal board 312. , Will be output to the hall computer of the amusement store.

Further, the payout control board 310 is connected to a payout motor 314 for paying out the game balls stored in the storage unit to the player as prize balls. The payout control board 310 controls the payout motor 314 based on the payout number designation command transmitted from the main control board 300 to control the player to pay out a predetermined prize ball. At this time, the number of game balls paid out is detected by the payout ball counting switch 316s, and it is possible to grasp whether the prize balls to be paid out have been paid out to the player.

Further, the payout control board 310 is connected to a dish full tank detection switch 318s that detects the full tank state of the lower dish 134. The plate full tank detection switch 318s is provided in a passage that guides the game ball to be paid out as a prize ball to the lower plate 134, and each time the game ball passes through the passage, a game ball detection signal is sent to the payout control board 310. It is supposed to be entered.

Then, when a predetermined amount or more of game balls are stored in the lower plate 134 and become full, the game balls stay in the passage toward the lower plate 134, and the plate full tank detection switch 318s is directed toward the payout control board 310. , The game ball detection signal is continuously input. When the game ball detection signal is continuously input for a predetermined time, the payout control board 310 determines that the lower plate 134 is in a full tank state, and transmits a plate full tank command to the main control board 300. On the other hand, if the continuous input of the game ball detection signal is interrupted after the dish full tank command is transmitted, it is determined that the dish full tank state has been released, and the dish full tank release command is transmitted to the main control board 300.

Further, the launch control circuit 320 is bidirectionally connected to the payout control board 310 so as to be communicable. When the launch control circuit 320 receives the launch control data from the payout control board 310, the launch control circuit 320 permits the launch. The launch control circuit 320 is connected to a touch sensor 112s provided on the operation handle 112 and detecting that the player touches the operation handle 112, and an operation volume 112a for detecting the operation angle of the operation handle 112. Has been done. Then, when a signal is input from the touch sensor 112s and the operation volume 112a, the launch control circuit 320 controls to energize the launch solenoid 112c provided in the game ball launcher to launch the game ball.

The sub-control board 330 mainly controls each effect such as during a game or during standby. The sub control board 330 includes a sub CPU 330a, a sub ROM 330b, a sub RAM 330c, and an RTC 330d, and is connected to the main control board 300 so as to be communicable from the main control board 300 to the sub control board 330 in one direction. ing. The sub CPU 330a reads the program stored in the sub ROM 330b, performs arithmetic processing, and executes and controls the effect based on the command transmitted from the main control board 300, the input signal from the timer, and the like. At this time, the sub RAM 330c functions as a data work area during the arithmetic processing of the sub CPU 330a.

Specifically, the sub-control board 330 performs image display control for displaying an image on the effect display unit 200a. A large number of various image data displayed on the effect display unit 200a are stored in the sub ROM 330b, and the sub CPU 330a reads the image data from the sub ROM 330b into a VRAM (not shown) to display the image of the effect display unit 200a. Control.

In addition, the sub-control board 330 moves the effect accessory device 202, controls the lighting of the effect lighting device 204, and controls the sound output from the sound output device 206. Furthermore, when an operation detection signal is input from the effect button detection switch 208s that detects that the effect button 208 has been pressed, and the cross key detection switch 209s that detects that the cross key 209 has been pressed. , Perform a predetermined process.

A power supply board (not shown) is connected to each board, and power is supplied from a commercial power source to each board via the power supply board. Further, the power supply board is provided with a backup power supply composed of a capacitor. The RTC330d provided on the sub-control board 330 receives power from the backup power source and measures the current time.

FIG. 6 is an address map of the memory area used by the main CPU 300a. In FIG. 6, the address is shown in hexadecimal, and "H" is shown in hexadecimal. As shown in FIG. 6, the memory area used by the main CPU 300a includes a memory area (0000H to 2FFFH) allocated to the main ROM 300b and a memory area (F000H to F3FFH) allocated to the main RAM 300c.

The memory area of the main ROM 300b is a used area (0000H to 1A7AH) for storing a program and data for controlling the progress of the game, and an area other than the used area, and is a process for performing a test specified by the game machine rules. An unused area (2000H to 2BFFF) for storing a program and data for executing a process for displaying the performance display monitor 184 (including a process for calculating the base ratio displayed on the performance display monitor 184). And are provided.

The used area of the main ROM 300b includes a program area (0000H to 0A89H) in which a program for controlling the progress of the game is stored, an unused area (0A8AH to 0FFFH), and a data area (1000H) in which data other than the program is stored. ~ 1A7AH) is provided. The used area may not include an unused area (0A8AH to 0FFFH).

The non-use area of the main ROM 300b is a program area (2000H to 27FFH) in which a program for executing a process for performing a test specified by the game machine rules and a process for displaying the performance display monitor 184 is stored. A data area (2800H to 2BFFH) for storing data other than these programs is provided.

In addition to the used area and the unused area, the memory area of the main ROM 300b is a ROM comment area (1E00H to 1EFFH) in which arbitrary data such as an unused area (1A7BH to 1DFFH), a program title, and a version are stored. ), An unused area (1F00H to 1FFFH), an unused area (2C00H to 2FBFH), and a program management area (2FC0H to 2FFFH) in which information necessary for the main CPU 300a to execute a program is stored.

The memory area of the main RAM 300c is a used area (F000H to F1FFH) temporarily used when a program for controlling the progress of the game is executed, and an area other than the used area, according to the game machine rules. An unused area (F210H to F228H) that is temporarily used when a program for performing a predetermined test or a process for displaying the performance display monitor 184 is executed is provided.

The used area of the main RAM 300c includes a work area (F000H to F12AH) temporarily used when a program for controlling the progress of the game is executed, an unused area (F12BH to F1D7H), and the progress of the game. A stack area (F1D8H to F1FFH) for temporarily saving data during execution of a program for control is provided. The used area may not include an unused area (F12BH to F1D7H).

In the unused area of the main RAM 300c, a work area (F210H) temporarily used when a processing program for performing a test specified by the game machine rules and a processing program for displaying the performance display monitor 184 is being executed. ~ F21FH), and stack areas (F220H to F228H) for temporarily saving data when these programs are being executed are provided.

Further, in the memory area of the main RAM 300c, an unused area (F200H to F20FH) and an unused area (F229H to F3FFH) are provided in addition to the used area and the unused area.

As described above, in the main ROM 300b and the main RAM 300c, the used area used for controlling the progress of the game, the process for performing the test specified by the game machine rules, and the process for controlling the display of the performance display monitor 184. It is provided separately from the unused area used to execute.

In the main RAM 300c, a 16-byte unused area (F200H to F20FH) is provided between the used area and the unused area. This unused area (F200H to F20FH) is set as a boundary area that separates the used area and the unused area, the boundary between the used area and the unused area becomes clear, and a program for controlling the progress of the game is provided. When the unused area is used during execution, and when the program for performing the test specified by the game machine rules and the processing for controlling the display of the performance display monitor 184 is being executed. It prevents the used area from being used.

The unused area provided between the used area and the unused area may be at least 1 byte or more, preferably 4 bytes or more from the viewpoint of fraud prevention, and is set to 16 bytes or more. Is more desirable. Further, although the unused area is prohibited from writing and reading data, it may be cleared at a predetermined timing from the viewpoint of preventing fraud.

Next, the game in the game machine 100 of the present embodiment will be described together with various tables stored in the main ROM 300b.

As described above, in the game machine 100 of the present embodiment, two types of games, a special game and a normal game, proceed in parallel, and a non-time-saving game state is defined as a game state when both of these games are performed. Alternatively, the game progresses in any of the game states of the time-saving game state.

The details of each game state will be described later, but the non-time-saving game state is a game state in which the movable piece 122b is difficult to open and the game ball is difficult to enter the second starting port 122, and the time-saving game state. This is a gaming state in which the movable piece 122b is more likely to be opened and the gaming ball is more likely to enter the second starting port 122 than in the non-time saving gaming state. The initial state of the game machine 100 is set to the non-time saving game state.

When the player operates the operation handle 112 to launch the game ball into the game area 116 and the game ball flowing down the game area 116 enters the first start port 120 or the second start port 122, the player is allowed to play the game. A lottery for whether or not to give a profit (hereinafter referred to as a "major role lottery") is held. In this big role lottery, if a big hit or a small hit is won, the first big winning opening 126 and the second big winning opening 128 are opened, and the game ball to the first big winning opening 126 and the second big winning opening 128 A large role game or a small hit game that allows the ball to enter is executed. In addition, the game state after the end of the major role game is set to any of the above game states. The major role lottery method will be described below.

As will be described in detail later, when a game ball enters the first start port 120 or the second start port 122, various random numbers related to the big win lottery (big hit decision random number, hit symbol random number, reach group decision random number, reach). The mode determination random number and the fluctuation pattern random number) are acquired, and each of these random number values is stored in the special figure reservation storage area of the main RAM 300c. In the following, various random numbers stored in the special figure hold storage area when the game ball enters the first start port 120 are collectively referred to as special 1 hold, and the game ball enters the second start port 122. The various random numbers stored in the special figure hold storage area are collectively called special 2 hold.

The special figure reservation storage area of the main RAM 300c includes a first special figure reservation storage area and a second special figure reservation storage area. The first special figure reserved storage area and the second special figure reserved storage area each have four storage units (first to fourth storage units). Then, when the game ball enters the first start port 120, the special 1 hold is stored in order from the first storage unit of the first special figure hold storage area, and when the game ball enters the second start port 122, the special 1 hold is stored. 2 Holds are stored in order from the first storage unit of the second special figure hold storage area.

For example, when a game ball enters the first starting port 120, if the hold is not stored in any of the first storage units to the fourth storage units of the first special figure hold storage area, the first storage Store special 1 hold in the department. Further, for example, when a game ball enters the first starting port 120 in a state where the special 1 hold is stored in the first storage unit to the third storage unit, the special 1 hold is set to the fourth storage unit. Remember. Further, even when the game ball enters the second starting port 122, the special 2 hold is stored in the 1st to 4th storage units of the 2nd special figure hold storage area in the same manner as described above. Special 2 hold is stored in the storage unit with the smallest number (ordinal number).

However, the number of special 1 hold (X1) and the number of special 2 hold (X2) that can be stored in the first special figure hold storage area and the second special figure hold storage area are set to four, respectively. Therefore, for example, when the game ball enters the first starting port 120, if four special 1 holdings are already stored in the first special figure holding storage area, the first starting port 120 is entered. No new special 1 hold is memorized by entering the game ball. Similarly, when the game ball enters the second starting port 122, if four special 2 holdings are already stored in the second special figure holding storage area, the game to the second starting port 122 is played. No new special 2 hold is memorized by entering the ball.

FIG. 7 is a diagram illustrating a jackpot determination random number determination table for Special 1. When a game ball enters the first starting port 120 or the second starting port 122, one jackpot determination random number is acquired from the range of 0 to 65535. Then, when the big win lottery is started, that is, the big hit determination random number determination table is selected according to the game state when the big hit is determined, and the selected jackpot determination random number determination table and the acquired jackpot determination random number are used. A big role lottery will be held.

When starting the big win lottery for the special 1 hold, the big hit determination random number judgment table for the special 1 is referred to. Here, in the present embodiment, six levels of set values having different degrees of advantage are provided, and a special 1 jackpot determination random number determination table is provided for each set value. During the game, the set value is set to one of the six stages, and the special 1 jackpot determination random number determination corresponding to the currently set set value (registered set value stored in the set value buffer) is determined. A big role lottery is held with reference to the table.

When the set value = 1 (registered set value = 1), the big winning combination lottery is performed with reference to the special 1 jackpot determination random number determination table a shown in FIG. 7 (a). According to this special 1 jackpot determination random number determination table a, when the jackpot determination random number is 10001 to 12780, it is determined to be a jackpot, and when the jackpot determination random number is 20001 to 20655, it is determined to be a small hit, and others. If it is a big hit decision random number, it is judged as a loss. Therefore, the jackpot probability in this case is about 1 / 23.5, and the small hit probability is about 1 / 100.0.

When the set value = 2 (registered set value = 2), the big winning combination lottery is performed with reference to the special 1 jackpot determination random number determination table b shown in FIG. 7 (b). According to this special 1 jackpot determination random number determination table b, when the jackpot determination random number is 10001 to 12880, it is determined to be a jackpot, and when the jackpot determination random number is 20001 to 20655, it is determined to be a small hit, and others. If it is a big hit decision random number, it is judged as a loss. Therefore, the jackpot probability in this case is about 1 / 22.7, and the small hit probability is about 1 / 100.0.

When the set value = 3 (registered set value = 3), the big winning combination lottery is performed with reference to the special 1 jackpot determination random number determination table c shown in FIG. 7 (c). According to the jackpot determination random number determination table c for special 1, if the jackpot determination random number is 10001 to 12980, it is determined to be a jackpot, if the jackpot determination random number is 20001 to 20655, it is determined to be a small hit, and others. If it is a big hit decision random number, it is judged as a loss. Therefore, the jackpot probability in this case is about 1 / 21.9, and the small hit probability is about 1 / 100.0.

When the set value = 4 (registered set value = 4), the big winning combination lottery is performed with reference to the special 1 jackpot determination random number determination table d shown in FIG. 7 (d). According to this special 1 jackpot determination random number determination table d, when the jackpot determination random number is 10001 to 13080, it is determined to be a jackpot, when the jackpot determination random number is 20001 to 20655, it is determined to be a small hit, and others. If it is a big hit decision random number, it is judged as a loss. Therefore, the jackpot probability in this case is about 1 / 12.2, and the small hit probability is about 1 / 100.0.

When the set value = 5 (registered set value = 5), the big winning combination lottery is performed with reference to the special 1 jackpot determination random number determination table e shown in FIG. 7 (e). According to this special 1 jackpot determination random number determination table e, when the jackpot determination random number is 10001 to 13180, it is determined to be a jackpot, and when the jackpot determination random number is 20001 to 20655, it is determined to be a small hit, and others. If it is a big hit decision random number, it is judged as a loss. Therefore, the jackpot probability in this case is about 1 / 20.6, and the small hit probability is about 1 / 100.0.

When the set value = 6 (registered set value = 6), the big winning combination lottery is performed with reference to the special 1 jackpot determination random number determination table f shown in FIG. 7 (f). According to this special 1 jackpot determination random number determination table f, when the jackpot determination random number is 10001 to 13280, it is determined to be a jackpot, and when the jackpot determination random number is 20001 to 0655, it is determined to be a small hit, and others. If it is a big hit decision random number, it is judged as a loss. Therefore, the jackpot probability in this case is about 1 / 19.9, and the small hit probability is about 1 / 100.0.

FIG. 8 is a diagram illustrating a jackpot determination random number determination table for special 2. When starting the big win lottery for the special 2 hold, the big hit determination random number judgment table for the special 2 is referred to. The special 2 jackpot determination random number determination table is also provided for each set value in the same manner as the special 1 jackpot determination random number determination table.

When the set value = 1 (registered set value = 1), the big winning combination lottery is performed with reference to the special 2 jackpot determination random number determination table a shown in FIG. 8A. According to this special 2 jackpot determination random number determination table a, when the jackpot determination random number is 10001 to 12780, it is determined to be a jackpot, and when the jackpot determination random number is 20001 to 28856, it is determined to be a small hit, and others. If it is a big hit decision random number, it is judged as a loss. Therefore, the jackpot probability in this case is about 1 / 23.5, and the small hit probability is about 1 / 7.4.

Similarly, when the set value = 2 to 6 (registered set value = 2 to 6), the special 2 jackpot determination random number determination tables b to f shown in FIGS. 8 (b) to 8 (f) are displayed. A large role lottery will be held with reference. According to these special 2 jackpot determination random number determination tables b to f, when the jackpot determination random numbers are the values shown in the figures, it is determined to be a jackpot. Therefore, when the set value = 2 to 6, the jackpot probability is about 1 / 22.7 to 1 / 19.9, respectively, and the small hit probability is about 1 / 7.4.

As described above, the big role lottery is performed according to the registered set value. At this time, the winning probability of the jackpot differs depending on the registered set value, and it is easier to win the jackpot when the registered set value is large than when it is small. Here, it is assumed that the winning probability of the small hit does not change even if the registered set value is different, but the winning probability of the small hit may be different for each registered set value. In addition, the small hit is not essential, and only one of the big hit and the loss may be decided in the big win lottery.

FIG. 9 is a diagram illustrating a winning symbol random number determination table. When a game ball enters the first starting port 120 or the second starting port 122, one winning symbol random number is acquired from the range of 0 to 99. Then, when the determination result of "big hit" or "small hit" is derived by the above-mentioned big win lottery, the type of the special symbol is determined by the acquired winning symbol random number and the winning symbol random number determination table. At this time, if the "big hit" is won by the special 1 hold, the symbol random number determination table a for the special 1 is selected as shown in FIG. 9A, and the "small hit" is won by the special 1 hold. In this case, as shown in FIG. 9B, the symbol random number determination table b for special 1 is selected. In addition, when the "big hit" is won by the special 2 hold, the symbol random number determination table a for the special 2 is selected as shown in FIG. 9 (c), and the "small hit" is won by the special 2 hold. In this case, as shown in FIG. 9D, the symbol random number determination table b for special 2 is selected. In the following, the special symbol determined by the hit symbol random number, that is, the special symbol determined when the jackpot judgment result is obtained is called a jackpot symbol, and is determined when the small hit determination result is obtained. A special symbol is called a small hit symbol, and a special symbol determined when a loss determination result is obtained is called a lost symbol.

According to the special 1 hit symbol random number determination table a shown in FIG. 9 (a) and the special 2 per symbol random number determination table a shown in FIG. 9 (c), according to the acquired value of the winning symbol random number, As shown in the figure, the type of special symbol (big hit symbol) is determined. Further, according to the special 1 per symbol random number determination table b shown in FIG. 9 (b) and the special 2 per symbol random number determination table b shown in FIG. 9 (d), the value of the acquired per symbol random number is increased. As shown in the figure, the type of special symbol (small hit symbol) is determined.

On the other hand, if the result of the large winning combination lottery is "missing" and the lottery result is derived by the special 1 hold, the special symbol X is determined as the losing symbol without performing the lottery. In addition, when the result of the big role lottery is "missing" and the lottery result is derived by the special 2 hold, the special symbol Y is determined as the losing symbol without performing the lottery.

That is, the winning symbol random number determination table is referred only when the big winning lottery result is "big hit" or "small hit", and is not referred to when the big winning lottery result is "missing". Here, it is decided that the same jackpot symbol is determined in the special 1 per symbol random number determination table and the special 2 per symbol random number determination table. However, different jackpot symbols may be determined in both tables, or the type of special symbol (big hit symbol) may be determined by referring to the 1 hit symbol random number determination table regardless of the hold type. ..

Here, the selection ratio of the big hit symbol and the small hit symbol is common to all the set values, but either one or both of the big hit symbol and the small hit symbol may be different for each set value.

