JP2019187746A - Game machine - Google Patents

Abstract

To improve a performance effect of a light emission performance.SOLUTION: A Pachinko machine 1 is configured so that, in execution of a first light emission control (light emission control on the basis of lamp scenario data 01 or lamp scenario data 02), the Pachinko machine can execute a second light emission control (light emission control on the basis of lamp scenario data 02) in which light emission blocks L1-L8 being operation objects are changed in a prescribed pattern. Especially, the second light emission control is configured to operate the light emission blocks L1-L8 being the operation objects, in a mode different from that of the first light emission control. Therefore, in operation of the plurality of the light emission blocks L1-L8 on the basis of the first light emission control, operation of some light emission blocks can be changed on the basis of the second light emission control.SELECTED DRAWING: Figure 45

Description

  The present invention relates to a gaming machine that executes a light emission effect by a light emitting means.

2. Description of the Related Art Conventionally, a gaming machine that executes a light emission effect by a light emitting means is known (see Patent Document 1).
This gaming machine includes a plurality of lamps (light emitting means) and sub-control means for controlling lighting of each lamp. The sub-control means is provided with lamp drive data storage means for storing drive data for each lamp. And lighting of each lamp is controlled based on the drive data stored in the lamp drive data storage means.

JP 2013-10047 A

However, in the conventional gaming machine, there is a risk that the effect of the light emission effect is reduced.
That is, in the conventional gaming machine, the expression of the light emission effect becomes monotonous, and the effect of the light emission effect may be reduced.
An object of the present invention is to improve the effect of producing a light emission effect.

In order to achieve the above object, a gaming machine according to a first aspect of the present invention comprises a plurality of light emitting blocks and a control means for controlling the operation of each light emitting block, and operates a plurality of light emitting blocks in a predetermined manner. During the execution of the one light emission control, the second light emission control is performed in which the light emission block to be operated of the plurality of light emission blocks changes in a predetermined pattern. It is characterized by operating in a mode different from the light emission control.
In the gaming machine according to the first aspect, during the execution of the first light emission control, the second light emission control in which the light emission block to be operated changes in a predetermined pattern is executed. In particular, in the second light emission control, the light emission block to be operated is operated in a mode different from the first light emission control.
Thereby, during the operation of the plurality of light emission blocks based on the first light emission control, the operation of some of the light emission blocks can be changed based on the second light emission control.
Therefore, as compared with the case where only the effect operation based on the first light emission control is executed, the expression of the light emission effect can be gorgeous and the effect of the light emission effect can be improved.
Here, the light emission blocks L1 to L8 described later correspond to the plurality of light emission blocks. The control means corresponds to an effect control circuit 300 and an LED driver 16a described later. The first light emission control corresponds to control based on “lamp scenario data 01” or “lamp scenario data 02” described later. The second light emission control corresponds to control based on “lamp scenario data 00” to be described later.

The gaming machine according to the second invention is the gaming machine according to the first invention, wherein the first light emission control and the second light emission control are executed based on the individual control data, and the second light emission control is the first light emission control. It is characterized by being executed with priority over control.
In the gaming machine according to the second invention, control data for executing the first light emission control and control data for executing the second light emission control are individually provided.
Accordingly, it is possible to execute an effect operation based on only one light emission control and an effect operation based on both light emission controls of the first light emission control and the second light emission control.
Therefore, it is possible to diversify the light emission effects while suppressing an increase in the amount of control data.

A gaming machine according to a third invention is the gaming machine according to the first or second invention, wherein the second light emission control is performed in the second mode after the light emitting block to be operated is operated in the first mode. It is characterized by operating.
In the gaming machine according to the third aspect of the invention, the effect operation based on the second light emission control can be conspicuous, and the effect effect of the light emission effect can be further improved.
Here, the mode which makes it light later mentioned corresponds as a 1st mode. As a 2nd aspect, the aspect turned off mentioned later corresponds.

A gaming machine according to a fourth aspect of the present invention is the gaming machine according to the third aspect of the present invention, wherein one of the first aspect and the second aspect is an aspect in which a light-emitting block to be operated is lit, The mode is characterized in that the light emitting block to be operated is turned off.
In the gaming machine according to the fourth aspect of the present invention, the brightness difference between the operation according to the first aspect and the operation according to the second aspect becomes large, and the effect operation based on the second light emission control can be made more conspicuous. Become.

  According to the present invention, it is possible to improve the effect of the light emission effect.

It is a perspective view which shows the whole structure of a pachinko machine. It is the figure which showed the front of a game board and showed typically the part required for description. It is a block diagram which shows the structure of the control system of a pachinko machine. 3 is an address map of a memory area used by a CPU 210. It is a flowchart which shows CPU initialization processing. It is a flowchart which shows a main loop process. It is a flowchart which shows the evacuation process at the time of power-off. It is a flowchart which shows a timer interruption process. It is a flowchart which shows a setting value management process. It is a flowchart which shows switch management processing. It is a flowchart which shows a usual start ball | bowl detection process. FIG. 2 is a flowchart showing a starting ball detection process. FIG. 2 is a flowchart showing a starting ball detection process. It is a flowchart which shows a special symbol random number acquisition process. It is a flowchart which shows a special game management process. It is a flowchart which shows a special figure fluctuation waiting process. It is a flowchart which shows a special figure change process. It is a flowchart which shows a special figure stop process. It is a flowchart which shows the big winning opening opening pre-processing. It is a flowchart which shows a special electric role opening / closing switching process. It is a flowchart which shows a big winning opening release control process. It is a flowchart which shows a big winning opening closing effective process. It is a flowchart which shows a big winning opening release end wait process. It is a flowchart which shows a normal game management process. It is a flowchart which shows a usual figure change waiting process. It is a flowchart which shows a process during usual figure change. It is a flowchart which shows a process during a usual figure stop. It is a flowchart which shows a normal electric accessory release pre-process. It is a flowchart which shows a normal electric role opening / closing switching process. It is a flowchart which shows a normal electric accessory release control process. It is a flowchart which shows a normal electric accessory closing effective process. It is a flowchart which shows a normal electric accessory release completion | finish weight process. It is a flowchart which shows a performance display apparatus control process. It is a flowchart which shows a base ratio calculation process. It is a flowchart which shows a sub timer interruption process. It is a flowchart which shows a command analysis process. It is a flowchart which shows a pending | holding command reception process. It is a flowchart which shows prefetch command reception processing. It is a flowchart which shows a fluctuation command reception process. It is a flowchart which shows a stop command reception process. It is a figure which shows an example of a lamp production scenario table. It is a figure which shows the content of "lamp scenario data 00". It is a figure which shows the content of "lamp scenario data 01". It is a figure which shows the content of "lamp scenario data 02". It is a figure which shows the content of the synthetic | combination data of "lamp scenario data 00" and "lamp scenario data 01". It is a figure which shows the content of the synthetic | combination data of "lamp scenario data 00" and "lamp scenario data 02". It is a figure which shows schematic structure of a board surface electrical decoration board | substrate.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In this embodiment, the gaming machine according to the present invention is applied to the pachinko machine 1.

(Overall configuration of pachinko machine 1)
First, the overall configuration of the pachinko machine 1 will be described.
FIG. 1 is a perspective view showing the overall configuration of the pachinko machine. The pachinko machine 1 includes an outer frame unit 2, an inner frame unit 3, an integrated door unit 4, and a game board unit 10.
The outer frame unit 2, the inner frame unit 3, and the integrated door unit 4 are fixed to each other via a hinge mechanism. Thereby, the inner frame unit 3 can be opened and closed with respect to the outer frame unit 2. The integrated door unit 4 can be opened and closed with respect to each of the inner frame unit 3 and the outer frame unit 2.
The outer frame unit 2 includes a rectangular frame (outer frame). And the outer frame with which the outer frame unit 2 is provided is fixed with respect to the island facility of a game arcade.
The inner frame unit 3 includes a rectangular frame (inner frame). The inner frame unit 3 is disposed inside the outer frame unit 2.
The integrated door unit 4 is formed in a rectangular door shape. The door unit 4 includes a transparent plate 4a disposed substantially at the center, a decorative portion 4b disposed around the transparent plate 4a, a tray unit 5 disposed below the transparent plate 4a, and a tray. And a firing handle 6 disposed on the side of the unit 5.
The transparent plate 4a is formed in a flat plate shape using a transparent material such as resin or glass. The decorative portion 4b is formed of a transparent or translucent resin material and has a shape that bulges forward. Each corner on the upper side of the decorative portion 4b is provided with a sound extraction portion 4c in which a sound generator (speaker) 22 (see FIG. 3) is disposed. Each sound extraction part 4c is provided with a plurality of sound extraction holes through which the sound output from the sound generator 22 passes. In addition, a frame lamp 20 (see FIG. 3) is disposed in the decorative portion 4b. The frame lamp 20 includes a plurality of light emitting elements (LEDs) driven by dynamic lighting control.

The tray unit 5 includes a tray 5a for receiving game balls (rental balls and prize balls), and an effect button 5b and a rotary selector 5c arranged on the front side of the tray 5a.
The effect button 5b is formed in a substantially cylindrical shape, and is disposed so as to protrude upward from the tray unit 5. The effect button 5b can be pressed by the player (pressed downward). Inside the saucer unit 5, a first operation detection switch 24 (see FIG. 3) for detecting a pressing operation of the effect button 5b is disposed. The first operation detection switch 24 outputs a first operation signal to the effect control circuit 300 (see FIG. 3) every time the effect button 5b is pressed.
The rotary selector 5c (so-called “jog dial”) is formed in a substantially cylindrical shape and is disposed so as to surround the effect button 5b. The rotary selector 5c can be rotated by a player (operation to rotate about a cylindrical axis). Inside the tray unit 5, a second operation detection switch 25 (see FIG. 3) for detecting the rotation operation of the rotary selector 5c is disposed. The second operation detection switch 25 outputs a second operation signal to the effect control circuit 300 every time the rotary selector 5c is rotated by a predetermined angle (for example, 60 [°]).

A lending operation unit 7 is disposed on the upper surface of the tray unit 5. The lending operation unit 7 includes a ball lending button 7a, a return button 7b, and a frequency display device 7c.
Here, the pachinko machine 1 is communicably connected to a CR unit 500 (see FIG. 3) capable of reading and updating information recorded on the prepaid card. When a prepaid card (not shown) is inserted into the CR unit 500, the remaining frequency of the valuable medium recorded on the prepaid card inserted into the CR unit 500 is displayed on the frequency display device 7c.
When the ball lending button 7a is operated with the prepaid card inserted in the CR unit 500, a predetermined number of game balls are paid out to the tray 5a. At this time, the remaining frequency of the valuable medium recorded on the prepaid card is updated according to the number of paid-out game balls, and the updated remaining frequency of the valuable medium is displayed on the frequency display device 7c.
Further, when the return button 7 b is operated in a state where the prepaid card having the remaining frequency of the valuable medium is inserted in the CR unit 500, the prepaid card is returned from the CR unit 500.
Here, the prepaid cart corresponds to, for example, a magnetic storage medium, a storage IC built-in medium, or the like.
The firing handle 6 can be rotated by the player. Inside the firing handle 6, a firing volume (not shown) for detecting the angle at which the firing handle 6 is rotated is disposed. The firing volume outputs a detection signal corresponding to the detected angle to the payout control circuit 400 (see FIG. 3).

(Configuration of the game board unit 10)
Next, the configuration of the game board unit 10 will be described.
FIG. 2 is a diagram showing a front side of the game board and schematically showing a part particularly necessary for explanation.
The game board unit 10 is supported by the inner frame unit 3. Specifically, the game board unit 10 is attached to the inner side of the inner frame included in the inner frame unit 3. Accordingly, the game board unit 10 is disposed on the back side of the integrated door unit 4. And the player can visually recognize the game board 11 (game area | region 30) mentioned later via the transparent board 4a. In the present embodiment, a game area 30 described later is formed between the back surface of the transparent plate 4 a and the front surface of the game board 11.
As shown in FIG. 2, the game board unit 10 includes a set board (not shown), a game board 11 attached to the set board, and various effect devices (main image display device 31, sub) attached to the set board. Image display device 32).
The set plate is formed in a box shape whose front side is open. An opening made of a through-hole is provided at a substantially central portion of the back plate of the set plate.
The game board 11 is attached to the front side of the set board. The game board 11 is formed in a flat plate shape with resin. An opening (not shown) made up of a through hole is provided at a substantially central portion of the game board 11. Then, the player can view the display screen 31a of the main image display device 31 through the opening provided in the game board 11 and the opening provided in the set board.
Around the opening in the front of the game board 11, a game area 30 is formed in which game balls launched according to the rotation operation of the launch handle 6 flow down. The game area 30 includes a left path formed on the left side of the main image display device 31 and a right path formed on the right side of the main image display device 31 as paths through which the game balls flow down. Yes.

A board surface lamp 21 (see FIG. 3) is disposed in the game area 30 of the game board 11. The panel lamp 21 includes a plurality of light emitting elements driven by static lighting control.
Specifically, the panel lamp 21 includes a plurality of (eight in the present embodiment) light-emitting blocks L1 to L8 (see FIG. 4).
Each of the light emitting blocks L1 to L8 includes one or a plurality of light emitting elements L. In this embodiment, a full color LED is used as each light emitting element L.
Each light emitting element L includes an LED element Lr capable of emitting light by “red (R)”, an LED element Lg capable of emitting light by “green (G)”, and an LED capable of emitting light by “blue (B)”. And an element Lb. Each light emitting element L can emit light with various colors and brightness by controlling gradation (PWM control) for each of the three LED elements Lr, Lg, and Lb.
In this embodiment, when viewed from the front side, the game area 30 is virtually divided into a predetermined number (eight in this embodiment) of areas (hereinafter referred to as “partition areas”). And the light emission block corresponding to each division area is provided. Each light emission block L1-L8 is provided in the back side of the division area corresponding to the said light emission block. And each light emission block is provided so that light can be irradiated with respect to the division area | region corresponding to the said light emission block. As a result, it is possible to execute an effect such that light is emitted from each light-emitting block so that substantially the entire divided area corresponding to the light-emitting block emits light.