FIG. 10 is a diagram illustrating a reach group determination random number determination table. A plurality of reach group determination random number determination tables are provided, and a preset table is selected according to the hold type, the number of holds, the game state, the variation state associated with the game state, and the like. When the game ball enters the first starting port 120 or the second starting port 122, one reach group determination random number is acquired from the range of 0 to 10066. As described above, when the major winning combination lottery result is derived, a process of determining a variation effect pattern (variation mode number, variation pattern number) for notifying the major combination lottery result is performed. In the present embodiment, when the result of the large winning combination lottery is "missing", the group type is first determined by the reach group determination random number and the reach group determination random number determination table in determining the variation effect pattern. The variable state is a concept in which the table to be referred to to determine the variable effect pattern is defined, and is set separately from the game state.

For example, when the game state is set to the non-time saving game state, when the big role lottery result of "loss" is derived based on the special 1 hold, the number of holds for the special 1 hold when the big role lottery is performed ( Hereinafter, if the number (hereinafter simply referred to as “number of hold”) is 0, the reach group determination random number determination table 1 is selected as shown in FIG. 10 (a). Similarly, when the non-time saving game state is set and the result of the big role lottery of "loss" is derived based on the special 1 hold, the number of holds when performing the big role lottery is 1-2. For example, if the reach group determination random number determination table 2 is selected and the number of pending numbers is 3, as shown in FIG. 10 (b), the reach group determination random number determination table 3 is displayed as shown in FIG. 10 (c). Be selected. In FIG. 10, the group x described in the group type column indicates an arbitrary group number. Therefore, various group numbers are determined as the group type according to the acquired reach group determination random number and the type of the reach group determination random number determination table to be referred to.

In addition, although the reach group determination random number determination table referred to when the big role lottery result of "loss" is derived based on the special 1 hold in the non-time saving game state is described here, this is described in the main ROM 300b. In addition, many reach group determination random number determination tables are stored.

If the result of the big win lottery is "big hit" or "small hit", the group type is not decided when determining the variable effect pattern. That is, the reach group determination random number determination table is referred only when the big win lottery result is "missing", and is not referred to when the big win lottery result is "big hit" or "small hit".

FIG. 11 is a diagram illustrating a reach mode determination random number determination table. This reach mode determination random number determination table is selected when the big role lottery result is "miss", and the reach mode determination random number determination table at the time of loss, and the big hit selected when the big role lottery result is "big hit". It is roughly divided into a time reach mode determination random number determination table and a small hit hour reach mode determination random number determination table selected when the result of the big win lottery is "small hit". The reach mode determination random number determination table at the time of loss is provided for each group type determined as described above, and the reach mode determination random number determination table at the time of big hit and the reach mode determination random number determination table at the time of small hit are reserved types. It is provided for each.

In addition, each reach mode determination random number determination table is also provided for each game state and symbol type. Here, FIG. 11A shows an example of the reach mode determination random number determination table for group x referred to in a predetermined game state and symbol type, and an example of the reach mode determination random number determination table for special 1 jackpot. FIG. 11 (b) shows an example of the special 1 jackpot reach mode determination random number determination table, and FIG. 11 (c) shows an example of the special 1 small hit reach mode determination random number determination table. An example of the reach mode determination random number determination table for special 2 is shown in FIG. 11 (e).

When the game ball enters the first starting port 120 or the second starting port 122, one reach mode determination random number is acquired from the range of 0 to 250. Then, when the result of the above-mentioned major role lottery is "missing", as shown in FIG. 11A, a random number for determining the reach mode at the time of losing corresponding to the group type determined by the above-mentioned group type lottery. The determination table is selected, and the variable mode number is determined based on the selected reach mode determination random number determination table and the reach mode determination random number at the time of loss. Further, when the result of the above-mentioned big win lottery is "big hit", as shown in FIGS. 11B and 11C, the big hit reach mode determination random number determination table corresponding to the read hold type is obtained. Is selected, and the variable mode number is determined based on the selected jackpot reach mode determination random number determination table and the reach mode determination random number.

Further, when the result of the above-mentioned big win lottery is "small hit", as shown in FIGS. 11 (d) and 11 (e), the small hit time reach mode determination random number corresponding to the read hold type is obtained. The determination table is selected, and the variable mode number is determined based on the selected small hit reach mode determination random number determination table and the reach mode determination random number.

Further, in each reach mode determination random number determination table, the reach mode determination random number is associated with the variation pattern random number determination table described later together with the variation mode number, and at the same time when the variation mode number is determined, the variation pattern The random number judgment table is determined. In FIG. 11, the table x described in the column of the variation pattern random number determination table indicates an arbitrary table number. Therefore, the variation mode number and the table number of the variation pattern random number determination table are determined according to the acquired reach group determination random number and the type of the reach mode determination random number determination table to be referred to. Further, in the present embodiment, the variation mode number and the variation pattern number described later are set in hexadecimal numbers. In the following, "H" is added when indicating a hexadecimal number, but XXH in FIGS. 11 to 13 indicates an arbitrary value indicated by a hexadecimal number.

As described above, when the result of the large winning combination lottery is "missing", first, the group type is determined by the reach group determination random number determination table and the reach group determination random number shown in FIG. Then, the variation mode number and the variation pattern random number determination table are determined by the reach mode determination random number determination table and the reach mode determination random number at the time of loss shown in FIG. 11A according to the determined group type and game state.

On the other hand, if the result of the big win lottery is "big hit" or "small hit", the determined big hit symbol or small hit symbol (type of special symbol), big hit, or game state at the time of small hit winning, etc. The variation mode number and the variation pattern random number determination table are determined by referring to the corresponding jackpot reach mode determination random number determination table shown in FIG. 11 and using the reach mode determination random number.

FIG. 12 is a diagram illustrating a variation pattern random number determination table. Here, the variation pattern random number determination table x of a predetermined table number x is shown, but in addition to this, a large number of variation pattern random number determination tables are provided for each table number.

When the game ball enters the first starting port 120 or the second starting port 122, one variation pattern random number is acquired from the range of 0 to 238. Then, the variation pattern number is determined as shown in the figure based on the variation pattern random number determination table determined at the same time as the variation mode number and the acquired variation pattern random number.

When the big winning combination lottery is performed in this way, the variable mode number and the variable pattern number are determined according to the big winning combination lottery result, the determined symbol type, the game state, the number of holds, the hold type, and the like. These variation mode numbers and variation pattern numbers specify the variation effect pattern, and the mode and time of the variation effect are associated with each of them.

FIG. 13 is a diagram illustrating a fluctuation time determination table. When the variation mode number is determined as described above, the variation time 1 is determined according to the variation time 1 determination table shown in FIG. 13 (a). According to this variation time 1 determination table, the variation time 1 is associated with each variation mode number, and the corresponding variation time 1 is determined according to the determined variation mode number.

Further, when the fluctuation pattern number is determined as described above, the fluctuation time 2 is determined according to the fluctuation time 2 determination table shown in FIG. 13 (b). According to the fluctuation time 2 determination table, the fluctuation time 2 is associated with each fluctuation pattern number, and the corresponding fluctuation time 2 is determined according to the determined fluctuation pattern number. The total time of the variable times 1 and 2 determined in this way is the time of the variable effect for notifying the result of the big winning combination lottery, that is, the variable time.

When the variation mode number is determined as described above, the variation mode command corresponding to the determined variation mode number is transmitted to the sub-control board 330, and when the variation pattern number is determined, the determined variation The variation pattern command corresponding to the pattern number is transmitted to the sub-control board 330. In the sub-control board 330, the first half mode of the variation effect is mainly determined based on the received variation mode command, and the second half aspect of the variation effect is mainly determined based on the received variation pattern command. However, the details will be described later. In the following, the variation mode number and the variation pattern number may be collectively referred to as variation information, and the variation mode command and the variation pattern command may be collectively referred to as a variation command.

FIG. 14 is a diagram for explaining the first special electric accessory operating ram set table, and FIG. 15 is a diagram for explaining the second special electric accessory operating ram set table. The first special electric accessory operating ram set table and the second special electric accessory operating ram set table store various data for controlling the large role game or the small hit game, and are used during the large role game and the small hit. During the game, the first special winning opening solenoid 126c and the second special winning opening solenoid 128c are energized and controlled with reference to the first special electric accessory operating ram set table or the second special electric accessory operating ram set table. .. Hereinafter, the first special electric accessory operating ram set table and the second special electric accessory operating ram set table are collectively referred to simply as a special electric accessory operating ram set table. In reality, a plurality of special electric accessory operating ram set tables are provided for each type of special symbol (big hit symbol and small hit symbol), and the corresponding table plays a major role according to the determined special symbol type. It is set at the start of a game or a small hit game, but here, for convenience of explanation, control data of all special symbols is shown in one table.

When the special symbols A, B, and C, which are the jackpot symbols, are determined, as shown in FIG. 14, the first special winning opening 126 is opened and closed in a predetermined opening / closing pattern with reference to the first special electric accessory operating ram set table. The opening / closing process that controls opening / closing is executed. Further, when the special symbols a, b, and c, which are the small hit symbols, are determined, as shown in FIG. 15, the first special winning opening 126 and the first large winning opening 126 and the second special electric accessory operating ram set table are referred to. An opening / closing process for controlling the opening / closing of the two major winning openings 128 in a predetermined opening / closing pattern is executed. The big role game is composed of a plurality of round games in which the first big winning opening 126 is opened and closed a predetermined number of times, and the small hit game is a round game in which the second big winning opening 128 is opened and closed a predetermined number of times only once. To.

According to the special electric bonus actuating ram set table, the opening time (waiting time until the first round game is started), the maximum number of special electric bonus actuations (executed during one big role game or small hit game) Number of round games to be played), open large winning opening (1st large winning opening 126 and 2nd large winning opening 128 opened in each round game), number of special electric accessory opening / closing switching (1st in 1 round game) The number of times the large winning opening 126 and the second large winning opening 128 are opened), the solenoid energizing time (the first large winning opening solenoid 126c and the second large winning opening for each number of times the first large winning opening 126 and the second large winning opening 128 are opened) The energizing time of the mouth solenoid 128c, that is, the opening time of one first large winning opening 126 and the second large winning opening 128), the specified number (the first large winning opening 126 and the second large winning opening in one round game) Maximum number of winning openings 128), effective closing time of large winning openings 126 (closing time of first major winning openings 126 and second major winning openings 128 between round games, that is, interval time between rounds), ending time (last) The waiting time from the end of the round game to the resumption of the normal special game) is stored in advance as control data for the big role game for each type of jackpot symbol as shown in the figure.

In the present embodiment, when the special symbol A, which is the jackpot symbol, is determined, a big role game composed of four round games is executed, and when the special symbols B and C are determined, 15 rounds are executed. A major game consisting of games is executed. In each round game, a predetermined time (29.0 seconds) has elapsed since the specified number (7) of game balls entered the first large winning opening 126 or the first large winning opening 126 was opened. Then it ends.

Further, as shown in FIG. 15, when the special symbols a, b, and c which are the small hit symbols are determined, the small hit game composed of one round game is first executed. In this small hit game, the opening and closing of the second big winning opening 128 is repeatedly executed. In the small hit game in which the special symbol a is determined and executed, the second big winning opening 128 is opened only for 0.1 seconds × 1 time. Further, in the small hit game in which the special symbols b and c are determined and executed, the second big winning opening 128 is opened for 0.1 seconds (open 1), closed for 3.0 seconds (closed 1), and 0. 1 second open (open 2), 1.0 second close (close 2), 0.1 second open (open 3), 1.0 second close (close 3), 0.1 second open (open 3) Opening and closing is controlled in the order of 4).

Here, a specific area 140b and a non-specific area 140c are provided inside the second large winning opening 128, and the game ball that has entered the second large winning opening 128 is always in the specific area 140b or the non-specific area 140b. Enter region 140c. Then, in the small hit game, when the game ball that has entered the second big winning opening 128 enters the specific area 140b, the big role game in which the first big winning opening 126 is opened follows the small hit game. Will be executed.

At this time, if the special symbols a and b, which are the small hit symbols, are determined, the round game in which the first large winning opening 126 is opened 29.0 seconds × 1 time is executed four times. Further, if the special symbol c, which is a small hit symbol, is determined, the round game is executed 15 times in the large role game.

FIG. 16 is a diagram illustrating an opening / closing mode of the second special winning opening 128 and an opening / closing mode of the specific region 140b by the movable member 142. As shown in FIG. 16, in the small hit game in which the second special winning opening 128 is opened, the movable member 142 momentarily (about 0.1 seconds) the specific area 140b at the same time as opening the second large winning opening 128. After opening, the specific region 140b is maintained in the closed state for a predetermined time, and then the specific region 140b is maintained in the open state again. Then, as shown in FIG. 16A, when the special symbol a is determined and the small hit game is executed, the second big winning opening is only 0.1 seconds from the start of the small hit game (round game). 128 is released. During this time, it takes a predetermined time for the game ball that has entered the second special winning opening 128 to reach the specific area 140b. Therefore, when the game ball that has entered the second special winning opening 128 reaches the specific area 140b, the specific area 140b is always closed, and as a result, the special symbol a is determined and the small hit game is executed. In that case, the game ball does not enter the specific area 140b.

In addition, an unexpected situation such as the game ball biting into the second prize opening 128, or the game ball staying in the second prize opening 128 for a long time for some reason. When the above occurs, the game ball may enter the specific area 140b even in the small hit game in which the special symbol a is determined and executed. Therefore, in this specification, in order to facilitate understanding, the words "must" and "certainly" are used, but this is because the state of the game machine 100 advances the game. It is premised that it is in an appropriate state and that no unexpected situation has occurred, and does not mean 100% physical.

On the other hand, as shown in FIG. 16B, when the special symbols b and c are determined and the small hit game is executed, the second big winning opening 128 is a total of four times in the small hit game. Be released. Therefore, the game ball that has entered the second prize opening 128 at the same time as the first opening of the second prize opening 128 may not be able to enter the specific area 140b, but the second prize opening 128 In the second and subsequent openings of the above, the game ball that has entered the second large winning opening 128 can surely enter the specific area 140b. Although detailed description is omitted, a structure for decelerating the game ball rolling on the second special winning opening 128 is provided above the second large winning opening 128, which is appropriate from the start of the small hit game. When the game ball is launched into the second game area 116b, the game ball always enters the specific area 140b.

FIG. 17 is a diagram illustrating a game state setting table for setting a game state after the end of a major role game. In the present embodiment, when the big role game is executed, the game state after the end of the big role game is set according to the type of the determined special symbol. According to this game state setting table, even if any of the special symbols A, B, C, a, b, and c is determined, the time-saving game state is set after the end of the major role game.

When the gaming state is set to the time-saving gaming state, the number of times the time-saving gaming state is continued (hereinafter, referred to as "time-saving number of times") is set. Here, when the special symbols A and a are determined, the number of time reductions is set to 1, and when the special symbols B, C, b and c are determined, the number of time reductions is set to 7 times. To. This means that the time-saving game state continues until the result of the big win lottery is confirmed once or seven times. However, the above-mentioned number of time reductions indicates the maximum number of continuations in the time-saving game state of 1, and if a big hit is won before reaching the above-mentioned number of continuations, the game state and the number of times of time reduction are set again. Will be done. Therefore, when the time-saving game state is set after the end of the big role game, the lottery result of the big hit is not derived in the time-saving game state, and the lottery result of the loss or the small hit is derived once or seven times. , The gaming state will be changed to the non-time saving gaming state.

Here, in the time-saving game state, the remaining number of time-saving times is subtracted each time the large winning combination lottery result is determined, and when the remaining number of time-saving times becomes 0, the game state is changed to the non-time-saving gaming state. At this time, the number of time reductions is subtracted only when the result of the large winning combination lottery based on the special 2 hold is confirmed. That is, after the big role game, when the big role lottery result based on the special 2 hold is confirmed once or seven times, the remaining number of time reductions becomes 0, and the game state is changed to the non-time reduction game state.

In this case, when the time saving game state is set, the number of time saving times is set differently according to the type of the special symbol, but the number of time saving times is set to the same number regardless of the type of the special symbol. You may. Further, here, the number of time reductions is subtracted only when the result of the large role lottery based on the special 2 hold is confirmed, but the number of time reductions is also subtracted when the result of the large role lottery based on the special 1 hold is confirmed. May be.

FIG. 18 is a diagram illustrating a hit determination random number determination table. When a game ball flowing down the game area 116 passes through the gate 124, a determination process of a normal symbol associated with whether or not to control energization of the movable piece 122b of the second starting port 122 (hereinafter referred to as "general drawing lottery"). ) Is performed.

As will be described in detail later, when the game ball passes through the gate 124, one hit determination random number is acquired from the range of 0 to 99, and four of these random numbers are stored in the normal figure reservation storage area of the main RAM 300c. Is stored as the upper limit. That is, the normal figure reservation storage area includes four storage units for saving the winning determination random number. Therefore, when the game ball passes through the gate 124 in a state where the hit decision random number is stored in all four storage units of the normal figure reservation storage area, the hit decision random number is stored based on the passage of the game ball. There is no such thing. In the following, the hit determination random number that the game ball passes through the gate 124 and is stored in the normal figure hold storage area is referred to as a normal figure hold.

When starting the normal drawing lottery in the non-time saving game state, as shown in FIG. 18A, the hit determination random number determination table for the non-time saving game state is referred to. According to this non-time saving game state hit determination random number determination table, when the hit determination random number is 0, the hit symbol is determined as the type of the normal symbol, and when the hit determination random number is 1 to 99, A lost symbol is determined as the type of normal symbol. Therefore, the probability that the winning symbol is determined in the non-time saving game state, that is, the winning probability is 1/100. As will be described in detail later, when the winning symbol is determined in this general drawing lottery, the second starting port 122 is controlled to the open state, and when the lost symbol is determined, the second starting port 122 is closed. Be maintained.

Further, when the normal drawing lottery is started in the time-saving game state, as shown in FIG. 18B, the hit determination random number determination table for the time-saving game state is referred to. According to the hit determination random number determination table for the time-saving game state, when the hit determination random number is 0 to 98, the hit symbol is determined as the type of the normal symbol, and when the hit determination random number is 99, it is normal. A lost symbol is determined as the type of symbol. Therefore, the probability that the winning symbol is determined in the time-saving game state, that is, the winning probability is 99/100.

FIG. 19 (a) is a diagram for explaining a normal symbol fluctuation time data table, and FIG. 19 (b) is a diagram for explaining an open / close control pattern table. As described above, when the general drawing lottery is performed, the fluctuation time of the normal symbol is determined. The normal symbol fluctuation time data table is referred to when determining the fluctuation time of the normal symbol when the winning symbol or the lost symbol is determined by the ordinary symbol lottery. According to this normal symbol variation time data table, the variation time is determined to be 10 seconds when the gaming state is set to the non-time saving gaming state, and varies when the gaming state is set to the time saving gaming state. The time is determined to be 1 second. When the fluctuation time is determined in this way, the normal symbol display 168 is displayed in a variable manner (blinking display) over the determined time. Then, when the winning symbol is determined, the normal symbol display 168 is turned on, and when the lost symbol is determined, the normal symbol display 168 is turned off.

Then, when the winning symbol is determined by the ordinary symbol lottery and the normal symbol display 168 is turned on, the movable piece 122b of the second starting port 122 has an open / close control pattern as shown in FIG. 19 (b). Energization is controlled by referring to the table. Actually, the open / close control pattern table is provided for each game state, and the corresponding table is set at the start of energization of the normal electric accessory solenoid 122c according to the game state when the normal symbol is determined. However, here, for convenience of explanation, control data corresponding to each gaming state is shown in one table.

When the winning symbol is determined, as shown in FIG. 19B, the opening / closing control of the second starting port 122 is controlled with reference to the opening / closing control pattern table. According to this opening / closing control pattern table, the time before opening the normal electric power (waiting time until the opening of the second starting port 122 is started), the maximum number of times of switching the opening / closing of the ordinary electric accessory (the number of times of opening the second starting port 122) , The solenoid energizing time (the energizing time of the ordinary electric accessory solenoid 122c for each opening of the second starting port 122, that is, the opening time of the second starting port 122 once), the specified number (the total of the second starting port 122). The maximum number of prizes that can be awarded to the second start port 122 during opening), the normal power closing effective time (the closing time between each opening of the second starting port 122, that is, the pause time), and the normal power effective state time (second start). The second start port is the waiting time from the end of the last opening of the mouth 122) and the waiting time for ending the normal power (waiting time after the lapse of the normal power effective state time until the variable display of the normal symbol described later is resumed). The control data of 122 is stored in advance for each gaming state as shown in the figure.

As described above, the opening / closing control conditions for opening / closing the second start port 122 are associated with the non-time-saving game state and the time-saving game state as the game progress conditions, respectively, and the non-time-saving game state is associated with the non-time-saving game state. It becomes easier for the game ball to enter the second starting port 122 than in the game state. That is, in the time-saving game state, as long as the game ball passes through the gate 124, the regular drawing lottery is performed one after another, and the second starting port 122 is frequently opened, so that the player consumes the game ball. It is possible to perform a big role lottery while reducing the number of players.

The opening / closing condition of the second starting port 122 defines three elements: the winning probability of the normal symbol, the time for displaying the fluctuation of the normal symbol, and the opening time of the second starting port 122. Then, in the present embodiment, in two of these elements, the time-saving game state is set more favorably than the non-time-saving game state, so that the time-saving game state is the second start rather than the non-time-saving game state. It is set so that the game ball can easily enter the mouth 122. However, with respect to one or three of the above three elements, the time-saving gaming state may be set more advantageously than the non-time-saving gaming state. In any case, the time-saving game state is more advantageous than the non-time-saving game state for at least one element, so that the time-saving game state is generally more advantageous than the non-time-saving game state. The game ball may easily enter the 122. That is, when the gaming state is set to the non-time saving gaming state, the movable piece 122b is controlled to open and close according to the first condition, and when the gaming state is set to the time saving gaming state, from the first condition. The movable piece 122b may be controlled to open and close according to the second condition in which the movable piece 122b is likely to be opened.

Next, the main processing of the main control board 300 with the progress of the game in the game machine 100 will be described.

FIG. 20 is a diagram illustrating a game machine state flag. In the main control board 300, whether or not the game can proceed is managed by the game machine state flag. One of seven types of flag values from 00H to 06H is set in the game machine status flag. The flag value = 00H of the game machine state flag indicates a game-enabled state, and when the game machine state flag is 00H, the game progress is controlled, and when the game machine state flag is other than 00H, the game is played. It will be stopped.

The flag value = 01H of the game machine status flag indicates the setting change state, and when the game machine status flag is 01H, the registration setting value can be changed. The flag value of the game machine status flag = 02H indicates the setting confirmation status, and when the game machine status flag is 02H, the registration setting value is displayed on the performance display monitor 184, and the registration setting value is set. It becomes possible to confirm. The flag value = 03H of the game machine state flag indicates a setting abnormal state, and when the game machine state flag is 03H, the game is stopped because the registered setting value is abnormal. The flag value = 04H of the game machine state flag indicates the RAM abnormal state, and when the game machine state flag is 04H, the game is stopped. The flag value = 05H of the game machine state flag indicates a checksum abnormal state, and when the game machine state flag is 05H, the game is stopped. The flag value = 06H of the game machine state flag indicates the fraud detection state, and when the game machine state flag is 06H, the game is stopped. When the power is turned on, the game machine status flag is set to one of the flag values, and processing is performed according to the game machine status flag.

(CPU initialization process of main control board 300)
FIG. 21 is a first flowchart for explaining the CPU initialization process on the main control board 300, and FIG. 22 is a second flowchart for explaining the CPU initialization process on the main control board 300.

When power is supplied from the power supply board, a system reset occurs in the main CPU 300a, and the main CPU 300a performs the following CPU initialization process (S100).

(Step S100-1)
The main CPU 300a reads the startup program from the main ROM 300b as the initial setting process in response to the power-on, and also performs the setting process necessary for executing various processes.

(Step S100-3)
The main CPU 300a sets the wait processing time in the timer counter.

(Step S100-5)
The main CPU 300a determines whether or not the power supply cutoff warning signal is detected. The main control board 300 is provided with a power supply cutoff detection circuit, and when the power supply voltage becomes equal to or lower than a predetermined value, a power supply cutoff warning signal is output from the power supply cutoff detection circuit. If the power off warning signal is detected, the process is transferred to step S100-3, and if the power off warning signal is not detected, the process is transferred to step S100-7.

(Step S100-7)
The main CPU 300a determines whether or not the wait time set in step S100-3 has elapsed. As a result, if it is determined that the wait time has elapsed, the process is transferred to step S100-9, and if it is determined that the wait time has not elapsed, the process is transferred to step S100-5.

(Step S100-9)
The main CPU 300a executes a process necessary for permitting access to the main RAM 300c.

(Step S100-11)
The main CPU 300a loads the flag value of the game machine state flag before the power is turned off into the D register.

(Step S100-13)
The main CPU 300a calculates the checksum and determines whether the calculated checksum matches the checksum saved when the power is turned off (normal) and whether the backup flag is normal. As a result, if it is determined that the backup flag and the checksum are normal, the process is transferred to step S100-15, and if it is determined that either or both are not normal, the process is transferred to step S100-25. ..

(Step S100-15)
The main CPU 300a sets the address that does not include the set value and the game machine status flag at the start address of the main RAM 300c to be cleared.

(Step S100-17)
The main CPU 300a determines whether the RAM clear operation signal is input from the RAM clear switch 182s (whether the RAM clear button is pressed). As a result, if it is determined that the RAM clear operation signal has been input, the process is transferred to step S100-31, and if it is determined that the RAM clear operation signal has not been input, the process is transferred to step S100-19. ..

(Step S100-19)
The main CPU 300a determines whether the flag value of the game machine status flag loaded in step S100-11 is 00H (gamable state), the setting change switch 180s is on, and the middle frame 104 is open. judge. As a result, if it is determined that all three conditions are satisfied, the process is transferred to step S100-21, and if it is determined that even one of the three conditions is not satisfied, the process is transferred to step S100-23.

(Step S100-21)
The main CPU 300a sets 02H (setting confirmation state) in the game machine state flag. That is, when the middle frame 104 is open, the setting change switch 180s is turned on, and the power is normally turned on while the RAM clear button is not pressed, the setting confirmation state is set.

(Step S100-23)
The main CPU 300a executes an initialization process for clearing a clear target at the time of power recovery, which is an area after the start address set in step S100-15 of the main RAM 300c, and shifts the process to step S100-49.

(Step S100-25)
The main CPU 300a sets 05H (checksum abnormal state) in the D register.

(Step S100-27)
The main CPU 300a performs an out-of-area read / write check process for checking and clearing the read / write memory in the out-of-use area.

(Step S100-29)
The main CPU 300a sets an address including a set value and a game machine status flag at the start address of the main RAM 300c to be cleared.

(Step S100-31)
The main CPU 300a checks and clears the read / write memory of the used area.

(Step S100-33)
The main CPU 300a determines whether the check result of the read / write memory in the step S100-31 is normal. As a result, if it is determined that it is normal, the process is transferred to step S100-37, and if it is determined that it is not normal, the process is transferred to step S100-35.

(Step S100-35)
The main CPU 300a sets 04H (RAM abnormal state) in the D register, and shifts the processing to steps S100-45.

(Step S100-37)
The main CPU 300a determines whether 02H (setting confirmation state) is set in the D register. As a result, if it is determined that 02H is set, the process is transferred to step S100-39, and if it is determined that 02H is not set, the process is transferred to step S100-41.

(Step S100-39)
The main CPU 300a sets 00H (playable state) in the D register.

(Step S100-41)
The main CPU 300a determines whether or not the setting change condition is satisfied. As a result, if it is determined that the setting change condition is satisfied, the process is transferred to step S100-43, and if it is determined that the setting change condition is not satisfied, the process is transferred to step S100-45. Here, at least, the setting change condition is that the setting change switch 180s is on, the middle frame 104 is open, and the RAM clear operation signal is input from the RAM clear switch 182s. included.

(Step S100-43)
The main CPU 300a sets 01H (setting change state) in the D register.

(Step S100-45)
The main CPU 300a saves the value set in the D register in the game machine status flag.

(Step S100-47)
The main CPU 300a executes an initialization process for clearing the clear target at the time of clearing the RAM in the main RAM 300c, and shifts the process to steps S100-49.

(Step S100-49)
The main CPU 300a performs a transmission process (stores the RAM clear designation command in the transmission buffer) of a payout command (RAM clear designation command) for transmitting to the payout control board 310 that the main RAM 300c has been cleared.

(Step S100-51)
The main CPU 300a loads the game machine status flag.

(Step S100-53)
The main CPU 300a determines whether the gaming machine status flag loaded in step S100-51 is 00H (gamable state). As a result, if it is determined that it is 00H, the process is transferred to step S110, and if it is determined that it is not 00H, the process is transferred to steps S100-55.

(Step S110)
The main CPU 300a performs subcommand group set processing. The subcommand group set processing will be described later.

(Step S100-55)
The main CPU 300a performs a subcommand set process for transmitting a predetermined command to the subcontrol board 330.

(Step S100-57)
The main CPU 300a sets the timer interrupt cycle.

(Step S100-59)
The main CPU 300a performs a process for disabling interrupts.

(Step S100-61)
The main CPU 300a updates the initial value update random number for the winning symbol random number. The initial value update random number for the winning symbol random number is for determining the initial value and the ending value of the winning symbol random number. That is, when the hit symbol random number goes around from the initial value update random number for the hit symbol random number to the initial value update random number -1 for the hit symbol random number by the update process of the hit symbol random number described later, the hit symbol random number is obtained at that time. The initial value update random number for the winning symbol random number will be updated.

(Step S100-63)
The main CPU 300a analyzes the received data (main command) received from the payout control board 310 and executes various processes according to the received data.

(Step S100-65)
The main CPU 300a performs a process for transmitting the subcommand stored in the transmission buffer to the sub-control board 330.

(Step S100-67)
The main CPU 300a performs a process for permitting an interrupt.

(Step S100-69)
The main CPU 300a updates the reach group determination random number, the reach mode determination random number, and the variation pattern random number, and thereafter repeats the process from step S100-59. In the following, the reach group determination random number, the reach mode determination random number, and the variation pattern random number for determining the variation effect pattern are collectively referred to as a variation effect random number.

FIG. 23 is a flowchart illustrating the subcommand group set process (S110) on the main control board 300.

(Step S110-1)
The main CPU 300a loads the flag value of the game machine status flag.

(Step S110-3)
The main CPU 300a performs a subcommand set process for transmitting a predetermined command to the subcontrol board 330.

(Step S110-5)
The main CPU 300a performs a model command setting process for setting a model command indicating the model information of the game machine 100 in the transmission buffer.

(Step S110-7)
The main CPU 300a performs a setting value specification command setting process for setting a setting value specification command indicating a registration setting value in the transmission buffer.

(Step S110-9)
The main CPU 300a performs a special figure 1 hold designation command setting process for setting a special figure 1 hold designation command indicating the number of special 1 hold in the transmission buffer.

(Step S110-11)
The main CPU 300a performs a special figure 2 hold designation command setting process for setting a special figure 2 hold designation command indicating the number of special 2 hold designations in the transmission buffer.

(Step S110-13)
The main CPU 300a performs a number-of-times command setting process for setting a number-of-times command indicating the remaining number of times in the time-saving game state in the transmission buffer.

(Step S110-15)
The main CPU 300a performs a variation pattern selection state specification command setting process for setting a variation pattern selection state specification command indicating the variation pattern selection state in the transmission buffer.

(Step S110-17)
The main CPU 300a performs a special figure phase designation command setting process for setting a special figure phase designation command indicating the special game management phase in the transmission buffer. The special game management phase will be described later.

(Step S110-19)
The main CPU 300a determines whether the special game management phase is in the special symbol change waiting state. As a result, if it is determined that the state is in the special symbol change waiting state, the process is shifted to step S110-21, and if it is determined that the state is not in the special symbol change waiting state, the subcommand group set process is terminated.

(Step S110-21)
The main CPU 300a sets the customer waiting designation command in the transmission buffer, and ends the subcommand group set processing.

Next, interrupt processing on the main control board 300 will be described. Here, save processing (XINT interrupt processing) and timer interrupt processing when the power is turned off will be described.

(Evacuation processing when the power of the main control board 300 is turned off (XINT interrupt processing))
FIG. 24 is a flowchart illustrating an evacuation process (XINT interrupt process) when the power is turned off in the main control board 300. The main CPU 300a monitors the power supply cutoff detection circuit, and when the power supply voltage becomes equal to or less than a predetermined value, it interrupts the CPU initialization process and executes the power failure saver process.

(Step S300-1)
When the power cutoff warning signal is input, the main CPU 300a saves the register.

(Step S300-3)
The main CPU 300a checks the power off warning signal.

(Step S300-5)
The main CPU 300a determines whether or not the power supply cutoff warning signal is detected. As a result, if it is determined that the power off warning signal has been detected, the process is transferred to step S300-11, and if it is determined that the power off warning signal has not been detected, the process is transferred to step S300-7. ..

(Step S300-7)
The main CPU 300a restores the register.

(Step S300-9)
The main CPU 300a performs a process for permitting an interrupt, and ends the save process when the power is turned off.

(Step S300-11)
The main CPU 300a executes an output port clearing process for stopping the output of the output port.

(Step S300-13)
The main CPU 300a executes a checksum setting process for calculating and saving the checksum.

(Step S300-15)
The main CPU 300a executes the RAM protection setting process necessary for prohibiting access to the main RAM 300c.

(Step S300-17)
The main CPU 300a sets a predetermined number of times of power failure detection signal detection to the counter value of the loop counter in order to set the power failure occurrence monitoring time.

(Step S300-19)
The main CPU 300a checks the power off warning signal.

(Step S300-21)
The main CPU 300a determines whether or not the power supply cutoff warning signal is detected. As a result, if it is determined that the power off warning signal has been detected, the process is transferred to step S300-17, and if it is determined that the power off warning signal has not been detected, the process is transferred to step S300-23. ..

(Step S300-23)
The main CPU 300a subtracts 1 from the value of the loop counter set in step S300-17.

(Step S300-25)
The main CPU 300a determines whether the counter value of the loop counter is not 0. As a result, if it is determined that the counter value is not 0, the process proceeds to step S300-19, and if it is determined that the counter value is 0, the process proceeds to the CPU initialization process (step S100) described above.

When the power is actually cut off, the operation of the game machine 100 is stopped while looping steps S300-17 to S300-25.

(Timer interrupt processing of main control board 300)
FIG. 25 is a flowchart illustrating timer interrupt processing on the main control board 300. The main control board 300 is provided with a reset clock pulse generation circuit that generates a clock pulse at a predetermined cycle (4 milliseconds in the present embodiment, hereinafter referred to as “4 ms”). Then, when a clock pulse is generated by the reset clock pulse generation circuit, the CPU initialization process (step S100) is interrupted and the following timer interrupt process is executed.

(Step S400-1)
The main CPU 300a saves the register.

(Step S400-3)
The main CPU 300a performs a process for permitting an interrupt.

(Step S400-5)
The main CPU 300a outputs the common data set in the common output buffer to the output port, and outputs the first special symbol display 160, the second special symbol display 162, the first special symbol hold display 164, and the second special symbol display. A dynamic port output process for lighting control of the display 166, the normal symbol display 168, the normal symbol hold display 170, the right-handed notification display 172, and the performance display monitor 184 is executed.

(Step S400-7)
The main CPU 300a reads various input port information and executes a port input process for accurately acquiring the latest switch state.

(Step S400-9)
Similar to step S100-61, the main CPU 300a executes the update process of the initial value update random number for the winning symbol random number.

(Step S400-11)
The main CPU 300a performs a process of updating the winning symbol random number. Specifically, the random number counter is added and updated by 1, and when the added result exceeds the maximum value of the random number range, the random number counter is returned to 0, and when the random number counter makes one round, at that time. Update the initial value for the winning symbol random number Update the random number from the value of the random number.

Although detailed description is omitted, in the present embodiment, the jackpot determination random number and the hit determination random number use the hardware random number updated by the hardware random number generator built in the main control board 300. The hardware random number generator updates both the jackpot random number and the hit decision random number according to a certain rule, automatically changes the random number sequence every time the random number sequence goes around, and sets the start value every time the system is reset. I'm changing.

(Step S400-13)
The main CPU 300a loads the flag value of the game machine status flag.

(Step S400-15)
The main CPU 300a determines whether the flag value loaded in step S400-13 is 00H (gamable state). As a result, if it is determined that it is 00H, the process is transferred to step S400-19, and if it is determined that it is not 00H, the process is transferred to step S400-17.

(Step S400-17)
The main CPU 300a determines whether the flag value loaded in step S400-13 is 03H (setting abnormal state) or more. As a result, if it is determined that it is 03H or more, the process is transferred to step S400-27, and if it is determined that it is not 03H or more, the process is transferred to step S450.

(Step S450)
The main CPU 300a executes the setting-related processing and shifts the processing to steps S400-27. The setting-related processing will be described later.

(Step S400-19)
The main CPU 300a performs a timer update process for updating various timer counters. Here, the various timer counters are subtracted each time the timer interrupt process of the main control board 300 is performed, and the subtraction is stopped when it reaches 0, unless otherwise specified.

(Step S500)
The main CPU 300a includes a first start port detection switch 120s, a second start port detection switch 122s, a gate detection switch 124s, a first special winning opening detection switch 126s, a second big winning opening detection switch 128s, a specific area detection switch 140s, and an out. A switch management process for determining whether or not a signal has been input from the ball detection switch 130s is executed. The details of this switch management process will be described later.

(Step S600)
The main CPU 300a executes a special game management process for controlling the progress of the special game. Further, when driving the first prize opening solenoid 126c or the second prize opening solenoid 128c, a solenoid output image for driving the first prize opening solenoid 126c or the second prize opening solenoid 128c is created. .. The details of this special game management process will be described later.

(Step S700)
The main CPU 300a executes a normal game management process for controlling the progress of the normal game. Further, when driving the ordinary electric accessory solenoid 122c, a solenoid output image for driving the ordinary electric accessory solenoid 122c is created. The details of this normal game management process will be described later.

(Step S400-21)
When the main CPU 300a drives the movable member drive solenoid 142c, the main CPU 300a creates a solenoid output image for driving the movable member drive solenoid 142c. The movable member drive solenoid 142c opens and closes the movable member 142 when the above-mentioned small hit game is executed.

That is, when the flag value of the game machine state flag is not 00H (gamable state), the normal electric accessory solenoid 122c, the first special winning opening solenoid 126c, the second major winning opening solenoid 128c, and the movable member drive. The solenoid output image of the solenoid 142c is not created.