For the eight light emitting blocks L1 to L8, the operation of the light emitting element L is controlled based on individual control information (specifically, luminance value information described later). Thus, the operation of the light emitting element L can be individually controlled for the eight light emitting blocks L1 to L8.
On the other hand, the operation of all the light emitting elements L included in each of the light emitting blocks L1 to L8 is controlled based on the same control information (specifically, luminance value information described later). Thereby, all the light emitting elements L included in the light emitting blocks L1 to L8 always have the same operation.
As described above, for example, by causing all the light emission blocks L1 to L8 to emit light (light on), it is possible to execute an effect in which substantially the entire game area 30 emits light. On the other hand, an effect that only a part of the game area 30 emits light is performed by causing some of the light emitting blocks L1 to L8 to emit light (light on) and stop the light emission of the remaining light emitting blocks (light off). It becomes possible to do. At this time, the light emission mode (brightness, color, etc.) of the light emitting element L can be varied for each light emitting block.

The main image display device 31 is attached to the back side of the set plate. The main image display device 31 includes a variable display device such as a liquid crystal display or a CRT (Cathode Ray Tube) display. The main image display device 31 has a display screen 31a capable of displaying effect images.
On the display screen 31a, three first effect symbols display areas a1 to a3 (not shown) in which a first effect symbol z1 (not shown) is displayed and a second effect symbol z2 (not shown) are displayed. It is possible to configure one second effect symbol display area a4 (not shown).
The 1st production design z1 is constituted including identification information (symbol), such as a number, a character, a symbol, and a character. In each of the first effect symbol display areas a1 to a3, it is possible to perform change display and stop display of the first effect symbol z1. The second effect design z2 is composed of color bars. In the second effect symbol display area a4, it is possible to perform change display and stop display of the second effect symbol z2.

The variation display of the effect symbols z1 and z2 means that the first effect symbol z1 is moved (scrolled) in the first effect symbol display areas a1 to a3 and is displayed in the second effect symbol display area a4. 2 A display in which the type of effect design z2 is changed (the color represented by the color bar is sequentially changed).
The stop display of the effect symbols z1 and z2 means that one kind of the first effect symbol z1 is stopped at the lottery result display positions of the first effect symbol display areas a1 to a3, and the second effect symbol display area a4. 1, a display in which one type of second effect design z2 is displayed (a color bar represents a predetermined color).
A special symbol is obtained by combining the first effect symbol z1 that is stopped and displayed in the three first effect symbol display areas a1 to a3 and the second effect symbol z2 that is stopped and displayed in the second effect symbol display area a4. The result of the lottery (the first special symbol lottery or the second special symbol lottery) is displayed.
In addition, the display screen 31a can be configured with reserved symbol display areas b1 and b2 (not shown) in which a reserved symbol h (not shown) is displayed.
In the holding symbol display area b1, a holding symbol h corresponding to the start information in the notification display (special symbol variation display and stop display) is displayed. In the hold symbol display area b2, a hold symbol h corresponding to the start information for which the notification display is held is displayed.

The sub image display device 32 is disposed at a position on the front side of the main image display device 31.
The sub image display device 32 is configured by a variable display device such as a liquid crystal display or a CRT display. The sub image display device 32 has a display screen 32a capable of displaying an effect image.
The sub image display device 32 can be displaced (moved) in the vertical direction by a drive mechanism (not shown). Specifically, the sub image display device 32 can be displaced within a predetermined range including an origin position (see FIG. 2) and an effect position (not shown) below the origin position. Yes.
The sub image display device 32 arranged (displaced) at the origin position is arranged above the display screen 31a of the main image display device 31 and does not cover the display screen 31a. On the other hand, the sub image display device 32 arranged (displaced) at the effect position is arranged on the front side of the display screen 31a of the main image display device 31, and covers a part of the display screen 31a.

A first start port 51 is provided below the display screen 31 a in the game area 30. The first start port 51 is a ball entrance that is open upward (so-called “nose”), and a game ball can be entered at all times. The first start port 51 is capable of entering a game ball that flows down the left path (cannot enter a game ball that flows down the right path).
A special FIG. 1 start port switch 101 (see FIG. 3) is disposed in the first start port 51. The special FIG. 1 start port switch 101 sends a detection signal to the main control circuit 200 in response to the detection of the game ball that has entered the first start port 51 (the game ball has entered the first start port 51). Output. The main control circuit 200 executes the first special symbol lottery in response to the detection signal input from the special figure 1 start port switch 101.
On the left side of the first starting port 51 in the game area 30, an upper left other winning port 55, a left middle other winning port 56, and a lower left other winning port 57 are provided. Each of the other winning holes 55 to 57 is a ball opening that opens upward, and game balls can always be entered. Each of the other winning prize openings 55 to 57 is capable of entering a game ball flowing down the left path (impossible to enter a game ball flowing down the right path).
The game board 11 is provided with a left prize opening switch 106 (see FIG. 3). The left winning port switch 106 is a game ball that has entered the upper left other winning port 55 (game ball entering the upper left other winning port 55), and a game ball that has entered the left middle other winning port 56 (other left left winning items). In response to the detection of a game ball that has entered the lower left other winning port 57 (the game ball has entered the lower left other winning port 57). 200 is output. The main control circuit 200 causes the game ball payout device 440 to execute the payout operation of the prize ball in response to the input of the detection signal from the left winning port switch 106.

A start gate 41 is provided on the right side of the display screen 31 a in the game area 30. The start gate 41 is formed so that it can always be passed by a game ball. The start gate 41 is capable of passing a game ball flowing down the right route (impossible to pass a game ball flowing down the left route).
The start gate 41 is provided with a gate switch 104 (see FIG. 3). The gate switch 104 outputs a detection signal to the main control circuit 200 in response to detection of a game ball passing through the start gate 41 (passing of the start gate 41 by the game ball). The main control circuit 200 executes the normal symbol lottery in response to the detection signal input from the gate switch 104.
Below the start gate 41 in the game area 30, a big prize opening 53 is provided. The grand prize opening 53 is displaced between a closed state in which gaming balls cannot enter the grand prize opening 53 and an open state in which gaming balls can enter the grand prize opening 53. A special electric combination (special electric combination) 53a (so-called “attacker”) is provided.
The special electric accessory 53a is opened and closed by a special prize opening solenoid 65 (see FIG. 3). The special winning opening 53 is normally closed with the special electric accessory 53a closed, so that it is impossible to enter a game ball, but the first special symbol lottery or the second special symbol lottery is won. Thus, when the big hit gaming state occurs, the special electric accessory 53a is opened, and the game ball can be entered. The big prize opening 53 is capable of entering a game ball flowing down the right path (cannot enter a game ball flowing down the left path).
A count switch 103 (see FIG. 3) is disposed in the big prize opening 53. The count switch 103 outputs a detection signal to the main control circuit 200 in response to the detection of a game ball that has entered the grand prize opening 53 (a game ball that has entered the big prize opening 53). The main control circuit 200 causes the game ball payout device 440 to perform a prize ball payout operation in response to an input of a detection signal from the count switch 103.