(Step S400-23)
The main CPU 300a checks the general winning opening detection switch 118s, the first starting opening detection switch 120s, the second starting opening detection switch 122s, the first major winning opening detection switch 126s, and the second major winning opening detection switch 128s. The winning opening switch process for adding the counter for controlling the winning ball to be performed is executed.

(Step S400-25)
The main CPU 300a executes a payout control management process for creating and transmitting a payout command based on the counter value of the prize ball control counter set in step S400-23.

(Step S400-27)
The main CPU 300a creates a solenoid output image for driving the constantly movable body motor 144c that operates the constantly movable body 144. That is, the solenoid output image for driving the constantly movable body motor 144c is created regardless of the flag value of the game machine state flag. Therefore, the constantly movable body 144 can be used while the power of the game machine is turned on. It will operate at all times. As a result, it is possible to suppress a so-called goto act (illegal act) in which an error is intentionally generated and some kind of fraud is always performed on the movable body 144. For example, while the constantly movable body 144 is stopped, it is possible to prevent the constantly moving body 144 from being worked on, or the constantly moving body to stop at an advantageous position so that the remaining ball becomes advantageous. be able to.

(Step S460)
Based on the input port information acquired in step S400-7, the main CPU 300a executes a state management process for determining various errors and making settings according to the determination results. The details of this state management process will be described later.

(Step S400-29)
The main CPU 300a executes an external information management process for setting output data for external information to be output from the game information output terminal plate 312 to the outside.

(Step S470)
The main CPU 300a executes a game machine state flag setting process for stopping the game based on the occurrence of various errors. The details of this game machine state flag setting process will be described later.

(Step S400-31)
The main CPU 300a includes a first special symbol display 160, a second special symbol display 162, a first special symbol hold indicator 164, a second special symbol hold indicator 166, a normal symbol display 168, and a normal symbol hold indicator 170. , The LED display setting process for setting display data for lighting control of various indicators (LEDs) such as the right-handed notification indicator 172 in the output buffer corresponding to each common is executed.

(Step S400-33)
The main CPU 300a synthesizes the solenoid output images of the ordinary electric accessory solenoid 122c, the first prize-winning port solenoid 126c, the second prize-winning port solenoid 128c, the movable member drive solenoid 142c, and the constantly movable motor 144c, and outputs the output port. Executes solenoid output image composition processing for storage in the buffer. As described above, when the flag value of the game machine state flag is not 00H (playable state), the normal electric accessory solenoid 122c, the first special winning opening solenoid 126c, the second major winning opening solenoid 128c, Also, the solenoid output image of the movable member drive solenoid 142c is not created. Therefore, when the flag value of the game machine state flag is not 00H (gamable state), only the solenoid output image of the constantly movable motor 144c is stored in the output port buffer in the step S400-33. ..

(Step S400-35)
The main CPU 300a executes a port output process for outputting the value of the common output buffer stored in each output port buffer to the output port.

(Step S400-37)
The main CPU 300a performs a process for disabling interrupts.

(Step S400-39)
The main CPU 300a performs a process for calculating the base ratio to be displayed on the performance display monitor 184 using the unused area of the main RAM 300c, and commons common data for displaying the calculated base ratio on the performance display monitor 184. Executes the performance display monitor control process to be set in the output buffer. In the performance display monitor control process, the base ratio is calculated for each predetermined period. Here, the performance display monitor 184 may switch and display the base ratio of the current period and the base ratio of the period before that at predetermined time intervals. Further, the base ratio displayed on the performance display monitor 184 may be switched according to a predetermined operation.

(Step S400-41)
The main CPU 300a returns the register and ends the timer interrupt process.

FIG. 26 is a flowchart illustrating the above setting-related process (S450).

(Step S450-1)
The main CPU 300a determines whether the flag value of the game machine state flag is 01H (setting change state). As a result, if it is determined that it is 01H, the process is transferred to step S450-3, and if it is determined that it is not 01H, the process is transferred to step S450-15.

(Step S450-3)
The main CPU 300a loads the registered set value stored in the set value buffer into a predetermined processing area.

(Step S450-5)
The main CPU 300a determines whether the RAM clear switch 182s is pressed (whether the RAM clear operation signal is input). As a result, if it is determined that the RAM clear switch 182s is pressed, the process is transferred to step S450-7, and if it is determined that the RAM clear switch 182s is not pressed, the process is transferred to step S450-9. ..

(Step S450-7)
The main CPU 300a adds 1 to the set value of the processing area.

(Step S450-9)
The main CPU 300a determines whether the set value of the processing area is in the range of 1 to 6. As a result, if it is determined that the set value is in the range of 1 to 6, the process is transferred to step S450-13, and if it is determined that the set value is not in the range of 1 to 6, the process is performed in step S450-11. To move.

(Step S450-11)
The main CPU 300a sets the set value of the processing area to 1.

(Step S450-13)
The main CPU 300a sets the set value of the processing area in the set value buffer.

(Step S450-15)
The main CPU 300a determines whether the setting change switch 180s is on. As a result, when it is determined that the setting change switch 180s is on, the setting-related process is terminated, and when it is determined that the setting change switch 180s is not on, the process is moved to step S450-17.

(Step S450-17)
The main CPU 300a sets a setting-related end specification command indicating the end of the setting-related processing in the transmission buffer.

(Step S110)
The main CPU 300a executes the subcommand group set process shown in FIG. 23. That is, when the setting-related processing is executed, at the end of the execution, the model command, the setting value specification command, the special figure 1 hold designation command, the special figure 2 hold designation command, the number of times command, the variation pattern selection state specification command, and the special figure phase The designated command and the customer waiting designated command will be transmitted to the sub-control board 330.

(Step S450-19)
The main CPU 300a sets the gaming machine status flag to 00H (game-enabled state), and ends the setting-related processing.

As described above, according to the present embodiment, when the middle frame 104 is opened, the setting change switch 180s is turned on, and the RAM clear button is pressed and the power is turned on normally, the CPU is initialized. In the process (FIG. 21), 01H (setting change state) is set in the game machine state flag. After that, the timer interrupt process is executed, but since 01H (setting change state) is set in the game machine status flag, all the processes related to the progress of the game (steps S400-19 to S400-25 in FIG. 25). ) Is stopped and the setting related processing is executed.

The setting-related processing is repeatedly executed while the setting change switch 180s is on, and during this setting-related processing, the operation of pressing the RAM clear button is accepted as the setting change operation of the registered setting value. That is, during the setting change process (S450-1 to S450-13) for accepting the setting change operation, the registered setting value stored in the setting value buffer is one of the setting values provided in a plurality of stages according to the setting change operation. Can be switched to.

Then, when 01H (setting change state) is set in the game machine status flag and the setting change switch 180s is switched off, the setting change process is completed and 00H (game available state) is set in the game machine status flag. Set. As a result, the process related to the progress of the game can be executed from the next timer interrupt process.

Here, in the setting-related processing of the present embodiment, after the RAM clear button pressing operation, that is, the acceptance of the registration setting value setting change operation is completed, the setting value designation command corresponding to the registration setting value is performed in the subcommand group set processing. Is transmitted to the sub-control board 330. On the other hand, the setting value designation command is not transmitted to the sub-control board 330 while the setting change operation is being accepted. In this way, while the setting change operation is being accepted, the setting value specification command is transmitted when the acceptance of the setting change operation is completed and the game progresses to a state in which the setting value specification command is not transmitted. By doing so, it is possible to reduce the risk that the registered setting value is illegally acquired.

Further, in the present embodiment, a plurality of flag values including at least 01H (setting change state) can be switched. Then, when 01H (setting change state) is set in the game machine state flag, the setting-related processing can be executed and the progress of the game is stopped. In this way, since the setting-related processing is not executed while the game is in progress, the setting value specification command is not transmitted while the game is in progress, and the risk of illegal acquisition of the registered setting value is reduced. Will be done.

FIG. 27 is a flowchart illustrating a state management process (S460) on the main control board 300. Based on the input port information acquired in step S400-7, the main CPU 300a executes various abnormality (error) determinations and state management processing for making settings according to the determination results.

Specifically, an error including when the opening of the middle frame 104 and the front frame 106 is detected by the door opening detection sensor, magnetism from the outside is detected by the magnetic detection sensor, vibration is detected by the vibration sensor, and the like. To judge. The determination of the error (switch error) related to the specific area detection switch 140s is performed in the switch management process (step S500).

In the state management process, common processes (S460-5 to S460-17) are sequentially executed with reference to a state management process table (not shown) for determining various errors. The state management processing table stores data used in common processing for determining various errors. Specifically, for example, the address where the input port information indicating the status of the corresponding sensor is stored and whether or not to turn on the game machine error status flag described later when an error is detected are stored respectively. ing.

(Step S460-1)
The main CPU 300a sets the address of the state management processing table. Here, in the state management processing table, the address in which the target error determination data is stored is set.

(Step S460-3)
The main CPU 300a sets the number of loops for looping the common processing of the following steps S460-5 to S460-17, corresponding to the number of sensors to be detected for error determination. For example, in the first common process, an error determination regarding the magnetic detection sensor is performed, and in the second and subsequent common processes, the error determination regarding the door opening detection sensor, the radio wave detection sensor, and the like, and the processing for the determination result are sequentially executed.

(Step S460-5)
The main CPU 300a determines whether or not an error has occurred in the sensor that is the detection target of the error determination. As a result, if an error has occurred, the process is transferred to step S460-7, and if no error has occurred, the process is transferred to step S460-15.

(Step S460-7)
The main CPU 300a sets the error specification command in the transmission buffer. The error specification command can identify the type of error that has occurred. The error designation command set here will be transmitted to the sub-control board 330 in the above steps S100-65. As will be described in detail later, when the sub-control board 330 receives the error designation command, it stores the error history information.

(Step S460-9)
The main CPU 300a sets output data for external information indicating that an error has occurred. The output data for this external information will be output to the outside from the game information output terminal board 312.

(Step S460-11)
The main CPU 300a determines whether or not to turn on the game machine error state flag used for setting the game machine state flag. As described above, in the state management processing table, whether or not to turn on the game machine error state flag when an error is detected is stored for each corresponding sensor. In the present embodiment, when an error (vibration error and magnetic error) is detected based on the vibration sensor and the magnetic sensor, it is set in advance to turn on the game machine error state flag, while the door open sensor When an error (door opening error) is detected based on the above, it is preset not to turn on the game machine error status flag.

(Step S460-13)
The main CPU 300a turns on the game machine error status flag.

(Step S460-15)
The main CPU 300a determines whether or not the loop of the number of loops set in step S460-3 has been completed. As a result, when the loop ends, the state management process ends, and when the loop does not end, the process moves to step S460-17.

(Step S460-17)
The main CPU 300a selects an error determination to be the target of the next common processing, and returns the processing to step S460-5.

The above state management process is executed every time the timer interrupt process is performed, regardless of the flag value of the game machine state flag. Therefore, even when the game machine status flag is 01H (setting change status) or 02H (setting confirmation status), if it is determined in step S460-5 that an error has occurred, the error designation command is issued. It will be transmitted to the sub-control board 330. Therefore, in cases other than the playable state, for example, even if an error occurs during the setting change processing and the setting confirmation processing, the history information can be stored in the sub-control board 330, so that fraudulent acts can occur. Even if it is done, it is possible to detect that cheating has been done at an early stage. This makes it possible to improve countermeasures against fraudulent activities.

FIG. 28 is a flowchart illustrating the game machine state flag setting process (S470).

(Step S470-1)
The main CPU 300a determines whether the flag value of the game machine state flag is 00H (gamable state). As a result, if it is determined that it is 00H, the process is moved to step S470-3, and if it is determined that it is not 00H, the game machine state flag setting process is terminated.

(Step S470-3)
The main CPU 300a determines whether the game machine error status flag is on. As a result, if it is determined that the game machine error status flag is on, the process is shifted to step S470-5, and if it is determined that the game machine error status flag is not on, the game machine status flag setting process is performed. finish.

(Step S470-5)
The main CPU 300a sets 06H (illegal detection state) to the game machine state flag, and ends the game machine state flag setting process.

As described above, in the present embodiment, when the flag value of the game machine state flag is 00H (gamable state) and the game machine error state flag is turned on, the game machine state flag is set to 06H (illegal detection state). ) Is set and the game is stopped. Therefore, for example, even if various errors occur when the game machine status flag is 01H (setting change state) or 02H (setting confirmation state), the setting change or setting confirmation is not interrupted, so that the setting change And workability when checking settings can be improved. If the game machine error status flag is turned on while the setting is being changed or the setting is being confirmed, when the setting change or the setting confirmation is completed, the gaming state is momentarily shifted to the gameable state (00H), but the timer interrupt processing is performed. The game machine state flag setting process (step S470) in the above mode shifts to the fraud detection state (06H). Therefore, as a result, when a predetermined error occurs during the setting process (the game machine error state flag is turned on), the game machine state flag is set from 01H or 02H to 06H at once.

Next, among the timer interrupt processes described above, the switch management process in step S500, the special game management process in step S600, and the normal game management process in step S700 will be described in detail.

FIG. 29 is a flowchart illustrating a switch management process (step S500) on the main control board 300.

(Step S500-1)
The main CPU 300a determines whether the gate detection switch is on, that is, whether the game ball has passed through the gate 124 and the detection signal from the gate detection switch 124s is turned on. As a result, if it is determined that the gate detection switch-on is detected, the process is transferred to step S510, and if it is determined that the gate detection switch-on is not detected, the process is transferred to step S500-3.

(Step S510)
The main CPU 300a executes the gate passage process based on the passage of the game ball to the gate 124. The details of this gate passing process will be described later.

(Step S500-3)
The main CPU 300a determines whether the first start port detection switch is on, that is, whether the game ball has entered the first start port 120 and the detection signal has been input from the first start port detection switch 120s. As a result, if it is determined that the first start port detection switch-on is detected, the process is transferred to step S520, and if it is determined that the first start port detection switch-on is not detected, the process is performed in step S500-5. To move.

(Step S520)
The main CPU 300a executes the first starting port passing process based on the entry of the game ball into the first starting port 120. The details of the process of passing through the first starting port will be described later.

(Step S500-5)
The main CPU 300a determines whether the second start port detection switch is on, that is, whether the game ball has entered the second start port 122 and the detection signal has been input from the second start port detection switch 122s. As a result, if it is determined that the second start port detection switch-on is detected, the process is transferred to step S530, and if it is determined that the second start port detection switch-on is not detected, the process is performed in step S500-7. To move.

(Step S530)
The main CPU 300a executes the second starting port passing process based on the entry of the game ball into the second starting port 122. The details of the second starting port passing process will be described later.

(Step S500-7)
The main CPU 300a is at the time when the large winning opening detection switch is turned on, that is, the game ball enters the first large winning opening 126 and the second large winning opening 128, and the first large winning opening detection switch 126s and the second It is determined whether or not the detection signal is input from the large winning opening detection switch 128s. As a result, if it is determined that the large winning opening detection switch-on is detected, the process is shifted to step S500-9, and if it is determined that the large winning opening detection switch-on is not detected, the process proceeds to step S500-11. Move the process.

(Step S500-9)
The main CPU 300a determines whether or not the game is currently in a big role game or a small hit game, and the game ball is properly inserted into the first big winning opening 126 and the second big winning opening 128. Determine if there is. Here, when it is determined that the player is not in the big role game or the small hit game, the predetermined fraud detection process is executed, the player is in the big role game or the small hit game, and the first big winning opening 126 and the second big hit are in progress. When it is determined that the game ball has been properly entered into the winning opening 128, the large winning opening winning ball number counter is added by 1, and the large winning opening winning designation command is set in the transmission buffer.

(Step S500-11)
The main CPU 300a determines whether the specific area detection switch is on, that is, whether the game ball has entered the specific area 140b and the detection signal is input from the specific area detection switch 140s. As a result, if it is determined that the specific area detection switch-on is detected, the process is transferred to step S540, and if it is determined that the specific area detection switch-on is not detected, the process is transferred to step S500-13.

(Step S540)
The main CPU 300a executes the specific area passage process based on the entry of the game ball into the specific area 140b. Further, in the specific area passing process, an error (switch error) related to the specific area detection switch 140s is monitored (detected). The details of this specific area passing process will be described later.

(Step S500-13)
The main CPU 300a determines whether the general winning opening detection switch is on, that is, whether the game ball has entered the general winning opening 118 and the detection signal has been input from the general winning opening detection switch 118s. As a result, if it is determined that the general winning opening detection switch-on is detected, the process is shifted to step S500-15, and if it is determined that the general winning opening detection switch-on is not detected, the process is performed in step S500-17. To move.

(Step S500-15)
The main CPU 300a sets the general winning opening winning designation command in the transmission buffer.

(Step S500-17)
The main CPU 300a determines whether the out-ball detection switch is on, that is, whether the detection signal is input from the out-ball detection switch 130s. As a result, if it is determined that the out-ball detection switch-on is detected, the process is moved to step S500-19, and if it is determined that the out-ball detection switch-on is not detected, the switch management process is terminated. ..

(Step S500-19)
The main CPU 300a sets the out-ball detection designation command in the transmission buffer and ends the switch management process.

FIG. 30 is a flowchart illustrating a gate passing process (step S510) in the main control board 300.

(Step S510-1)
The main CPU 300a loads the hit determination random number updated by the hardware random number generator.

(Step S510-3)
The main CPU 300a determines whether the counter value of the normal symbol reserved ball number counter is the maximum value or more, that is, whether the counter value of the normal symbol reserved ball number counter is 4 or more. As a result, when it is determined that the counter value of the normal symbol reserved ball count counter is equal to or higher than the maximum value, the gate passing process is terminated, and when it is determined that the normal symbol reserved ball number counter is not equal to or higher than the maximum value. The process is transferred to step S510-5.

(Step S510-5)
The main CPU 300a updates the counter value of the normal symbol reserved ball count counter to a value obtained by adding "1" to the current counter value.

(Step S510-7)
The main CPU 300a calculates the target storage unit for saving the acquired hit determination random number among the four storage units in the normal figure reservation storage area.

(Step S510-9)
The main CPU 300a saves the winning determination random number acquired in step S510-1 in the target storage unit calculated in step S510-7.

(Step S510-11)
The main CPU 300a sets the normal figure hold designation command indicating the number of normal figure hold stored in the normal figure hold storage area in the transmission buffer, and ends the gate passing process.

FIG. 31 is a flowchart illustrating a first starting port passing process (step S520) in the main control board 300.

(Step S520-1)
The main CPU 300a sets "00H" as a special symbol identification value. The special symbol identification value is for identifying whether the hold type is special 1 hold or special 2 hold, and the special symbol identification value (00H) indicates special 1 hold, and the special symbol identification value ( 01H) indicates special 2 hold.

(Step S520-3)
The main CPU 300a sets the address of the special symbol 1 reserved ball number counter.

(Step S535)
The main CPU 300a executes the special symbol random number acquisition process and ends the first start port passage process. It should be noted that this special symbol random number acquisition process is executed by using a module common to the second start port passage process (step S530). Therefore, the details of the special symbol random number acquisition process will be described after the description of the second start port passage process.

FIG. 32 is a flowchart illustrating a second starting port passing process (step S530) in the main control board 300.

(Step S530-1)
The main CPU 300a sets "01H" as a special symbol identification value.

(Step S530-3)
The main CPU 300a sets the address of the special symbol 2 reserved ball number counter.

(Step S535)
The main CPU 300a executes a special symbol random number acquisition process described later.

(Step S530-5)
The main CPU 300a loads the normal game management phase. As will be described in detail later, the normal game management phase indicates the stage of the normal game execution process, that is, the progress of the normal game, and is updated according to the stage of the normal game execution process.

(Step S530-7)
The main CPU 300a determines whether the normal game management phase loaded in step S530-5 is "04H". In addition, "04H" of the normal game management phase indicates that the normal electric accessory winning opening opening control process is in progress. In this ordinary electric accessory winning opening opening control process, since the ordinary electric accessory solenoid 122c is energized and the movable piece 122b is controlled to be in the open state, the second starting port 122 can be appropriately opened here. It will be determined whether it is in a state. As a result, if it is determined that the normal game management phase is not "04H", the second start port passage process is terminated, and if it is determined that the normal game management phase is "04H", step S530-9 Move the process to.

(Step S530-9)
The main CPU 300a updates the counter value of the normal electric accessory winning ball number counter to a value obtained by adding "1" to the current counter value, and ends the second starting port passing process.

FIG. 33 is a flowchart illustrating a special symbol random number acquisition process (step S535) on the main control board 300. This special symbol random number acquisition process is executed by using a common module in the first start port passage process (step S520) and the second start port passage process (step S530) described above.

(Step S535-1)
The main CPU 300a loads the special symbol identification value set in step S520-1 or step S530-1.

(Step S535-3)
The main CPU 300a loads the target special symbol reserved ball number. Here, if the special symbol identification value loaded in step S535-1 is "00H", the counter value of the special symbol 1 reserved ball count counter, that is, the special 1 reserved number is loaded. If the special symbol identification value loaded in step S535-1 is "01H", the counter value of the special symbol 2 reserved ball number counter, that is, the special 2 reserved number is loaded.

(Step S535-5)
The main CPU 300a loads the jackpot determination random number updated by the hardware random number generator.

(Step S535-7)
The main CPU 300a determines whether or not the number of target special symbol reserved balls loaded in step S535-3 is equal to or greater than the upper limit value. As a result, if it is determined that the value is equal to or higher than the upper limit value, the process is transferred to step S535-23, and if it is determined that the value is not equal to or higher than the upper limit value, the process is transferred to step S535-9.

(Step S535-9)
The main CPU 300a updates the counter value of the target special symbol reserved ball count counter to a value obtained by adding "1" to the current counter value.

(Step S535-11)
The main CPU 300a calculates the target storage unit for saving the acquired jackpot determination random number among the eight storage units in the special figure reservation storage area.

(Step S535-13)
The main CPU 300a has a jackpot determination random number loaded in step S535-5, a hit symbol random number updated in step S400-19, a reach group determination random number updated in step S100-69, a reach mode determination random number, and a variation pattern. A random number is acquired and stored in the target storage unit calculated in step S535-11.

(Step S535-15)
The main CPU 300a performs a special symbol hold ball winning order setting process of updating and storing the winning order of the special 1 hold and the special 2 hold stored in the special symbol hold storage area.

(Step S535-17)
The main CPU 300a executes an acquisition-time effect determination process for performing a large role provisional lottery, a winning symbol provisional determination, and a variation information provisional determination based on various random numbers stored in the target storage unit in step S535-13. In this acquisition-time effect determination process, a look-ahead designation command indicating fluctuation information determined when the newly stored hold is read is transmitted to the sub-control board 330.

(Step S535-19)
The main CPU 300a loads the counter values of the special symbol 1 reserved ball number counter and the special symbol 2 reserved ball number counter.

(Step S535-21)
The main CPU 300a sets the special figure hold designation command in the transmission buffer based on the counter value loaded in step S535-17. Here, the special figure 1 hold designation command is set based on the counter value (special 1 hold number) of the special symbol 1 hold ball number counter, and based on the counter value (special 2 hold number) of the special symbol 2 hold ball number counter. Set the special figure 2 hold specification command. As a result, each time the special 1 hold or the special 2 hold is stored, the special 1 hold number and the special 2 hold number are transmitted to the sub-control board 330.

(Step S535-23)
The main CPU 300a loads the normal game management phase.

(Step S535-25)
The main CPU 300a confirms the normal game management phase loaded in step S535-23, and determines whether or not it is less than the normal electric accessory winning opening open control state described later. As a result, if it is determined that the state is less than the normal electric accessory winning opening open control state, the process is moved to step S535-27, and if it is determined that the state is not less than the ordinary electric accessory winning opening open control state, the special case is concerned. The symbol random number acquisition process is terminated.

(Step S535-27)
The main CPU 300a determines whether or not there is an abnormal prize, and if it determines that there is an abnormal prize, executes a start port abnormal prize error process that performs a predetermined process, and performs the special symbol random number acquisition process (step S535). ) Is finished.

FIG. 34 is a flowchart illustrating the process of passing through the specific area in step S540.

(Step S540-1)
When the main CPU 300a determines in step S500-11 that the specific area detection switch is on, it determines whether or not the validity period flag is turned on. As a result, if it is determined that the validity period flag is on, the process is transferred to step S540-3, and if it is determined that the validity period flag is not turned on, the process is transferred to step S540-9.

As will be described in detail later, this validity period flag is for determining whether or not the entry of the game ball into the specific area 140b is regarded as valid, and in the present embodiment, the small hit game It is turned on at the beginning of (the first round game).

(Step S540-3)
If it is determined in step S540-1 that the validity period flag is on, the main CPU 300a determines whether the specific area entry flag is on. The specific area entry flag identifies that the game ball has already effectively entered the specific area 140b. If it is determined that the specific area entry flag is on, the specific area passage process is terminated, and if it is determined that the specific area entry flag is not turned on, the process is moved to step S540-5.

(Step S540-5)
The main CPU 300a turns on the specific area entry flag.

(Step S540-7)
The main CPU 300a sets a specific area entry command in the transmission buffer in order to transmit to the sub-control board 330 that the game ball has effectively entered the specific area 140b, and ends the specific area passage process.

(Step S540-9)
The main CPU 300a executes a predetermined error process.

(Step S540-11)
The main CPU 300a sets an error specification command indicating that an error has been detected in the transmission buffer. Here, an error designation command indicating that an illegal winning (illegal winning error) has occurred in the specific area 140b is set in the transmission buffer.

(Step S540-13)
The main CPU 300a turns on the game machine error state flag and ends the specific area passing process.

FIG. 35 is a diagram illustrating a special game management phase. As described above, in the present embodiment, a special game triggered by the entry of the game ball into the first starting port 120 or the second starting port 122 and a normal game triggered by the passage of the game ball through the gate 124. And proceed in parallel at the same time. The processing related to the special game is executed stepwise and repeatedly, and the main control board 300 manages each processing related to the special game by the special game management phase.

As shown in FIG. 35, a plurality of special game control modules for executing and controlling special games are stored in the main ROM 300b, and a special game management phase is associated with each of these special game control modules. .. Specifically, when the special game management phase is "00H", the module for executing the "special symbol change waiting process" is called, and when the special game management phase is "01H", the module is called. When the module for executing "special symbol change processing" is called and the special game management phase is "02H", the module for executing "special symbol stop symbol display processing" is called and special. When the game management phase is "03H" or "07H", the module for executing the "pre-processing for opening the large winning opening" is called, and when the special game management phase is "04H" or "08H". Is called a module for executing the "large winning opening opening control process", and when the special game management phase is "05H" or "09H", the "large winning opening closing effective processing" is executed. When the special game management phase is "06H" or "0AH", the module for executing the "large winning opening end wait process" is called.

FIG. 36 is a flowchart illustrating a special game management process (step S600) on the main control board 300.

(Step S600-1)
The main CPU 300a loads the special game management phase.

(Step S600-3)
The main CPU 300a selects the special game control module corresponding to the special game management phase loaded in step S600-1.

(Step S600-5)
The main CPU 300a calls the special game control module selected in step S600-3 to start the process.

(Step S600-7)
The main CPU 300a loads a special game timer that manages the control time of the special game, and ends the special game management process.

FIG. 37 is a flowchart illustrating a special symbol change waiting process on the main control board 300. This special symbol change waiting process is executed when the special game management phase is "00H".

(Step S610-1)
The main CPU 300a determines whether the counter value of the special symbol 2 hold ball number counter, that is, the special 2 hold number (X2) is "1" or more. As a result, when it is determined that the special 2 hold number (X2) is "1" or more, the process is moved to step S610-7, and when it is determined that the special 2 hold number (X2) is not "1" or more. The process is transferred to step S610-3.

(Step S610-3)
The main CPU 300a determines whether the counter value of the special symbol 1 hold ball number counter, that is, the special 1 hold number (X1) is "1" or more. As a result, when it is determined that the special 1 hold number (X1) is "1" or more, the process is moved to step S610-7, and when it is determined that the special 1 hold number (X1) is not "1" or more. The process is transferred to step S610-5.

(Step S610-5)
The main CPU 300a sets the customer waiting command in the transmission buffer, executes the customer waiting setting process for setting the customer waiting state, and ends the special symbol change waiting process.

(Step S610-7)
The main CPU 300a is stored in the first storage unit to the fourth storage unit of the second special figure reservation storage area, or in the first storage unit to the fourth storage unit of the first special figure reservation storage area. The stored special 1 hold is block-transferred to a storage unit having a smaller ordinal number. Specifically, in step S610-1, when it is determined that the number of balls reserved for special symbol 2 is "1" or more, the second storage unit to the fourth storage unit of the second special symbol reserved storage area are stored. The stored special 2 hold is transferred to the first storage unit to the third storage unit. Further, the main RAM 300c is provided with a 0th storage unit to be processed, and the special 2 hold stored in the 1st storage unit is block-transferred to the 0th storage unit. Further, in step S610-3, when it is determined that the number of special symbol 1 reserved balls is "1" or more, it is stored in the second storage unit to the fourth storage unit of the first special symbol reserved storage area. The special 1 hold stored in the first storage unit is transferred to the first storage unit to the third storage unit, and the special 1 hold stored in the first storage unit is block-transferred to the 0th storage unit. In this special symbol storage area shift process, the counter value of the target special symbol hold ball count counter corresponding to the hold type transferred to the 0th storage unit is subtracted by "1", and special 1 hold or special 2 hold. Sets the hold decrement command in the send buffer to indicate that "1" has been subtracted.

(Step S611)
The main CPU 300a executes a special symbol hit determination process for performing a large winning combination lottery. This special symbol hit detection process will be described later.

(Step S610-11)
The main CPU 300a executes a special symbol symbol determination process for determining a special symbol. Here, when the determination information (lottery result of the big role lottery) stored in step S611 is a big hit or a small hit, the winning type (whether it is a big hit or a small hit) and the holding type are loaded and corresponded. Set the winning symbol random number judgment table. Then, the set hit symbol random number determination table is referred to, special symbol determination data is extracted using the hit symbol random number transferred to the 0th storage unit, and the extracted special symbol determination data (type of jackpot symbol or small hit symbol). ) Is saved. On the other hand, when the lottery result of the large role lottery stored in step S611 is lost, if the hold type is special 1 hold, the special symbol X is saved as the lost symbol, and if the hold type is special 2 hold, Save the special symbol Y as a lost symbol. Here, the symbol type specification command corresponding to the saved special symbol determination data is set in the transmission buffer.

(Step S610-13)
The main CPU 300a saves the special symbol stop symbol number corresponding to the special symbol determination data extracted in step S610-11. The first special symbol display 160 and the second special symbol display 162 are each composed of 7 segments, and each segment constituting the 7 segments is associated with a number (counter value). The special symbol stop symbol number determined here indicates the number (counter value) of the segment that is finally lit.

(Step S612)
The main CPU 300a executes a special symbol variation number determination process for determining the variation mode number and the variation pattern number. The details of this special symbol variation number determination process will be described later.

(Step S610-15)
The main CPU 300a loads the fluctuation mode number and the fluctuation pattern number determined in step S612, and determines the fluctuation time 1 and the fluctuation time 2 with reference to the fluctuation time determination table. Then, the total time of the determined fluctuation times 1 and 2 is set in the special symbol fluctuation timer.

(Step S610-17)
The main CPU 300a performs a preliminary area setting process for performing processing such as storing the game state when the big winning combination lottery is executed in the game state buffer. Further, in this spare area setting process, when the result of the big win lottery is a big hit, the game state information and the type of big hit symbol (special symbol determination data) set after the big win game are stored in the spare area of the main RAM 300c. ..

(Step S610-19)
The main CPU 300a executes a process of setting a special symbol display symbol counter in the first special symbol display 160 or the second special symbol display 162 in order to start the variable display of the special symbol. A counter value is associated with each segment of the 7-segments constituting the first special symbol display 160 and the second special symbol display 162, and the segment corresponding to the counter value set in the special symbol display symbol counter is Lighting is controlled. Here, the counter value corresponding to the segment to be turned on at the start of the variable display of the special symbol is set in the special symbol display symbol counter. The special symbol display symbol counter is provided separately with a special symbol 1 display symbol counter corresponding to the first special symbol display 160 and a special symbol 2 display symbol counter corresponding to the second special symbol display 162. Here, the counter value is set in the counter corresponding to the hold type.

(Step S610-21)
The main CPU 300a loads the counter values of the special symbol 1 hold ball count counter and the special symbol 2 hold ball count counter, and sets the special symbol hold designation command in the transmission buffer. Here, the special figure 1 hold designation command is set based on the counter value (special 1 hold number) of the special symbol 1 hold ball number counter, and based on the counter value (special 2 hold number) of the special symbol 2 hold ball number counter. Set the special figure 2 hold specification command. Further, here, the special symbol winning order command corresponding to the winning order of the special 1 hold and the special 2 hold stored in step S610-7 is set in the transmission buffer. As a result, each time the special 1 hold or the special 2 hold is exhausted, the number of the special 1 hold and the special 2 hold, and the winning order of each of these holds are transmitted to the sub-control board 330.

(Step S610-23)
The main CPU 300a updates the special game management phase to "01H" and ends the special symbol change waiting process.

FIG. 38 is a flowchart illustrating the above-mentioned special symbol collision determination process (S611).

(Step S611-1)
The main CPU 300a loads the registered set value of the set value buffer.

(Step S611-3)
The main CPU 300a determines whether the registration setting value loaded in step S611-1 is within the normal range. As a result, if it is determined that the value is within the normal range, the process is transferred to step S611-9, and if it is determined that the value is not within the normal range, the process is transferred to step S611-5.

(Step S611-5)
The main CPU 300a sets 03H (setting abnormal state) in the game machine state flag.

(Step S611-7)
The main CPU 300a sets the setting abnormal state command (subcommand) in the transmission buffer, and ends the special symbol hit determination process. When this setting error status command is transmitted to the sub-control board 330, a notification indicating that the setting is abnormal is made.

(Step S611-9)
The main CPU 300a refers to the jackpot determination random number determination table corresponding to the information loaded in step S611-1, and sets the lower limit value and the upper limit value when determining jackpot or small hit, respectively.

(Step S611-11)
The main CPU 300a compares the big hit determination random number transferred to the 0th storage unit with the above lower limit value and upper limit value, and performs a determination process (big win lottery) for determining whether or not a big hit or a small hit has been won.

(Step S611-13)
The main CPU 300a sets the result of the determination process in step S611-11 as determination information, and ends the special symbol hit detection process.

FIG. 39 is a flowchart illustrating a special symbol variation number determination process on the main control board 300.

(Step S612-1)
The main CPU 300a determines whether the result of the big winning combination lottery in step S611 is a big hit or a small hit. As a result, if it is determined that it is a big hit or a small hit, the process is moved to step S612-3, and if it is determined that it is neither a big hit nor a small hit (it is a loss), the process is performed in step S612-5. Move.

(Step S612-3)
The main CPU 300a sets a reach mode determination random number determination table corresponding to the current game state, jackpot symbol type, hold type, and variable state.

(Step S612-5)
The main CPU 300a confirms the counter value of the special symbol 2 hold ball count counter when the read hold type is special 2 hold, and when the read hold type is special 1 hold, the main CPU 300a confirms the counter value. Special symbol 1 Check the counter value of the reserved ball count counter.

(Step S612-7)
The main CPU 300a sets the corresponding reach group determination random number determination table based on the current gaming state, the number of holds confirmed in step S612-5, and the hold type. Then, the reach group (group type) is determined based on the set reach group determination random number determination table and the reach group determination random number transferred to the 0th storage unit in step S610-5.

(Step S612-9)
The main CPU 300a sets a random number determination table for determining the reach mode at the time of loss corresponding to the group type determined in step S612-7.

(Step S612-11)
The main CPU 300a has a variable mode based on the reach mode determination random number determination table set in step S612-3 or step S612-9 and the reach mode determination random number transferred to the 0th storage unit in step S610-7. Determine the number. Further, here, the fluctuation pattern random number determination table is determined together with the fluctuation mode number.

(Step S612-13)
The main CPU 300a sets the variation mode command corresponding to the variation mode number determined in step S612-11 in the transmission buffer.

(Step S612-15)
The main CPU 300a determines the variation pattern number based on the variation pattern random number determination table determined in step S612-11 and the variation pattern random number transferred to the 0th storage unit in step S610-7.

(Step S612-17)
The main CPU 300a sets the variation pattern command corresponding to the variation pattern number determined in step S612-15 in the transmission buffer, and ends the special symbol variation number determination process.

FIG. 40 is a flowchart illustrating processing during special symbol change in the main control board 300. This special symbol change processing is executed when the special game management phase is "01H".

(Step S620-1)
The main CPU 300a executes a process of updating the special symbol fluctuation base counter. The counter value of the special symbol fluctuation base counter is set so as to make one round in a predetermined cycle (for example, 100 ms). Specifically, when the counter value of the special symbol fluctuation base counter is "0", a predetermined counter value (for example, 25) is set, and when the counter value is "1" or more, it is set. The counter value is updated to the value obtained by subtracting "1" from the current counter value.

(Step S620-3)
The main CPU 300a determines whether the counter value of the special symbol variation base counter updated in step S620-1 is "0". As a result, if the counter value is "0", the process is transferred to step S620-5, and if the counter value is not "0", the process is transferred to step S620-9.

(Step S620-5)
The main CPU 300a performs a special symbol variation timer update process of subtracting a predetermined value from the timer value of the special symbol variation timer set in step S610-15.

(Step S620-7)
The main CPU 300a determines whether the timer value of the special symbol variation timer updated in step S620-5 is "0". As a result, if the timer value is "0", the process is transferred to step S620-15, and if the timer value is not "0", the process is transferred to step S620-9.

(Step S620-9)
The main CPU 300a updates the special symbol display timer that measures the lighting time of each segment of the 7-segments constituting the first special symbol display 160 and the second special symbol display 162. Specifically, when the timer value of the special symbol display timer is "0", a predetermined timer value is set, and when the timer value is "1" or more, the current timer value is used. "1" Updates the timer value to the subtracted value.