A second start port 52 is provided below the special winning port 53 in the game area 30. The second start port 52 includes a closed state in which a game ball cannot enter the second start port 52 and an open state in which a game ball can enter the second start port 52. An ordinary electric combination (ordinary electric combination) 52a (so-called “electric tulip”) that can be displaced is provided.
The ordinary electric accessory 52a is opened and closed by an ordinary electric accessory solenoid 64 (see FIG. 3). The second starting port 52 is normally closed with the ordinary electric accessory 52a closed, so that it is impossible to enter a game ball. However, when the normal symbol lottery is won, 52a is opened, and a game ball can be entered. The second starting port 52 can enter a game ball flowing down the right path (cannot enter a game ball flowing down the left path).
In the second start port 52, a special FIG. 2 start port switch 102 (see FIG. 3) is disposed. The special figure 2 start port switch 102 sends a detection signal to the main control circuit 200 in response to the detection of the game ball that has entered the second start port 52 (the game ball has entered the second start port 52). Output. The main control circuit 200 executes the second special symbol lottery in response to the input of the detection signal from the special figure 2 start port switch 102.
A right other winning port 54 is provided below the second starting port 52 in the game area 30. The other right winning port 54 is a ball opening that opens upward, and a game ball can be always entered. The right other winning port 54 is capable of entering a game ball flowing down the right path (cannot enter a game ball flowing down the left path).
In the other right winning opening 54, a right winning opening switch 105 (see FIG. 3) is arranged. The right winning port switch 105 outputs a detection signal to the main control circuit 200 in response to detection of a game ball that has entered the right other winning port 54 (a game ball that has entered the right other winning port 54). . The main control circuit 200 causes the game ball payout device 440 to execute the payout operation of the prize ball in response to the input of the detection signal from the right prize opening switch 105.

At the lowermost position in the game area 30, an out port 58 is provided for discharging game balls that have not entered (winned) any of the winning ports 51 to 57.
Here, the inner frame unit 3 includes a discharge path (not shown) through which game balls discharged from the game area 30 pass. Specifically, the discharge path is attached to the back side of the inner frame provided in the inner frame unit 3. The pachinko machine 1 is configured so that all game balls launched into the game area 30 (all game balls discharged from the game area 30) pass through the discharge path. That is, the game ball launched into the game area 30 is discharged from the game area 30 by entering any of the winning holes 51 to 57 or passing through the out-port 58 and flows into the discharge path. To do.
Specifically, game balls that have entered the winning holes 51 to 57 are detected by the switches 101 to 103, 106, and 106 disposed in the winning holes, and then guided to the discharge path. In addition, the game ball discharged from the out port 58 is guided to the discharge path.
The inner frame unit 3 is provided with an out switch 109 (see FIG. 3). The out switch 109 outputs a detection signal to the main control circuit 200 in response to detection of a game ball passing through the discharge path (game ball discharged from the game area 30). As a result, all game balls discharged from the game area 30 are detected by the out switch 109.
Further, a plurality of nails (not shown) are arranged in the game area 30 so as to guide the game balls to the winning ports 51 to 57 and the start gate 41.

A main display 60 is disposed on the game board 11. The main display 60 includes a plurality of lighting elements (segments). Each lighting element is configured by a light emitting element (in the present embodiment, an LED).
Information relating to the game is displayed on the main display 60. That is, the main display 60 includes a special figure 1 display apparatus, a special figure 2 display apparatus, a universal figure display apparatus, and a status display apparatus.
Specifically, the main display 60 includes 32 lighting elements (LED1 to LED32). And in the main display 60, LED1-LED8 becomes a special figure 1 display apparatus, LED7-LED16 becomes a special figure 2 display apparatus, LED17-LED24 becomes a common figure display apparatus, and LED25-LED32 shows a status display. It is a device.
The special figure 1 display device can perform change display and stop display of the first special symbol made up of numbers, symbols and the like. And in the special figure 1 display apparatus, the result of the 1st special symbol lottery is displayed by the 1st special symbol stopped and displayed.
The special figure 2 display device can perform change display and stop display of the second special symbol made up of numbers, symbols and the like. And in the special figure 2 display apparatus, the result of the 2nd special symbol lottery is displayed by the 2nd special symbol stopped and displayed.
Here, the display of the special symbol (the first special symbol or the second special symbol) in the special symbol display device and the display of the effect symbols z1 and z2 in the effect symbol display areas a1 to a4 are the time when the variable display is started. The time when the stop display is started and the lottery result indicated by the stopped and displayed symbols are associated with each other.
When the first special symbol (stop symbol) stopped and displayed on the special figure 1 display device becomes a specific symbol (big hit symbol), or the second special symbol (stopped on the special symbol 2 display device) When the stop symbol) becomes a specific symbol (a jackpot symbol), a jackpot gaming state that is a gaming state advantageous to the player is generated.
The general-purpose display device can perform a change display and a stop display of normal symbols made up of numbers, symbols, and the like. Then, the normal symbol display device displays the result of the normal symbol lottery according to the stopped normal symbol. Then, when the normal symbol stopped and displayed on the general diagram display device becomes a specific symbol (per symbol per symbol), a game state per symbol which is a game state advantageous to the player is generated.
In the status display device, the number of times the display of the lottery result of the first special symbol lottery is suspended (special figure 1 number of suspensions), the number of times the display of the lottery result of the second special symbol lottery is suspended (special figure 2) Number of holds), the number of times that the display of the lottery result of the normal symbol lottery is held (ordinary number of holds), the type of jackpot gaming state (number of round games executed), instructions for launching game balls to the right path, etc. Is displayed.