(Step S620-11)
The main CPU 300a determines whether the timer value of the special symbol display timer is "0". As a result, when it is determined that the timer value of the special symbol display timer is "0", the process is shifted to step S620-13, and when it is determined that the timer value of the special symbol display timer is not "0", the process is concerned. Ends processing during special symbol change.

(Step S620-13)
The main CPU 300a updates the counter value of the special symbol display symbol counter to be updated, and ends the processing during the special symbol change. As a result, each segment constituting the 7-segment is sequentially turned on at predetermined time intervals.

(Step S620-15)
The main CPU 300a updates the special game management phase to "02H".

(Step S620-17)
The main CPU 300a saves the special symbol stop symbol number (counter value) determined in step S610-13 in the target special symbol display symbol counter. As a result, the determined special symbol is stopped and displayed on the first special symbol display 160 or the second special symbol display 162.

(Step S620-19)
The main CPU 300a sets in the transmission buffer a special symbol stop designation command indicating that the special symbol has been stopped and displayed on the first special symbol display 160 or the second special symbol display 162.

(Step S620-21)
The main CPU 300a sets the special symbol change stop time, which is the time for stopping and displaying the special symbol, in the special game timer, and ends the processing during the special symbol change.

FIG. 41 is a flowchart illustrating a special symbol stop symbol display process on the main control board 300. This special symbol stop symbol display process is executed when the special game management phase is "02H".

(Step S630-1)
The main CPU 300a determines whether the timer value of the special game timer set in step S620-21 is not "0". As a result, when it is determined that the timer value of the special game timer is not "0", the special symbol stop symbol display process is terminated, and when it is determined that the timer value of the special game timer is "0", the special symbol stop symbol display process is terminated. The process is transferred to step S630-3.

(Step S630-3)
The main CPU 300a confirms the result of the big role lottery.

(Step S630-5)
The main CPU 300a determines whether the result of the big winning combination lottery is a big hit. As a result, if it is determined that it is a big hit, the process is transferred to step S630-19, and if it is determined that it is not a big hit, the process is transferred to step S630-7.

(Step S630-7)
The main CPU 300a executes the count-cutting management process. Here, the time saving state flag for identifying whether the gaming state is the non-time saving gaming state or the time saving gaming state is loaded, and whether the current gaming state is the non-time saving gaming state or the time saving gaming state. To confirm. Then, when the gaming state is the time-saving gaming state, the counter value of the time-saving number-cutting counter is updated to a value obtained by subtracting "1" from the current counter value. If the counter value becomes "0" as a result of updating the time reduction count cut counter, the time reduction state flag corresponding to the non-time reduction game state is set. As a result, in the time-saving game state, the game state shifts to the non-time-saving game state when the special symbol is determined a predetermined number of times without winning the jackpot.

(Step S630-9)
The main CPU 300a updates the fluctuation state.

(Step S630-11)
The main CPU 300a sets in the transmission buffer a command for confirming the game state when the special symbol is confirmed, which indicates the game state when the special symbol is confirmed.

(Step S630-13)
The main CPU 300a sets in the transmission buffer a number of times command for transmitting the number of time reductions updated in step S630-7 to the sub-control board 330.

(Step S630-15)
The main CPU 300a determines whether the result of the big winning combination lottery is a small hit. As a result, if it is determined that it is a small hit, the process is transferred to step S630-21, and if it is determined that it is not a small hit, the process is transferred to step S630-17.

(Step S630-17)
The main CPU 300a updates the special game management phase to "00H" and ends the special symbol stop symbol display process. As a result, when the special game management process based on the hold of 1 is completed and the special 1 hold or the special 2 hold is stored, the process for starting the variable display of the special symbol based on the next hold is performed. Will be remembered.

(Step S630-19)
The main CPU 300a resets (sets) the gaming state to the non-time-saving gaming state, which is the initial state.

(Step S630-21)
The main CPU 300a sets the data of the special electric accessory operation ram set table according to the type of the determined special symbol.

(Step S630-23)
The main CPU 300a performs a process of setting the maximum number of operations of the special electric accessory. Specifically, referring to the data set in step S630-21, a predetermined number (counter value corresponding to the type of special symbol = number of rounds) is set as a counter value in the special electric accessory maximum operation count counter. .. In addition, this special electric accessory maximum operation number counter indicates the number of rounds that can be executed in the big role game to be started from now on. On the other hand, the main RAM 300c is provided with a special electric accessory continuous operation count counter, and by adding the counter value of the special electric accessory continuous operation counter to "1" at the start of each round game, the current counter value is added. The number of round games is managed. Here, with the start of the big role game, the process of resetting (updating to "0") the counter value of the special electric accessory continuous operation number counter is also executed.

(Step S630-25)
The main CPU 300a refers to the data set in step S630-21 and saves a predetermined opening time as a timer value in the special game timer.

(Step S630-27)
The main CPU 300a sets in the transmission buffer an opening designation command for transmitting the start of the big win game or the small hit game to the sub-control board 330. It should be noted that this opening designation command is provided for each opening time, and here, the opening designation command corresponding to the opening time saved in step S630-25 is set in the transmission buffer.

(Step S630-29)
The main CPU 300a updates the special game management phase to "03H" when the result of the big win lottery confirmed in step S630-3 is a big hit, and sets the special game management phase to "03H" when it is a small hit. Update to "07H" to end the special symbol stop symbol display process. As a result, the big role game or the small hit game is started.

FIG. 42 is a flowchart illustrating the pre-opening process of the large winning opening on the main control board 300. This large winning opening pre-opening process is executed when the special game management phase is "03H" or "07H".

(Step S640-1)
The main CPU 300a determines whether the timer value of the special game timer is "0". As a result, if it is determined that the timer value of the special game timer is not "0", the pre-processing for opening the large winning opening is terminated, and if it is determined that the timer value of the special game timer is "0", The process is transferred to step S640-3.

(Step S640-3)
The main CPU 300a updates the counter value of the special electric accessory continuous operation count counter to a value obtained by adding "1" to the current counter value.

(Step S640-5)
The main CPU 300a sets in the transmission buffer a command for specifying the opening of the first special winning opening 126 and the opening of the second special winning opening 128 (start of the round game) to be transmitted to the sub-control board 330.

(Step S641)
The main CPU 300a executes a large winning opening opening / closing switching process. This large winning opening opening / closing switching process will be described later.

(Step S640-7)
The main CPU 300a determines whether the special game management phase is 07H, that is, whether the small hit game is in progress. As a result, if it is determined that the special game management phase is 07H, the process is transferred to step S640-9, and if it is determined that the special game management phase is not 07H, the process is transferred to step S640-13.

(Step S640-9)
The main CPU 300a determines whether or not it is the start of the first round game based on the counter value of the special electric accessory continuous operation number counter. As a result, if it is determined that it is the start of the first round game, the process is transferred to step S640-11, and if it is determined that it is not the start of the first round game, the process is performed in step S640-13. Move.

(Step S640-11)
The main CPU 300a turns on the validity period flag. As a result, the entry of the game ball into the specific area 140b is enabled with the start of the small hit game.

(Step S640-13)
The main CPU 300a updates the special game management phase to a value obtained by adding 01H to the current value (“04H” or “08H”), and ends the pre-processing for opening the large winning opening.

FIG. 43 is a flowchart illustrating a large winning opening opening / closing switching process on the main control board 300.

(Step S641-1)
In the main CPU 300a, the counter value of the special electric accessory opening / closing switching counter is the number of times the special electric accessory opening / closing switching is performed (the number of times the first special winning opening 126 and the second major winning opening 128 are opened / closed during one round game). Determine if it is the upper limit. As a result, when it is determined that the counter value is the upper limit value, the large winning opening opening / closing switching process is terminated, and when it is determined that the counter value is not the upper limit value, the process is moved to step S641-3.

(Step S641-3)
The main CPU 300a energizes the first special electric accessory opening solenoid 126c or the second special winning opening solenoid 128c based on the counter value of the special electric accessory opening / closing switching count counter with reference to the data of the special electric accessory operating ram set table. The solenoid control data for control and the timer data which is the energization time or the energization stop time of the first special winning opening solenoid 126c or the second special winning opening solenoid 128c are extracted.

(Step S641-5)
Based on the solenoid control data extracted in step S641-3, the main CPU 300a starts energizing the first winning opening solenoid 126c or the second winning opening solenoid 128c, or the first winning opening solenoid 126c. Alternatively, the large winning opening solenoid energization control process for stopping the energization of the second special winning opening solenoid 128c is executed. By executing this large winning opening solenoid energization control process, the energization start or energization stop of the first special winning opening solenoid 126c or the second special winning opening solenoid 128c is controlled in steps S400-31 and S400-33. It will be.

(Step S641-7)
The main CPU 300a saves the timer value based on the timer data extracted in step S641-3 in the special game timer. The timer value saved in the special game timer here is the maximum opening time of one of the first special winning opening 126 and the second special winning opening 128.

(Step S641-9)
The main CPU 300a is in the energization start state of the first special winning opening solenoid 126c or the second special winning opening solenoid 128c, that is, in step S641-5, the first special winning opening solenoid 126c or the second special winning opening solenoid 128c Determine if the control process to start energization has been performed. As a result, if it is determined that the energization start state is established, the process is shifted to step S641-11, and if it is determined that the energization start state is not present, the large winning opening opening / closing switching process is terminated.

(Step S641-11)
The main CPU 300a updates the counter value of the special electric accessory opening / closing switching count counter to a value obtained by adding "1" to the current counter value, and ends the special winning opening opening / closing switching process.

FIG. 44 is a flowchart illustrating a large winning opening opening control process on the main control board 300. This large winning opening opening control process is executed when the special game management phase is "04H" or "08H".

(Step S650-1)
The main CPU 300a determines whether the timer value of the special game timer saved in step S641-7 is "0". As a result, if it is determined that the timer value of the special game timer is not "0", the process shifts to step S650-5, and if it is determined that the timer value of the special game timer is "0", step S650 Move the process to -3.

(Step S650-3)
The main CPU 300a determines whether the counter value of the special electric accessory opening / closing switching number counter is the upper limit value of the special electric accessory opening / closing switching number. As a result, when it is determined that the counter value is the upper limit value, the process is transferred to step S650-7, and when it is determined that the counter value is not the upper limit value, the process is transferred to step S641.

(Step S641)
If it is determined in step S650-3 that the counter value of the special electric accessory opening / closing switching count counter is not the upper limit value of the special electric accessory opening / closing switching count, the main CPU 300a executes the process of step S641. To do.

(Step S650-5)
In the main CPU 300a, the counter value of the large winning opening winning ball number counter updated in step S500-9 has not reached the specified number, that is, the first special winning opening 126 or the second large winning opening 128 is set. It is determined whether or not the same number of game balls as the maximum number of winning balls in one round have been entered. As a result, if it is determined that the specified number has not been reached, the large winning opening opening control process is terminated, and if it is determined that the specified number has been reached, the process is moved to step S650-7.

(Step S650-7)
The main CPU 300a has a large winning opening closing process required to stop the energization of the first special winning opening solenoid 126c and the second special winning opening solenoid 128c to close the first special winning opening 126 and the second large winning opening 128. To execute. As a result, the first prize opening 126 and the second prize opening 128 are closed.

(Step S650-9)
The main CPU 300a saves the winning opening closing effective time (interval time) in the special game timer.

(Step S650-11)
The main CPU 300a updates the special game management phase to a value obtained by adding 01H to the current value (“05H” or “09H”).

(Step S650-13)
The main CPU 300a sets a command for designating the closing of the first special winning opening 126 and the second special winning opening 128 in the transmission buffer, and ends the special winning opening opening control process.

FIG. 45 is a flowchart illustrating a large winning opening closing effective process in the main control board 300. This special game management phase is executed when the special game management phase is "05H" or "09H".

(Step S660-1)
The main CPU 300a determines whether the timer value of the special game timer saved in step S650-9 is not "0". As a result, if it is determined that the timer value of the special game timer is not "0", the special game timer closing valid processing is terminated, and if it is determined that the timer value of the special game timer is "0", the special game timer is determined to be "0". The process is transferred to step S660-3.

(Step S660-3)
The main CPU 300a determines whether the counter value of the special electric accessory continuous operation count counter matches the counter value of the special electric accessory maximum operation count counter, that is, whether the round game of a preset number of times is completed. .. As a result, when it is determined that the counter value of the special electric accessory continuous operation count counter matches the counter value of the special electric accessory maximum operation count counter, the process is transferred to step S660-9, and when it is determined that they do not match. The process is transferred to step S660-5.

(Step S660-5)
The main CPU 300a updates the special game management phase to "03H". When the special game management phase is "09H", that is, during the control of the small hit game, the number of round games of the small hit game is "1". Therefore, it is always determined as YES in step S660-3. However, the process does not shift to the step.

(Step S660-7)
The main CPU 300a saves a predetermined large winning opening closing time in the special game timer, and ends the large winning opening closing valid process. As a result, the next round game will be started.

(Step S660-9)
The main CPU 300a determines whether the special game management phase is 09H, that is, whether the small hit game is in progress. As a result, if it is determined that the special game management phase is 09H, the process is transferred to step S660-11, and if it is determined that the special game management phase is not 09H, the process is transferred to step S660-21.

(Step S660-11)
The main CPU 300a determines whether all the game balls that have entered the second special winning opening 128 have been discharged. Here, when the value obtained by subtracting the total number of game balls that have entered the specific area 140b and the non-specific area 140c from the number of game balls that have entered the second major winning opening 128 becomes 0, the discharge is completed. Is determined. If it is determined that the discharge is completed, the process is moved to step S660-13, and if it is determined that the discharge is not completed, the large winning opening closing effective process is terminated. If the determination result that the discharge is not completed is continuously derived for a certain period of time, error processing is performed.

(Step S660-13)
The main CPU 300a determines whether or not the specific area entry flag is turned on. As a result, if it is determined that the specific area entry flag is on, the process is transferred to step S660-15, and if it is determined that the specific area entry flag is not turned on, the process is transferred to step S660-21. ..

(Step S660-15)
The main CPU 300a turns off the specific area entry flag.

(Step S660-17)
The main CPU 300a confirms the type of the small hit symbol, and adds 1 to the counter for the maximum number of operations of the special electric accessory as a counter value (counter value corresponding to the type of special symbol = the number of rounds minus 1). Set the number of round games in the big role game).

(Step S660-19)
The main CPU 300a sets 03H in the special game management phase and ends the large winning opening closing effective process.

(Step S660-21)
The main CPU 300a executes an ending time setting process for saving the ending time in the special game timer.

(Step S660-23)
The main CPU 300a updates the special game management phase to a value obtained by adding 01H to the current value (“06H” or “0AH”).

(Step S660-25)
The main CPU 300a sets an ending designation command indicating the start of the ending in the transmission buffer, and ends the large winning opening closing valid processing.

FIG. 46 is a flowchart illustrating the large winning opening end wait process on the main control board 300. This large winning opening end wait process is executed when the special game management phase is "06H" or "0AH".

(Step S670-1)
The main CPU 300a determines whether the timer value of the special game timer saved in step S660-9 is not "0". As a result, if it is determined that the timer value of the special game timer is not "0", the large winning opening end wait process is terminated, and if it is determined that the timer value of the special game timer is "0", the step The process is transferred to S670-3.

(Step S670-3)
The main CPU 300a executes a state setting process for setting a game state after the end of the major game. Here, the game state after the end of the big role game is set based on the big hit symbol that triggered the execution of the big role game. Specifically, when the jackpot symbols that triggered the execution of the big role game are the special symbols A and a, the time reduction game state is set and the time reduction number of times is set to one. Further, when the jackpot symbols that triggered the execution of the big role game are the special symbols B, C, b, and c, the time reduction game state is set and the time reduction number is set to 7 times.

Further, here, after the end of the big role game or the small hit game, based on the big hit symbol that triggered the execution of the big role game or the small hit symbol that triggered the execution of the small hit game and the set value being set. The process of setting the fluctuation state is also performed.

(Step S670-5)
The main CPU 300a sets in the transmission buffer a game state change designation command for transmitting a game state and a change state set after the end of the major game.

(Step S670-7)
The main CPU 300a sets in the transmission buffer a command for specifying the number of times corresponding to the number of times saved in step S670-3.

(Step S670-9)
The main CPU 300a updates the special game management phase to "00H" and ends the large winning opening end wait process. As a result, when the special 1 hold or the special 2 hold is stored, the variable display of the special symbol is restarted.

FIG. 47 is a diagram illustrating a normal game management phase. As described above, in the present embodiment, the processing related to the normal game triggered by the passage of the game ball to the gate 124 is executed stepwise and repeatedly, but in the main control board 300, such a normal game Each process related to is managed by the normal game management phase.

As shown in FIG. 47, a plurality of normal game control modules for executing and controlling normal games are stored in the main ROM 300b, and a normal game management phase is associated with each of these normal game control modules. .. Specifically, when the normal game management phase is "00H", the module for executing the "normal symbol change waiting process" is called, and when the normal game management phase is "01H", the module is called. The module for executing "normal symbol change processing" is called, and when the normal game management phase is "02H", the module for executing "normal symbol stop symbol display processing" is called, and normal. When the game management phase is "03H", the module for executing "pre-processing for opening the winning opening of the normal electric accessory" is called, and when the normal game management phase is "04H", "normal". When the module for executing the "electric accessory winning opening opening control process" is called and the normal game management phase is "05H", the module for executing the "normal electric accessory winning opening closing effective processing" Is called, and when the normal game management phase is "06H", the module for executing the "normal electric accessory winning opening end wait process" is called.

FIG. 48 is a flowchart illustrating a normal game management process (step S700) on the main control board 300.

(Step S700-1)
The main CPU 300a loads the normal game management phase.

(Step S700-3)
The main CPU 300a selects the normal game control module corresponding to the normal game management phase loaded in step S700-1.

(Step S700-5)
The main CPU 300a calls the normal game control module selected in step S700-3 and starts processing.

(Step S700-7)
The main CPU 300a loads a normal game timer that manages the control time of the normal game.

FIG. 49 is a flowchart illustrating a normal symbol change waiting process on the main control board 300. This normal symbol change waiting process is executed when the normal game management phase is "00H".

(Step S710-1)
The main CPU 300a loads the counter value of the normal symbol hold ball number counter, and determines whether the counter value is "0", that is, whether the normal symbol hold is "0". As a result, when it is determined that the counter value is "0", the normal symbol change waiting process is terminated, and when it is determined that the counter value is not "0", the process is moved to step S710-3.

(Step S710-3)
The main CPU 300a blocks-transfers the normal figure hold (hit determination random number) stored in the first to fourth storage units of the normal figure hold storage area to the storage unit having a smaller ordinal number. Specifically, the normal figure hold stored in the second storage unit to the fourth storage unit is transferred to the first storage unit to the third storage unit. Further, the main RAM 300c is provided with a 0th storage unit to be processed, and the normal drawing hold stored in the 1st storage unit is transferred to the 0th storage unit. In this normal symbol storage area shift process, the counter value of the normal symbol hold ball count counter is subtracted by "1", and a normal symbol hold reduction specification command indicating that the normal symbol hold is subtracted by "1" is transmitted. Set in the buffer.

(Step S710-5)
The main CPU 300a loads the hit determination random number transferred to the 0th storage unit, selects the hit determination random number determination table corresponding to the current game state, performs a general drawing lottery, and stores the lottery result. Execute the judgment process.