The pachinko machine 1 is provided with detection sensors for detecting various abnormal states.
In this embodiment, a glass frame opening sensor 107, an inner frame opening sensor 108, a vibration detection sensor 113, a radio wave detection sensor 114, a magnetic detection sensor 115, and the like are arranged as detection sensors.
The glass frame opening sensor 107 detects the opening of the integrated door unit 4 with respect to the inner frame unit 3. The glass frame opening sensor 107 transmits a detection signal (glass frame opening signal) to the main control circuit 200 in response to the opening of the integrated door unit 4 with respect to the inner frame unit 3.
The inner frame opening sensor 108 detects the opening of the inner frame unit 3 with respect to the outer frame unit 2. The inner frame opening sensor 108 transmits a detection signal (an inner frame opening signal) to the main control circuit 200 in response to the opening of the inner frame unit 3 with respect to the outer frame unit 2.
The vibration detection sensor 113 detects the vibration of the game board 11. In the present embodiment, the vibration detection sensor 113 is disposed on the game board 11. Then, the vibration detection sensor 113 transmits a detection signal (board surface vibration detection sensor signal) to the main control circuit 200 in response to detection of vibration of the game board 11.
The radio wave detection sensor 114 detects radio waves generated around the game board 11. In the present embodiment, two radio wave detection sensors 114 are arranged in the game board 11. Each radio wave detection sensor 114 transmits a detection signal (panel radio wave detection sensor signal 1, panel radio wave detection sensor signal 2) to the main control circuit 200 in response to the detection of the radio wave.
The magnetic detection sensor 115 detects magnetism generated around the game board 11. In the present embodiment, three magnetic detection sensors 115 are provided. Specifically, one magnetic detection sensor 115 is disposed in the inner frame unit 3 (discharge path). In the game board 11, two magnetic detection sensors 115 are provided. The magnetic detection sensor 115 disposed in the inner frame unit 3 transmits a detection signal (out-port magnetic detection sensor signal) to the main control circuit 200 in response to the detection of magnetism. In addition, each magnetic detection sensor 115 disposed on the game board 11 sends a detection signal (panel magnetic detection sensor signal 1, panel magnetic detection sensor signal 2) to the main control circuit 200 in response to the detection of magnetism. To send.

(Control system configuration)
Next, the configuration of the control system in the pachinko machine 1 will be described.
FIG. 3 is a block diagram showing the configuration of the control system of the pachinko machine. FIG. 4 is an address map of the memory area used by the CPU 210.
The pachinko machine 1 includes various control circuits.
Specifically, as shown in FIG. 3, the pachinko machine 1 supplies power (electric power) to the main control circuit 200, the effect control circuit 300, the payout control circuit 400, the control circuits 200, 300, 400, and the like. And a power supply circuit 600 to be supplied.
Each control circuit 200, 300, 400 includes a CPU (Central Processing Unit), a ROM (Read Only Memory) that stores a program related to the progress of the game and data necessary for the progress of the game, and a CPU that is stored in the ROM. And a RAM (Random Access Memory), which is a temporary storage area used for proceeding with processing based on a program.

The main control circuit 200 is mounted on a main control board (not shown). The main control circuit 200 includes a CPU 210, a ROM 220, a RAM 230, an input port 240, an output port 250, a frequency generation circuit 260, and a hard random number generation circuit 270.
The input port 240 includes a plurality of input ports (in this embodiment, input port 0 to input port 3).

The input port 0 includes a detection signal from the glass frame opening sensor 107 (glass frame opening signal), a detection signal from the inner frame opening sensor 108 (inner frame opening signal), and a detection signal from the vibration detection sensor 113 (board surface vibration detection). Sensor signal), detection signal from one radio wave detection sensor 114 (panel surface radio wave detection sensor signal 2), detection signal from three magnetic detection sensors 115 (out mouth magnetic field detection sensor signal, panel surface magnetic field detection sensor signal 1, panel surface magnetic field) Detection sensor signal 2) and the like are input.
The input port 1 receives a RAM clear signal from the RAM clear switch, a detection signal (not shown) from the key rotation detection switch 111, a detection signal (not shown) from the set value selection switch, and the like.
The input port 2 has a detection signal from the count switch 103, a detection signal from the right prize opening switch 105, a detection signal from the left prize opening switch 106, a detection signal from the out switch 109, and a signal from the other radio wave detection sensor 114. A detection signal (board surface radio wave detection sensor signal 1) or the like is input.
The input port 3 receives a detection signal from the special figure 1 start port switch 101, a detection signal from the special figure 2 start port switch 102, a detection signal from the gate switch 104, and the like.
Each input port (input port 0 to input port 3) is provided with a reception storage area corresponding to each signal (each detection sensor). In each reception storage area, 1-bit data indicating a reception state of a signal corresponding to the reception storage area is set.
Specifically, each reception storage area is set to “1” when a signal corresponding to the reception storage area is input, and when a signal corresponding to the reception storage area is not input, “0” is set.

The output port 250 includes a plurality of output ports (in this embodiment, output port 0 to output port 4).
The output port 0 outputs a data signal (“SEGDATA0” to “SEGDATA7”) for controlling lighting of the main display 60. The data signal output from the output port 0 is input to a source driver (not shown) described later.
The output port 1 outputs common signals (“COM0” to “COM3”) for controlling lighting of the main display 60 and the performance display device 61. The common signal output from the output port 1 is input to a sink driver (not shown) described later.
The output port 2 outputs external signals (OUT1 to OUT6, OUT8). An external signal output from the output port 2 is input to the hall computer 450 via an external terminal board (not shown).

The output port 3 outputs a control signal for controlling the driving of the ordinary electric accessory solenoid 64, a control signal for controlling the driving of the special prize opening solenoid 65, and the like. Each control signal output from the output port 3 is input to the solenoids 64 and 65.
The output port 4 outputs a data signal (“7SEGDATA0” to “7SEGDATA7”) for controlling the lighting of the performance display device 61. The data signal output from the output port 4 is input to a source driver (not shown) described later.

The main control circuit 200 includes a command output port 1 and a command output port 2. Then, the CPU 210 transmits a control command (subcommand transmission signal) from the command output port 1 to the effect control circuit 300, and transmits a control command (payout command transmission) from the command output port 2 to the payout control circuit 400. Signal).
The command output port 1 and the command output port 2 are respectively a transmission data register (not shown), a FIFO (First In First Out) buffer (not shown), a transmission shift register (not shown), have.
The transmission data register outputs a control command input based on a subcommand transmission process (step S2-4), which will be described later, to the FIFO buffer.
The FIFO buffer is composed of a plurality of registers, and can store a plurality of control commands. The FIFO buffer stores the control command input from the transmission data register and outputs the stored control command to the transmission shift register in the input order.
The transmission shift register performs parallel-serial conversion on the control command input from the FIFO buffer, and transmits it to the effect control circuit 300 or the payout control circuit 400 as serial data.