(Step S710-7)
The main CPU 300a saves the normal symbol stop symbol number corresponding to the result of the normal symbol lottery in step S710-5. In the present embodiment, the normal symbol display 168 is composed of one LED lamp, and the normal symbol display 168 is turned on in the case of a hit, and the normal symbol display 168 is turned off in the case of a loss. .. The normal symbol stop symbol number determined here indicates whether or not the normal symbol display 168 is finally turned on. For example, if a winner is won, the normal symbol stop symbol number is "0". Is determined, and in the case of loss, "1" is determined as the normal symbol stop symbol number.

(Step S710-9)
The main CPU 300a confirms the current gaming state, selects and sets the corresponding normal symbol variation time data table.

(Step S710-11)
The main CPU 300a determines the normal symbol fluctuation time based on the hit determination random number transferred to the 0th storage unit in step S710-3 and the normal symbol fluctuation time data table set in step S710-9.

(Step S710-13)
The main CPU 300a saves the normal symbol fluctuation time determined in step S710-11 in the normal game timer.

(Step S710-15)
The main CPU 300a executes a process of setting a normal symbol display symbol counter in the normal symbol display 168 in order to start a variable display of the normal symbol. When, for example, "0" is set as the counter value in the normal symbol display symbol counter, the normal symbol display 168 is lit and controlled, and when "1" is set as the counter value, the normal symbol display is performed. The device 168 is turned off. Here, a predetermined counter value is set in the normal symbol display symbol counter at the start of the fluctuation display of the normal symbol.

(Step S710-17)
The main CPU 300a sets in the transmission buffer a command for designating the hold of the normal figure, which indicates the number of hold of the normal figure stored in the hold storage area of the normal figure.

(Step S710-19)
The main CPU 300a transmits a normal symbol designation command based on the normal symbol stop symbol number determined in step S710-7, that is, the symbol type (win symbol or lost symbol) determined by the normal symbol hit determination process. Set to.

(Step S710-21)
The main CPU 300a updates the normal game management phase to "01H" and ends the normal symbol change waiting process.

FIG. 50 is a flowchart illustrating processing during normal symbol variation in the main control board 300. This normal symbol change processing is executed when the normal game management phase is "01H".

(Step S720-1)
The main CPU 300a determines whether the timer value of the normal game timer saved in step S710-13 is "0". As a result, if the timer value is "0", the process is transferred to step S720-9, and if the timer value is not "0", the process is transferred to step S720-3.

(Step S720-3)
The main CPU 300a updates the normal symbol display timer that measures the lighting time and the extinguishing time of the normal symbol display 168. Specifically, when the timer value of the normal symbol display timer is "0", a predetermined timer value is set, and when the timer value is "1" or more, the current timer value is used. "1" Updates the timer value to the subtracted value.

(Step S720-5)
The main CPU 300a determines whether the timer value of the normal symbol display timer is "0". As a result, when it is determined that the timer value of the normal symbol display timer is "0", the process is shifted to step S720-7, and when it is determined that the timer value of the normal symbol display timer is not "0", the process is performed. Ends processing during normal symbol change.

(Step S720-7)
The main CPU 300a updates the counter value of the normal symbol display symbol counter. Here, when the counter value of the normal symbol display symbol counter is a counter value indicating that the normal symbol display 168 is turned off, the counter value indicating lighting is updated, and the counter value indicating lighting of the normal symbol display 168 is updated. If is, the counter value indicating that the light is turned off is updated, and the processing during the normal symbol change is terminated. As a result, the normal symbol display 168 is repeatedly turned on and off (blinks) at predetermined time intervals over the normal symbol fluctuation time.

(Step S720-9)
The main CPU 300a saves the normal symbol stop symbol number (counter value) determined in step S710-7 in the normal symbol display symbol counter. As a result, the normal symbol display 168 is finally controlled to be turned on or off, and the result of the normal symbol lottery is notified.

(Step S720-11)
The main CPU 300a sets the normal symbol fluctuation stop time, which is the time for stopping and displaying the normal symbol, in the normal game timer.

(Step S720-13)
The main CPU 300a sets in the transmission buffer a command for specifying the stop of the normal symbol indicating that the stop display of the normal symbol has started.

(Step S720-15)
The main CPU 300a updates the normal game management phase to "02H" and ends the normal symbol changing process.

FIG. 51 is a flowchart illustrating a normal symbol stop symbol display process on the main control board 300. This normal symbol stop symbol display process is executed when the normal game management phase is "02H".

(Step S730-1)
The main CPU 300a determines whether the timer value of the normal game timer set in step S720-11 is "0". As a result, when it is determined that the timer value of the normal game timer is not "0", the normal symbol stop symbol display process is terminated, and when it is determined that the timer value of the normal game timer is "0", the timer value is determined to be "0". The process is transferred to step S730-3.

(Step S730-3)
The main CPU 300a confirms the result of the drawing lottery.

(Step S730-5)
The main CPU 300a determines whether or not the result of the general drawing lottery is a hit. As a result, if it is determined that it is a hit, the process is transferred to step S730-9, and if it is determined that it is not a hit (it is a loss), the process is transferred to step S730-7.

(Step S730-7)
The main CPU 300a updates the normal game management phase to "00H" and ends the normal symbol stop symbol display process. As a result, when the normal game management process based on the normal figure hold of 1 is completed and the normal figure hold is stored, the process for starting the variable display of the normal symbol based on the next hold is performed. It becomes.

(Step S730-9)
The main CPU 300a refers to the data in the open / close control pattern table, and saves the time before opening the normal power as a timer value in the normal game timer.

(Step S730-11)
The main CPU 300a updates the normal game management phase to "03H" and ends the normal symbol stop symbol display process. As a result, the opening / closing control of the second starting port 122 is started.

FIG. 52 is a flowchart illustrating the preprocessing for opening the winning opening of the ordinary electric accessory on the main control board 300. This normal electric accessory winning opening pre-opening process is executed when the normal game management phase is "03H".

(Step S740-1)
The main CPU 300a determines whether the timer value of the normal game timer is "0". As a result, when it is determined that the timer value of the normal game timer is not "0", the pre-processing for opening the winning opening of the normal electric accessory is terminated, and when it is determined that the timer value of the normal game timer is "0". The process is transferred to step S741.

(Step S741)
The main CPU 300a executes an ordinary electric accessory winning opening opening / closing switching process. The opening / closing switching process for the winning opening of the ordinary electric accessory will be described later.

(Step S740-3)
The main CPU 300a updates the normal game management phase to "04H" and ends the pre-opening process of the normal electric accessory winning opening.

FIG. 53 is a flowchart illustrating a process of switching the opening / closing of the winning opening of the ordinary electric accessory on the main control board 300.

(Step S741-1)
The main CPU 300a determines whether the counter value of the normal electric accessory opening / closing switching number counter is the upper limit value of the normal electric accessory opening / closing switching number (the number of times the movable piece 122b is opened / closed during one opening / closing control). As a result, when it is determined that the counter value is the upper limit value, the opening / closing switching process of the ordinary electric accessory winning opening is terminated, and when it is determined that the counter value is not the upper limit value, the process is performed in step S741-3. Move.

(Step S741-3)
The main CPU 300a refers to the data in the open / close control pattern table, and based on the counter value of the normal electric accessory opening / closing switching count counter, the solenoid control data (energization control data or energization control data) for energizing the ordinary electric accessory solenoid 122c. Stop control data) and timer data that is the energization time (solenoid energization time) or energization stop time (normal power closing effective time = pause time) of the ordinary electric accessory solenoid 122c are extracted.

(Step S741-5)
Based on the solenoid control data extracted in step S741-3, the main CPU 300a starts energizing the ordinary electric accessory solenoid 122c, or stops energization of the ordinary electric accessory solenoid 122c. The object solenoid energization control process is executed. By executing this normal electric accessory solenoid energization control process, the energization start or energization stop of the ordinary electric accessory solenoid 122c is controlled in steps S400-31 and S400-33.

(Step S741-7)
The main CPU 300a saves the timer value based on the timer data extracted in step S741-3 in the normal game timer. The timer value saved in the normal game timer here is the maximum opening time of the second start port 122 once.

(Step S741-9)
The main CPU 300a determines whether the energization start state of the ordinary electric accessory solenoid 122c is performed, that is, whether the control process for starting the energization of the ordinary electric accessory solenoid 122c is performed in step S741-5. As a result, if it is determined that the energization start state is determined, the process is shifted to step S741-11, and if it is determined that the energization start state is not present, the normal electric accessory winning opening opening / closing switching process is terminated.

(Step S741-11)
The main CPU 300a updates the counter value of the normal electric accessory opening / closing switching count counter to a value obtained by adding "1" to the current counter value.

FIG. 54 is a flowchart illustrating a normal electric accessory winning opening opening control process on the main control board 300. This normal electric accessory winning opening opening control process is executed when the normal game management phase is "04H".

(Step S750-1)
The main CPU 300a determines whether the timer value of the normal game timer saved in step S741-7 is "0". As a result, if it is determined that the timer value of the normal game timer is not "0", the process is shifted to step S750-5, and if it is determined that the timer value of the normal game timer is "0", step S750 Move the process to -3.

(Step S750-3)
The main CPU 300a determines whether the counter value of the normal electric accessory opening / closing switching number counter is the upper limit value of the normal electric accessory opening / closing switching number. As a result, when it is determined that the counter value is the upper limit value, the process is transferred to step S750-7, and when it is determined that the counter value is not the upper limit value, the process is transferred to step S741.

(Step S741)
If it is determined in step S750-3 that the counter value of the normal electric accessory opening / closing switching count counter is not the upper limit of the normal electric accessory opening / closing switching count, the main CPU 300a executes the process of step S741. To do.

(Step S750-5)
In the main CPU 300a, the counter value of the normal electric accessory winning ball number counter updated in step S530-9 has not reached the specified number, that is, the second starting port 122 is being controlled to open / close once. It is determined whether or not the same number of game balls as the maximum number of winning balls have been entered. As a result, if it is determined that the specified number has not been reached, the normal electric accessory winning opening opening control process is terminated, and if it is determined that the specified number has been reached, the process is moved to step S750-7.

(Step S750-7)
The main CPU 300a executes the ordinary electric accessory closing process necessary for stopping the energization of the ordinary electric accessory solenoid 122c and closing the second starting port 122. As a result, the second starting port 122 is closed.

(Step S750-9)
The main CPU 300a saves the normal power effective state time in the normal game timer.

(Step S750-11)
The main CPU 300a updates the normal game management phase to "05H" and ends the normal electric accessory winning opening opening control process.

FIG. 55 is a flowchart illustrating an ordinary electric accessory winning opening closing effective process on the main control board 300. This normal electric accessory winning opening closing effective process is executed when the normal game management phase is "05H".

(Step S760-1)
The main CPU 300a determines whether the timer value of the normal game timer saved in step S750-9 is "0". As a result, when it is determined that the timer value of the normal game timer is not "0", the normal electric accessory winning opening closing effective process is terminated, and it is determined that the timer value of the normal game timer is "0". In that case, the process is transferred to step S760-3.

(Step S760-3)
The main CPU 300a saves the normal game end wait time in the normal game timer.

(Step S760-5)
The main CPU 300a updates the normal game management phase to "06H" and ends the normal electric accessory winning opening closing effective process.

FIG. 56 is a flowchart illustrating a normal electric accessory winning opening end weight process on the main control board 300. This normal electric accessory winning opening end wait process is executed when the normal game management phase is "06H".

(Step S770-1)
The main CPU 300a determines whether the timer value of the normal game timer saved in step S760-3 is "0". As a result, when it is determined that the timer value of the normal game timer is not "0", the normal electric accessory winning opening end wait process is terminated, and it is determined that the timer value of the normal game timer is "0". In that case, the process is moved to step S770-3.

(Step S770-3)
The main CPU 300a updates the normal game management phase to "00H" and ends the normal electric accessory winning opening end wait process. As a result, when the normal symbol hold is stored, the variable display of the normal symbol is restarted.

As described above, by executing various processes on the main control board 300, the special game and the normal game proceed, and during the progress of such a game, a command transmitted from the main control board 300 Based on the above, the sub-control board 330 is controlled to execute various effects.

FIG. 57 (a) is a diagram for explaining an example of the setting confirmation screen, FIG. 57 (b) is a diagram for explaining an example of the administrator menu screen, and FIG. 57 (c) is a standby screen. It is a figure explaining an example, and FIG. 57 (d) is a figure explaining an example of a staff menu screen. When the game machine status flag is set to 02H (setting confirmation status) on the main control board 300, a setting confirmation status specification command is transmitted to the sub control board 330 (S100-55 in FIG. 22). When the sub-control board 330 receives the setting confirmation status designation command, the effect display unit 200a displays the setting confirmation screen as shown in FIG. 57 (a).

This setting confirmation screen notifies that the setting has been confirmed, that is, the main control board 300 is in the setting confirmation state. On this setting confirmation screen, "Press and hold the left cross key to display the administrator menu" is displayed, and the input method of the menu display operation is notified. Here, an operation of continuously pressing the left button of the cross key 209 for a predetermined time or longer is preset as a menu display operation. If a menu display operation is input while the setting confirmation screen is being displayed, that is, while the main control board 300 is in the setting confirmation state, the administrator menu screen shown in FIG. 57B is displayed.

On the administrator menu screen, for example, "date and time setting", "setting change history confirmation", "error history confirmation", "power saving mode setting", "board LED confirmation", and "end" are written respectively. A tab is displayed. While the administrator menu screen is being displayed, any one of the six tabs is highlighted so that the currently selected item can be grasped. When a selection operation (pressing the up button or the down button on the cross key 209) is performed while the administrator menu screen is displayed, the highlighted tab, that is, the selected item is switched. Then, when the determination operation (pressing operation of the effect button 208) is performed, the detail screen corresponding to the selected item is displayed.

Further, when the initialization process is performed on the main control board 300, a RAM clear designation command is transmitted to the sub control board 330 (S110-3 in FIG. 23). When the sub-control board 330 receives the RAM clear designation command, the effect display unit 200a displays the standby screen as shown in FIG. 57 (c).

This standby screen notifies that the player is in a standby state until the game is started. Similar to the above setting confirmation screen, the standby screen also displays "Staff menu by pressing and holding the left cross key" to notify the input method of the menu display operation. If a menu display operation is input while the standby screen is being displayed, the staff menu screen shown in FIG. 57 (d) is displayed. Here, the menu display operation for displaying the administrator menu screen and the menu display operation for displaying the staff menu screen are common, but the two may be different.

On the staff menu screen, for example, four tabs marked with "date and time setting", "power saving mode setting", "board LED confirmation", and "end" are displayed. While the staff menu screen is being displayed, one of the four tabs is highlighted so that you can see which item is currently selected. When a selection operation is performed while the staff menu screen is displayed, the highlighted tab, that is, the selected item is switched, and when the decision operation is performed, the detail screen corresponding to the selected item is displayed.

There are fewer items displayed on the staff menu screen than on the administrator menu screen. Specifically, "date and time setting", "power saving mode setting", "board LED confirmation", and "end" are displayed on both the administrator menu screen and the staff menu screen. When the determination operation is performed while "date and time setting" is selected, the detail screen for setting the date and time is displayed on the effect display unit 200a. On the detail screen for setting the date and time, the date and time can be set in the game machine 100.

Similarly, when the determination operation is performed while "Power saving mode setting" is selected, the detailed screen for power saving mode setting is displayed on the effect display unit 200a, and various settings for power saving in the game machine 100 are possible. It becomes. Further, if the determination operation is performed while "Check board surface LED" is selected, it is possible to confirm the lighting of various LEDs provided on the game board 108. If the decision operation is performed while "End" is selected, the menu screen is closed.

On the other hand, "confirmation of setting change history" and "confirmation of error history" are displayed so as to be selectable only on the administrator menu screen. If the decision operation is performed while "Check setting change history" is selected, the setting change history information is displayed, and if the decision operation is performed while "Check error history" is selected, the error history information is displayed. Is displayed.

FIG. 58A is a diagram for explaining setting change history information, and FIG. 58B is a diagram for explaining error history information. When the determination operation is performed while "confirmation of setting change history" is selected on the administrator menu screen, the setting change history confirmation screen shown in FIG. 58A is displayed on the effect display unit 200a. On the setting change history confirmation screen, the date and time when the registered setting value is changed and the registered setting value after the change are displayed as the setting change history information. The sub RAM 330c of the sub control board 330 stores the setting change history information for the past 30 cases. When the registered setting value is further changed while the 30 setting change history information is stored, the oldest setting change history information is deleted and the new setting change history information is stored. By pressing the up button or the down button of the cross key 209 while the setting change history confirmation screen is displayed, all the setting change history information stored in the sub RAM 330c can be viewed.

Further, when the determination operation is performed while "error history confirmation" is selected on the administrator menu screen, the error history confirmation screen shown in FIG. 58 (b) is displayed on the effect display unit 200a. On the error history confirmation screen, the date and time when the error occurred and the type of the error are displayed as the error history information. The sub RAM 330c of the sub control board 330 stores error history information for the past 30 cases. If an error occurs further while 30 error history information is stored, the oldest error history information is deleted and new error history information is stored. By pressing the up button or the down button of the cross key 209 while the error history confirmation screen is displayed, all the error history information stored in the sub RAM 330c can be viewed.

Note that the sub-RAM 330c may store error history information for all the errors that have occurred, regardless of the type of error, or may store, for example, only some preset errors. Further, the errors include, for example, those detected by the main control board 300 such as a door opening error and a magnetic error, and those detected by the sub control board 330 such as a base abnormality. Here, both the error detected by the main control board 300 and the error detected by the sub control board 330 can be notified as error history information. However, for example, only one of the error detected by the main control board 300 and the error detected by the sub control board 330 may be notified.

Next, the processing of the sub-control board 330 related to viewing the above-mentioned setting change history information and error history information will be described.

(Sub CPU initialization process of sub control board 330)
FIG. 59 is a flowchart illustrating a sub CPU initialization process (S1000) of the sub control board 330.

(Step S1000-1)
When the power is turned on, the sub CPU 330a reads the CPU initialization processing program from the sub ROM 330b, and also initializes and sets the flags stored in the sub RAM 330c.

(Step S1000-3)
Next, the sub CPU 330a performs a process of updating each effect random number, and thereafter repeats the process of step S1000-3 until the interrupt process is performed. It should be noted that a plurality of types of effect random numbers are provided, and here, each effect random number is updated asynchronously.

(Subtimer interrupt processing of subcontrol board 330)
FIG. 60 is a flowchart illustrating subtimer interrupt processing (S1100) of the subcontrol board 330. The sub-control board 330 is provided with a reset clock pulse generation circuit (not shown) that generates a clock pulse at a predetermined cycle (30 times per second). Then, due to the generation of the clock pulse by the reset clock pulse generation circuit, the sub CPU 330a reads the timer interrupt processing program and starts the sub timer interrupt processing.

(Step S1100-1)
The sub CPU 330a saves the register.

(Step S1100-3)
The sub CPU 330a performs a process for permitting an interrupt.

(Step S1100-5)
The sub CPU 330a updates various timer counters used in the sub control board 330. Here, the various timer counters are subtracted by 1 each time the sub-timer interrupt processing of the sub-control board 330 is performed, and the subtraction is stopped when the value reaches 0, unless otherwise specified.