Further, a test signal output circuit is mounted on the main control board.
In the test signal management process (step S4-18) described later, the CPU 210 generates test information (test signal) indicating an internal state (such as a big hit gaming state, an execution state of time reduction control, a special symbol lottery probability state). The generated test signal is stored in the port output request buffer of the RAM 230. As a result, the test signal stored in the port output request buffer is output from a predetermined output port.
A test signal output from a predetermined output port is input to an interface board of a test computer (not shown) through a test signal output circuit (not shown).
Also, a detection signal from the special figure 1 start opening switch 101, a detection signal from the special figure 2 start opening switch 102, a detection signal from the gate switch 104, a detection signal from the count switch 103, and a detection from the right winning opening switch 105 A signal, a detection signal from the left winning opening switch 106, a detection signal from the out switch 109, and the like are input to the input port 240 and input to the interface board of the test computer via the test signal output circuit. .
Further, a control signal for controlling driving of each solenoid (normal electric accessory solenoid 64, big prize opening solenoid 65, etc.) output from the output port 3 is input to each solenoid 64, 65 and a test signal. It is input to the interface board of the test computer via the output circuit.

The main control circuit 200 includes a memory area used by the CPU 210. As shown in FIG. 4, the memory area used by the CPU 210 includes a memory area (0000H to 2FFFH) assigned to the ROM 220 and a memory area (F000H to F3FFH) assigned to the RAM 230. .
Here, in FIG. 4, the address for specifying the memory area is shown in hexadecimal (“H” indicates that it is hexadecimal).

The ROM 220 (memory area of the ROM 220) is provided with a use area m1 (0000H to 1A7AH) and a non-use area m2 (2000H to 2BFFH).
In the use area m1, a program and data for controlling the progress of the game are stored (stored).
The non-use area m2 includes a program and data for executing processing related to a test defined by the gaming machine rules, and a program and data for controlling display of the performance display device 61 (a program for calculating a base ratio described later) And data) are stored (stored).
The use area m1 includes a program area (0000H to 0A89H), an unused area (0A8AH to 0FFFH), and a data area (1000H to 1A7AH). In the program area, a program for controlling the progress of the game is stored. On the other hand, data for controlling the progress of the game is stored in the data area. The used area m1 may be configured without including an unused area.
In the non-use area m2, a program area (2000H to 27FFH) and a data area (2800H to 2BFFH) are provided. The program area stores a program for executing a process related to a test determined by the gaming machine rules and a program for controlling display on the performance display device 61. On the other hand, the data area stores data for executing processing related to the test determined by the gaming machine rules and data for controlling the display of the performance display device 61.
In addition to the use area m1 and the non-use area m2, the ROM 220 includes an unused area (1A7BH to 1DFFH), a ROM comment area (1E00H to 1EFFH), a program management area (2FC0H to 2FFFH), and the like. Yes.
Arbitrary data such as the title and version of the program is stored in the ROM comment area. On the other hand, the program management area stores information necessary for the CPU 210 to execute various programs.
In the ROM 220, an unused area m3 of a predetermined byte (for example, 4 bytes or more) is provided between the use area m1 and the non-use area m2. Thereby, the boundary between the use area m1 and the non-use area m2 is clarified.

The RAM 230 (memory area of the RAM 230) is provided with a use area M1 (F000H to F1FFH) and a non-use area M2 (F210H to F228H).
The use area M1 is used when executing a process based on a program (a program for controlling the progress of the game) stored in the use area m1. In other words, in the use area M1, various data are temporarily stored when executing the processing based on the program (program for controlling the progress of the game) stored in the use area m1.
The out-of-use area M2 is a process based on a program stored in the out-of-use area m2 (a program for executing a process related to a test defined by the gaming machine rules or a program for controlling display of the performance display device 61). Used when executing That is, in the non-use area M2, a program stored in the non-use area m2 (a program for executing a process related to a test determined by the gaming machine rules or a program for controlling the display of the performance display device 61) When executing the processing based on the above, various data are temporarily stored.
Specifically, in the use area M1, input / output data in the main control circuit 200, data for arithmetic processing, various counters (random number counter, timer counter, etc.), flags for managing lottery results and gaming states, etc. are temporarily stored. Memorized. In particular, the use area M1 is an area for storing start information acquired in response to input of detection signals from each of the special figure 1 start opening switch 101, the special figure 2 start opening switch 102, and the gate switch 104 ( A starting information storage area (to be described later) is provided.
The use area M1 is provided with a work area (F000H to F12AH), an unused area (F12BH to F1D7H), and a stack area (F1D8H to F1FFH). The work area is used as an area for temporarily storing various data during execution of the program (program for controlling the progress of the game) stored in the use area m1. On the other hand, the stack area is used as an area for temporarily saving various data during execution of a program (a program for controlling the progress of the game) stored in the use area m1. The used area M1 may be configured without including an unused area.
The non-use area M2 is provided with a work area (F210H to F21FH) and a stack area (F220H to F228H). The work area is executing a program stored in the non-use area m2 (a program for executing a process related to a test determined by the gaming machine rules or a program for controlling display of the performance display device 61). In addition, it is used as an area for temporarily storing various data. On the other hand, the stack area is executing a program stored in the non-use area m2 (a program for executing a process related to a test determined by the gaming machine rules or a program for controlling display of the performance display device 61). In addition, it is used as an area for temporarily saving various data.
Further, the RAM 230 is provided with an unused area M3 of a predetermined byte (4 bytes or more) between the use area M1 and the non-use area M2. Thereby, the boundary between the use area M1 and the non-use area M2 is clarified.

In particular, in the present embodiment, in processing based on a program (program for controlling the progress of a game) stored in the use area m1, it is permitted to refer to data stored in the non-use area M2. Yes.
On the other hand, it is prohibited to rewrite (change) the data stored in the non-use area M2 by the processing based on the program (program for controlling the progress of the game) stored in the use area m1. Yes.
Further, in a process based on a program stored in the non-use area m2 (a program for executing a process related to a test determined by the gaming machine rules or a program for controlling the display of the performance display device 61), the use area It is permitted to refer to the data stored in M1.
On the other hand, the area used by the process based on the program stored in the non-use area m2 (the program for executing the process related to the test defined by the gaming machine rules or the program for controlling the display of the performance display device 61) It is prohibited to rewrite (change) the data stored in M1.
The game in the pachinko machine 1 can be advanced (completed) by a program (a program for controlling the progress of the game) stored in the use area m1.

The frequency generation circuit 260 generates a clock (synchronization signal) at a predetermined clock frequency (12 [MHz] in this embodiment), and outputs this clock to each of the CPU 210 and the hard random number generation circuit 270.
A hard random number generation circuit 270 generates a first loop counter that generates a random number for a normal symbol lottery, a second loop counter that generates a big random number for a first special symbol lottery, and a big hit random number for a second special symbol lottery. The third loop counter includes a fourth loop counter that generates a reach group random number.
Each time one clock is input from the frequency generation circuit 260, the first loop counter updates the value of the loop counter within a predetermined range (in the present embodiment, within the range of 0 to 65535) by one, A random number is generated per normal symbol lottery. In the present embodiment, the value of the first loop counter is updated every 0.083 [μs] (1 [s] / 12 [MHz] = 0.083 [μs]).
Each time one clock is input from the frequency generation circuit 260, the second loop counter updates the value of the loop counter one by one within a predetermined range (in the range of 0 to 65535 in this embodiment). A big hit random number of the first special symbol lottery is generated. In the present embodiment, the value of the second loop counter is updated every 0.083 [μs] (1 [s] / 12 [MHz] = 0.083 [μs]).
Each time one clock is input from the frequency generation circuit 260, the third loop counter updates the value of the loop counter one by one within a predetermined range (in the range of 0 to 65535 in this embodiment). A big hit random number of the second special symbol lottery is generated. In the present embodiment, the value of the third loop counter is updated every 0.083 [μs] (1 [s] / 12 [MHz] = 0.083 [μs]).
Each time 32 clocks are input from the frequency generation circuit 260 (once every time the clock frequency is divided by 32), the fourth loop counter sets the value of the loop counter within a predetermined range (in this embodiment, 0 to 10006). Reach group random numbers are generated by updating one by one in the range. In the present embodiment, the value of the fourth loop counter is updated every 2.666 [μs] (32 [s] / 12 [MHz] = 2.666 [μs]).

The main control board is provided with a set value operation unit (not shown). The set value operation unit includes a key rotation detection switch 111, a set value selection switch 112, and a set value display device 62.
The key rotation detection switch 111 has an operation unit that can be switched between a setting permission state and a setting prohibition state. The key rotation detection switch 111 outputs a detection signal to the main control circuit 200 when the operation unit is switched to the setting permission state. On the other hand, the key rotation detection switch 111 stops outputting the detection signal to the main control circuit 200 when the operation unit is switched to the setting prohibited state.
In the present embodiment, a keyhole into which a dedicated key is inserted is provided in the operation unit of the key rotation detection switch 111. In the key rotation detection switch 111, the state of the operation unit (setting permitted state or setting prohibited state) can be switched by inserting a dedicated key into the keyhole. That is, in the key rotation detection switch 111, the state of the operation unit (setting permission state or setting prohibition state) cannot be switched unless a dedicated key is inserted into the keyhole.
Further, in the key rotation detection switch 111, it is possible to insert a dedicated key into the keyhole when the operation unit is in a setting prohibited state, and it is possible to remove the dedicated key from the keyhole. On the other hand, with the key rotation detection switch 111, it is impossible to insert a dedicated key into the keyhole when the operation unit is in a setting-permitted state, and it is impossible to remove the dedicated key from the keyhole. Become.
The set value selection switch 112 has an operation unit that can be pressed. The set value selection switch 112 outputs a detection signal to the main control circuit 200 every time the operation unit is pressed.
The set value display device 62 is configured by a 7-segment LED or the like. The set value display device 62 displays a set value to be described later. The set value display device 62 is arranged on the back side of the game board 11 so that it cannot be viewed by the player.

Here, setting information (setting value) set in the pachinko machine 1 will be described.
The “setting information” is information for designating the winning probability (probability of winning the big hit gaming state) of the special symbol lottery (the first special symbol lottery and the second special symbol lottery).
The RAM of the main control circuit 200 is provided with a setting information storage area. In the setting information storage area, any one of “1” to “6” is set (stored) as setting information. And in the pachinko machine 1, the winning probability of the special symbol lottery is set to a probability according to the value set in the setting information storage area.
In the following description, a value stored in the setting information storage area is referred to as a “setting value”.
In the present embodiment, the winning probability of the special symbol lottery corresponding to each setting value is the winning probability corresponding to the setting value = “6” and the winning probability corresponding to the setting value = “5” in descending order of winning probability , Winning probability corresponding to setting value = “4”, winning probability corresponding to setting value = “3”, winning probability corresponding to setting value = “2”, winning probability corresponding to setting value = “1” (winning Probability “high” → winning probability “low”).

In particular, in the pachinko machine 1, the set value can be changed (selected) when the power is turned on. Here, the change of the set value is executed by an administrator of the pachinko machine 1 (such as an employee of a game hall where the pachinko machine 1 is installed).
In the pachinko machine 1, the set value change permission state is started in response to the power being turned on while the operation unit of the key rotation detection switch 111 is displaced to the setting permission state.
During the setting value change permission state, the setting value display device 62 displays a value indicating a value (setting value) set in the setting information storage area.
In the setting value change permission state, each time the setting value selection switch 112 is pressed, the value (setting value) set in the setting information storage area is changed. At this time, when the value (set value) set in the setting information storage area is changed, the value (value indicating the set value) displayed on the set value display device 62 is also changed accordingly. Be changed.
As a result, the administrator of the pachinko machine 1 sets a desired value among “1” to “6” as the setting value by pressing the setting value selection switch 112 while the setting value change permission state is set. (Select).
Then, in the pachinko machine 1, the setting value change permission state is terminated in response to the operation unit of the key rotation detection switch 111 being switched from the setting permission state to the setting prohibition state. This makes it impossible to change the value (setting value) set in the setting information storage area. Further, in accordance with the end of the set value change permission state, the display of the value indicating the set value on the set value display device 62 is ended.

In addition, a performance display device 61 is provided on the main control board. The performance display device 61 is arranged on the back side of the game board 11 so that it cannot be viewed by the player.
The performance display device 61 includes a plurality of lighting elements (segments). Each lighting element is configured by a light emitting element (in the present embodiment, an LED).
In the performance display device 61, the number of game balls launched into the game area 30 and a predetermined entrance (in this embodiment, the first start port 51, the second start port 52, and other winning ports 54 to 57). Information (base ratio described later) calculated based on the number of prize balls paid out in accordance with the entry of game balls into the game is displayed.
The performance display device 61 includes four (four digits) display units (not shown). Each display unit is composed of eight lighting elements. That is, each display unit is composed of a 7-segment LED that can display numbers, symbols, and the like, and a dot-segment LED that can display dots such as a decimal point.
Specifically, the performance display device 61 includes 32 lighting elements (LED33 to LED64). In the performance display device 61, the LEDs 33 to 40 are the first digit display unit, the LED 41 to LED48 are the second digit display unit, the LED 49 to LED56 are the third digit display unit, and the LED 57 to LED64. Is the fourth digit display.
The main control circuit 200 calculates a base ratio, which will be described later, during the occurrence of a predetermined gaming state (in this embodiment, during the occurrence of the special figure low probability state and during the stop of the short-time control). Then, the calculated base ratio is displayed on the performance display device 61.
“Base ratio” is the ratio (percentage) of the number of payouts to the number of outballs. The main control circuit 200 calculates a base ratio for each predetermined section (period).
In the present embodiment, a section in which a predetermined number (60000 [sphere] in this embodiment) of out balls is detected (discharged) is defined as the predetermined section. That is, each section starts in response to the end of the previous section, and ends in response to the number of out balls detected in the current section reaching a predetermined number (60000 [sphere]). The main control circuit 200 calculates the base ratio at any time (in real time) during each section.
Here, a predetermined time may be defined as the predetermined section. That is, the main control circuit 200 may be configured to calculate the base ratio for each predetermined time.
“Number of out balls” refers to the number of out balls. “Out ball” refers to a game ball discharged from the game area 30. In the present embodiment, the out ball refers to a game ball (game ball detected by the out switch 109) that has passed through the discharge path.
Here, the game ball discharged from the out port 58 may be an out ball. Specifically, the out switch 109 may be configured to detect only the game balls discharged from the out port 58, and the game balls detected by the out switch 109 may be set as the out balls.
The “number of payouts” refers to the total number of winning balls paid out according to the number of game balls that have entered the first starting port 51, the second starting port 52, and the other winning ports 54 to 57.
The performance display device 61 alternately displays the first base ratio and the second base ratio every predetermined time (5.0 [s] in the present embodiment).
The “first base ratio” is the base ratio of the current section (the base ratio calculated for the period from the start of the current section to the current time).
The “second base ratio” is the base ratio of the previous section (the final base ratio calculated for the previous section).
Specifically, in the performance display device 61, information for identifying the type of the base ratio (first base ratio or second base ratio) by the upper two-digit display section of the four-digit display section. Is displayed. In the performance display device 61, the base ratio (percentage) is displayed by the lower two digits of the four digits display.