(Step S1200)
The sub CPU 330a analyzes the command received from the main control board 300 and performs command reception processing according to the received command. This command reception process will be described later with reference to FIG. 61.

(Step S1300)
The sub CPU 330a performs an operation input process that executes various processes in response to the operation input from the effect button 208 and the cross key 209. This operation input process will be described later.

(Step S1100-7)
The sub CPU 330a returns the register and ends the sub timer interrupt process.

FIG. 61 is a flowchart illustrating a command reception process on the sub-control board 330.

(Step S1210-1)
The sub CPU 330a determines whether or not the setting confirmation status specification command has been received. The setting confirmation status specification command is transmitted when the game machine status flag is set to 02H on the main control board 300. If it is determined that the setting confirmation status specification command has been received, the process is transferred to step S1210-3, and if it is determined that the setting confirmation status specification command has not been received, the process is transferred to step S1210-9.

(Step S1210-3)
The sub CPU 330a displays the setting confirmation screen on the effect display unit 200a.

(Step S1210-5)
The sub CPU 330a starts the dedicated lighting control of the predetermined effect lighting device 204, and starts outputting the dedicated sound from the sound output device 206. In the dedicated lighting control, for example, the predetermined effect lighting device 204 repeatedly blinks. Further, as the dedicated voice, for example, the message "setting is being confirmed" is repeatedly output from the voice output device 206.

(Step S1210-7)
The sub CPU 330a turns on the setting checking flag.

(Step S1210-9)
The sub CPU 330a determines whether or not the RAM clear designation command has been received. The RAM clear designation command is transmitted when the power is turned on while the RAM clear switch 182s is pressed and the predetermined area of the main RAM 300c is initialized. If it is determined that the RAM clear designation command has been received, the process is transferred to step S1210-11, and if it is determined that the RAM clear designation command has not been received, the process is transferred to step S1210-15.

(Step S1210-11)
The sub CPU 330a displays the standby screen on the effect display unit 200a.

(Step S1210-13)
The sub CPU 330a turns on the waiting flag.

(Step S1210-15)
The sub CPU 330a determines whether or not the set value designation command has been received. The set value designation command indicates the registered set value set on the main control board 300, and is transmitted when the power is turned on or when the setting is changed after the power is turned on. If it is determined that the set value designation command has been received, the process is transferred to step S1210-17, and if it is determined that the set value designation command has not been received, the process is transferred to step S1210-27.

(Step S1210-17)
The sub CPU 330a stores the set value information corresponding to the received set value designation command in the temporary storage area of the sub RAM 330c. The set value information corresponds to the registered set value set in the main control board 300. Therefore, in the sub-control board 330, the registered set value set in the main control board 300 is grasped by the set value information.

(Step S1210-19)
The sub CPU 330a loads the set value information stored in the main storage area of the sub RAM 330c.

(Step S1210-21)
The sub CPU 330a compares the set value information stored in the main storage area with the set value information stored in the temporary storage area, and determines whether or not the registered set value has been changed. As a result, if it is determined that the registered set value has been changed, the process is transferred to step S1210-23, and if it is determined that the registered set value has not been changed, the process is transferred to step S1210-27.

(Step S1210-23)
The sub CPU 330a acquires the current date and time from the RTC 330d.

(Step S1210-25)
The sub CPU 330a performs a setting information update process for updating various information related to the setting. Here, the set value information stored in the temporary storage area is overwritten in the main storage area, and the temporary storage area is cleared. Further, the date and time acquired in step S1210-23 and the set value information overwritten in the main storage area are stored in the sub RAM 330c as the setting change history information.

(Step S1210-27)
The sub CPU 330a determines whether or not the error designation command has been received. In the main control board 300, a door opening error, a magnetic error, a vibration error, etc. are determined in the state management process (FIG. 27), and an illegal winning error is determined in the specific area passing process (FIG. 34). An error designation command is provided for each type of error, and an error designation command corresponding to an error determined to have occurred on the main control board 300 is transmitted to the sub control board 330. If it is determined that the error specification command has been received, the process is transferred to step S1210-29, and if it is determined that the error specification command has not been received, the process is transferred to step S1210-35.

(Step S1210-29)
The sub CPU 330a acquires the current date and time from the RTC 330d.

(Step S1210-31)
The sub CPU 330a performs an error information update process for updating various information related to the error. Here, the date and time acquired in step S1210-29 and the error type corresponding to the received error specification command are stored in the sub RAM 330c as error history information.

(Step S1210-33)
The sub CPU 330a performs an error notification process for notifying the occurrence of an error.

(Step S1210-35)
The sub CPU 330a determines whether or not the setting-related end designation command has been received. The setting-related end designation command is transmitted to the sub-control board 330 when the setting of the registration setting value is completed on the main control board 300 (step S450-17 in FIG. 23). If it is determined that the setting-related end specification command has been received, the process is transferred to step S1210-37, and if it is determined that the setting-related end specification command has not been received, the process is transferred to step S1210-41.

(Step S1210-37)
The sub CPU 330a displays the initial screen on the effect display unit 200a.

(Step S1210-39)
The sub CPU 330a performs a reset process for resetting various information stored in the sub RAM 330c. For example, the above-mentioned setting confirmation flag and waiting flag are turned off by this reset process.

(Step S1210-41)
The sub CPU 330a determines whether or not the payout command has been received. The payout command is provided for each number of prize balls, and is transmitted from the main control board 300 to the sub control board 330 in the payout control management process (step S400-25 in FIG. 25) each time the prize balls are paid out. To. If it is determined that the payout command has been received, the process is transferred to step S1210-45, and if it is determined that the payout command has not been received, the process is transferred to step S1210-43.

(Step S1210-43)
The sub CPU 330a determines whether or not the out-ball detection designation command has been received. The out-ball detection designation command is transmitted from the main control board 300 to the sub-control board 330 each time the out-ball detection switch 130s detects a game ball (step S500-17 in FIG. 29). If it is determined that the out-ball detection designation command has been received, the process proceeds to step S1210-45, and if it is determined that the out-ball detection designation command has not been received, the command reception process is terminated.

(Step S1210-45)
The sub CPU 330a updates the base information. The base information is the ratio of the number of prize balls paid out to the number of balls launched by the game balls, and is updated every time the prize balls are paid out and every time the game balls are ejected from the game board 108. ..

(Step S1210-47)
The sub CPU 330a determines whether or not there is a base abnormality based on the base information updated in step S1210-45. Here, a threshold value is set for each progress of the game (for example, whether or not a major role game is being played), and when the base information per unit time exceeds the threshold value, it is determined that the base is abnormal. To. If it is determined that the base is abnormal, the process is moved to step S1210-49, and if it is determined that the base is not abnormal, the command reception process is terminated.

(Step S1210-49)
The sub CPU 330a performs an error information update process for updating the information related to the base abnormality error. Here, the date and time acquired from the RTC330d and the base abnormality error are associated with each other and stored in the sub RAM330c as error history information.

(Step S1210-51)
The sub CPU 330a performs an error notification process for notifying the occurrence of an error, and ends the command reception process.

FIG. 62 is a flowchart illustrating the above operation input process (S1300).

(Step S1300-1)
The sub CPU 330a determines whether the menu display operation is input from the cross key 209. As a result, if it is determined that the menu display operation has been input, the process is transferred to step S1300-3, and if it is determined that the menu display operation has not been input, the process is transferred to step S1300-17.

(Step S1300-3)
The sub CPU 330a determines whether or not the setting confirmation flag is on. As a result, if it is determined that the setting checking flag is on, the process is moved to step S1300-5, and if it is determined that the setting checking flag is not turned on, the process is moved to step S1300-11. ..

(Step S1300-5)
The sub CPU 330a displays the administrator menu screen on the effect display unit 200a.

(Step S1300-7)
The sub CPU 330a stops the output of the dedicated voice whose output is started when the display of the setting confirmation screen is started. That is, during the setting confirmation, the effect lighting device 204 and the audio output device 206 (plural output devices) perform dedicated output control, but when the administrator menu screen is displayed during the setting confirmation, the audio output device 206 Dedicated output control stops at (some output devices). In this way, when the work is performed according to the administrator menu, the output of the voice is stopped, so that the annoyance given to the worker can be reduced. It should be noted that the operation sound accompanying the operation of the administrator menu screen may be output.

(Step S1300-9)
The sub CPU 330a turns off the setting checking flag.

(Step S1300-11)
The sub CPU 330a determines whether the waiting flag is on. As a result, if it is determined that the waiting flag is on, the process is transferred to step S1300-13, and if it is determined that the waiting flag is not turned on, the process is transferred to step S1300-17.

(Step S1300-13)
The sub CPU 330a displays the staff menu screen on the effect display unit 200a. The output of the dedicated voice may be stopped in the same manner as when the administrator menu screen is displayed.

(Step S1300-15)
The sub CPU 330a turns off the waiting flag.

(Step S1300-17)
The sub CPU 330a determines whether or not the selection operation has been input. As a result, if it is determined that the selection operation has been input, the process is transferred to step S1300-19, and if it is determined that the selection operation has not been input, the process is transferred to step S1300-23.

(Step S1300-19)
The sub CPU 330a determines whether the menu screen (administrator menu screen and staff menu screen) is being displayed. As a result, if the menu screen is being displayed, the process is transferred to step S1300-21, and if the menu screen is not being displayed, the process is transferred to step S1300-23.

(Step S1300-21)
The sub CPU 330a switches the selected tab among the tabs displayed on the menu screen.

(Step S1300-23)
The sub CPU 330a determines whether the determination operation has been input. As a result, if it is determined that the determination operation has been input, the process is moved to step S1300-25, and if it is determined that the determination operation has not been input, the operation input process is terminated.

(Step S1300-25)
The sub CPU 330a determines whether the menu screen (administrator menu screen and staff menu screen) is being displayed. As a result, if the menu screen is being displayed, the process is moved to step S1300-27, and if the menu screen is not being displayed, the operation input process is terminated.

(Step S1300-27)
The sub CPU 330a displays the detail screen corresponding to the selected tab, and ends the operation input process.

Although the preferred embodiment of the present invention has been described above with reference to the accompanying drawings, it goes without saying that the present invention is not limited to such an embodiment. It is clear that a person skilled in the art can come up with various modifications or modifications within the scope of the claims, and it is understood that these also naturally belong to the technical scope of the present invention. Will be done.

The above-mentioned game characteristics, that is, the progress conditions of the game and various control methods are only examples. For example, the starting conditions for starting the big role lottery for determining whether or not the big role game can be executed, and the type, number, and contents of the big role game. Etc., the content of the game profit given to the player can be appropriately designed to the extent that the object of the present invention can be realized.

Further, in the above embodiment, the so-called type 2 mixed game machine has been described as an example, but it may be a type 1 game machine or a type 2 game machine.

Further, in the above embodiment, a switch for detecting whether or not the middle frame 104 is open is provided, and the gaming machine status flag is set to 01H (set) on condition that the middle frame 104 is open when the power is turned on. It can be set to (changed state) or 02H (setting confirmation state). Then, even if the closing of the middle frame 104 is detected while the game machine state flags are 01H and 02H, the game machine state flag may be maintained as it is without being changed.

Further, for example, after the setting confirmation state is completed with the middle frame 104 open, the voice output of the door opening is executed, and after the setting change state is completed with the middle frame 104 open, the door is opened. The audio output may not be performed. After changing the settings, it is necessary to perform processing that is not executed in the setting confirmation related to RAM clearing. Therefore, it is preferable to omit specific notification processing such as notification of door opening to reduce the processing load.

Further, in the above embodiment, as an example of the switch error to be detected, the case where the error related to the specific area detection switch 140s is detected in the specific area passing process (step S540) of the switch management process (step S500) is shown. , The present invention is not limited to this. For example, as switch errors for detection, further, general winning opening detection switch 118s, first starting opening detection switch 120s, second starting opening detection switch 122s, gate detection switch 124s, first major winning opening detection switch 126s, first An error (switch error) relating to the two major winning opening detection switches 128s, the effect switch 138s, and the out ball detection switch 130s may be detected. Further, whether or not to turn on the game machine error status flag may be different depending on the type of the detected switch error. For example, when an error related to the specific area detection switch 140s is detected, the game machine error status flag is turned on, while when an error related to a switch other than the specific area detection switch 140s is detected, the game machine error status flag is set. It may not be turned on.

Further, in the above embodiment, regardless of the flag value of the game machine status flag, an error determination is performed each time the timer interrupt process (step S400) is executed (sensor error), and the flag value of the game machine status flag is used. Although the case where the error determination is not performed (switch error) is provided based on the above is shown, all the error determinations may be performed regardless of the flag value of the game machine state flag. Alternatively, for a part of the switch error, the error may be determined every time the timer interrupt process is performed, regardless of the flag value of the game machine state flag. Alternatively, for a part of the sensor error, the error determination may not be performed based on the flag value of the game machine state flag.

Further, in the above embodiment, the case where the constantly movable body 144 is provided in the accessory device X is shown, but the present invention is not limited to this. That is, the present invention may be applied to the accessory device controlled by the main control board and the movable body controlled by the motor / solenoid in general.

Further, in the above embodiment, when the gaming machine status flag is set to 00H, a predetermined error (vibration error, magnetic error, or illegal winning error) is detected, and the gaming machine error status flag is turned on. In this case, the case where the game machine status flag is set to 06H is shown. On the other hand, if a predetermined error is detected when the game machine status flag is set to other than 00H, the game machine error status flag is turned on, but the game machine status flag is not set to 06H. showed that. However, the present invention is not limited to this. That is, at least, different processes may be executed when a predetermined error is detected depending on whether the game is set to the playable state or the game is not possible. Therefore, in the above embodiment, the case where different processes are executed on the main control board 300 is shown, but different processes may be executed on the sub control board 330. Specifically, for example, when the sub CPU 330a receives an error specification command when the game is set to the playable state, and when the sub CPU 330a receives the error specification command when the game is set to the non-game state. Then, the error history information may be displayed in an identifiable manner.

Further, in the above embodiment, the case where the movable body 144 is always operated by the main control board 300 is shown regardless of the flag value of the game machine state flag, but the present invention is not limited to this. For example, the sub-control board 330 may be controlled so that the effect accessory device 202 always operates in a predetermined manner (for example, the effect accessory device 202 always operates so as to swing up and down), and the game is possible and the game is not possible. It may be possible to perform a predetermined operation in both states. As a result, it is possible to confirm whether or not the effect accessory device 202 operates normally even in the non-gaming state.

Further, the effect accessory device 202 may be movable to a position where it overlaps with the effect display unit 200a, and when the effect accessory device 202 overlaps with the effect display unit 200a during the non-gaming state, the effect accessory device 202 It may be possible to perform the operation of returning to the initial position. As a result, it is possible to prevent the effect display unit 200a from obstructing the visibility of the effect display unit 200a when the effect display unit 200a notifies that the game is not possible. Further, during the non-game state, the effect accessory device 202 can only perform the return operation to the initial position, and other operations (initials for operating the effect accessory device 202 to the operating position and then returning to the initial position). By configuring the operation and the operation to be executed by the effect) so as not to be executed, it is possible to more effectively prevent the effect display unit 200a from being obstructed by the effect accessory device 202.

Further, the payout control board 310 can control the payout motor 314 even when the game is not possible, and may be able to pay out the remaining prize balls even if the game is not possible during the payout of the prize balls.

Further, in the above embodiment, the case where the determination of various errors is executed by the main control board 300 to which the abnormality detection sensor 174 is connected is shown, but the present invention is not limited to this. For example, the game machine 100 may be provided with a plurality of effect member units (movable bodies and decorative members) so as to be removable, and the sub-control board 330 is in both a playable state and a non-game state. It may be detected whether it is installed normally. Then, when the sub-control board 330 detects that the effect member unit is not normally attached while the game is possible, the installation error notification is executed, and the sub-control board 330 is the effect member unit while the game is not possible. If it is detected that is not normally installed, the notification that the game is not possible may be executed with priority, and the notification of the installation error may be executed after the transition to the game-enabled state.

Further, the payout control board 310 can detect a plurality of errors, and when an error is detected during the playable state, the payout control board 310 outputs output data for external information indicating that the error has occurred based on the detected error. The external information output process to be set or the error generation command transmission process for transmitting the error generation command that can identify the type of the error that has occurred to the main control board 300 may be executed. Then, the main control board 300 that has received the error generation command from the payout control board 310 transmits the error designation command to the sub control board 330, and the sub control board 330 that has received the error designation command from the main control board 300 has an error. An error notification process for notifying the occurrence may be executed. Further, the payout control board 310 can detect an error during the playable state and the non-game state, and when the occurrence of the error is detected during the non-game state, the error generation command is issued to the main control board. Even if it is configured so that the error occurrence command is transmitted to the main control board 300 after the game shifts to the playable state without transmitting to the 300, the notification that the game is not possible is prioritized. Good. Specifically, for example, an excess prize ball error (an error indicating that a predetermined number of balls have been paid out from the command from the main control board 300) and a ball jam error (a game ball is jammed in the payout unit that pays out the game ball). It is possible to detect an error indicating that (an error indicating that), a radio wave error (an error indicating that a radio wave has been detected), or the like by the payout control board 310.

In the above embodiment, the main CPU 300a that executes the processes of FIGS. 21, 26, and 28 corresponds to the state management means of the present invention.
Further, in the above embodiment, the case where the game machine state flag is 00H corresponds to the gameable state of the present invention, and the case where the game machine state flag is other than 00H in the above embodiment is the game impossible state of the present invention. Corresponds to.
Further, the abnormality detection sensor 174 in the above embodiment corresponds to the error detection means of the present invention. Further, the vibration error and the magnetic error in the above embodiment correspond to the predetermined error of the present invention.
Further, the main control board 300 in the above embodiment corresponds to the main control unit of the present invention.
Further, in the above embodiment, the main CPU 300a that executes the process of FIG. 26 corresponds to the setting changing unit of the present invention.
Further, in the above embodiment, the main CPU 300a that executes the process of step S400-39 of FIG. 25 corresponds to the setting confirmation unit of the present invention.
In the above embodiment, the sub CPU 330a that executes the process of step S1210-25 in FIG. 61 corresponds to the storage means of the present invention.

100 Game machine 174 Abnormality detection sensor 300 Main control board 300a Main CPU
300b main ROM
300c main RAM
330 Sub control board 330a Sub CPU
330b sub ROM
330c sub RAM

Claims (2)

A state management means for setting a playable state in which the player can play or a non-playable state in which the player cannot play,
An error detector that detects errors and
With
The error detection unit is a gaming machine capable of detecting the error even when the game is set to the non-gaming state by the state management means. Based on the input of the setting change operation, one of the setting values provided in multiple stages is set as the registered setting value. A main control unit including a setting confirmation unit that executes a setting confirmation process for displaying the registered setting value, and
A storage means for storing the history of the error detected by the error detection unit, and
With
The state management means makes the game impossible state when at least one of the setting change process and the setting confirmation process is executed in the main control unit.
The storage means is a case where at least one of the setting change process and the setting confirmation process is executed in the main control unit, and the error is detected by the error detection unit. However, the gaming machine according to claim 1, which stores the history of the error.

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