The effect control circuit 300 is mounted on a sub control board (not shown). The effect control circuit 300 includes a CPU, a ROM, a RAM, an input port, and an output port.
Based on the control command received from the main control circuit 200, the effect control circuit 300 displays effect images on the image display devices 31 and 32, lights the lamps 20 and 21, outputs sound by the sound generator 22, and various types. It controls the drive of a motor (not shown) that drives the movable body.
The ROM of the effect control circuit 300 stores a program related to the progress of the effect, data necessary for the progress of the effect, and the like.
The RAM of the effect control circuit 300 temporarily stores control commands received from the main control circuit 200, data for performing arithmetic processing, and the like.
The effect control circuit 300 includes a display control unit (not shown), a sound control unit (not shown), and a lamp control unit (not shown).
The CPU of the effect control circuit 300 determines the effect contents to be executed based on the control command received from the main control circuit 200. Then, according to the effect control table corresponding to the determined effect content, various command information (display effect request information, sound effect request information, lamp effect request information, etc.) is sent to the corresponding control unit (display control unit, sound control unit). Output to the lamp control unit.
When the display effect request information is input, the display control unit controls display of the effect image by the image display devices 31 and 32 based on the input display effect request information.
In addition, when the sound production request information is input, the sound control unit controls the sound output by the sound generator 22 based on the input sound production request information.
In addition, when the lamp production request information is input, the lamp control unit controls the operations of the various lamps 20 and 21 based on the input lamp production request information.

The payout control circuit 400 is mounted on a payout control board (not shown). The payout control circuit 400 includes a CPU, a ROM, a RAM, an input port, and an output port.
The payout control circuit 400 controls the game ball launching operation by the game ball launcher 430 based on the detection signal input from the launch volume.
Specifically, the payout control circuit 400 controls the launch operation of the game ball by the game ball launching device 430 so that the game ball is launched to the game area 30 with a strength according to the detection signal input from the launch volume. To do.
Also, the payout control circuit 400 controls the game ball payout operation by the game ball payout device 440 based on the control command received from the main control circuit 200 and the ball lending instruction signal received from the CR unit 500.
Specifically, the ball lending button 7 a transmits a ball lending operation signal to the CR unit 500 via the connection board 17 in response to the pressing operation. Then, when the CR unit 500 receives the ball lending operation signal, the CR unit 500 subtracts the frequency necessary for paying out a predetermined number of balls from the remaining frequency of the valuable medium recorded in the inserted prepaid card, The record of the remaining frequency of the valuable medium in the prepaid card is updated, and a ball lending instruction signal for instructing to pay out a predetermined number of game balls is transmitted to the payout control circuit 400 via the connection board 17. Further, when the payout control circuit 400 receives the ball lending instruction signal, the payout control circuit 400 controls the game ball payout operation by the game ball payout device 440 so as to pay out a predetermined number of game balls.
The CR unit 500 sends a frequency signal indicating the remaining frequency of the valuable medium via the connection board 17 when the prepaid cart is inserted and when the record of the remaining frequency of the valuable medium in the prepaid card is updated. It transmits with respect to the display apparatus 7c. When the frequency signal is received, the frequency display device 7c displays the remaining frequency of the valuable medium indicated by the frequency signal.
The return button 7 b transmits a return operation signal to the CR unit 500 via the connection board 17 in response to the pressing operation. When receiving the return operation signal, the CR unit 500 returns (discharges) the prepaid card in which the remaining frequency of the valuable medium remains.

(Control method of panel lamp 21 by effect control circuit 300)
Next, a method for controlling the panel lamp 21 by the effect control circuit 300 will be described.
FIG. 41 is a diagram illustrating an example of a lamp effect scenario table. FIG. 42 is a diagram showing the contents of “lamp scenario data 00”. FIG. 43 is a diagram showing the contents of “lamp scenario data 01”. FIG. 44 is a diagram showing the contents of “lamp scenario data 02”. FIG. 45 is a diagram showing the contents of the combined data of “lamp scenario data 00” and “lamp scenario data 01”. FIG. 46 is a diagram showing the contents of the combined data of “lamp scenario data 00” and “lamp scenario data 02”. FIG. 47 is a diagram showing a schematic configuration of the board surface decoration board.
The RAM of the effect control circuit 300 is provided with a lamp data buffer area (not shown). Then, when the lamp effect request information is input, the lamp control unit of the effect control circuit 300 generates lamp output data, and stores the generated lamp output data in the lamp data buffer area.
At this time, the lamp control unit generates lamp output data based on one or a plurality of lamp scenario data. In particular, the lamp control unit can generate lamp output data by combining a plurality of lamp scenario data.
That is, for each lamp scenario data, any one of a plurality of layers having different priority levels is designated.
In the present embodiment, “layer 1” and “layer 2” are defined as a plurality of layers. For each lamp scenario data, one of “layer 1” and “layer 2” is designated. Here, the priority order of each layer is defined to be “layer 1” and “layer 2” (higher order → lower order) in descending order of priority.
Then, the lamp scenario data designated as the upper layer (“layer 1”) (lamp control data included in the lamp scenario data) and the lamp scenario data designated as the lower layer (“layer 2”) If there is an overlapping part with the lamp scenario data included in the lamp scenario data, the lamp scenario data (the lamp scenario data) designated as the upper layer (“layer 1”) for the overlapping part. Lamp output data is generated with priority given to the lamp control data included in
A method for generating the lamp output data will be described later.
In the present embodiment, the effect control circuit 300 is configured to generate lamp output data by combining a plurality of lamp scenario data. However, in the LED driver 16a described later, a plurality of lamp scenario data may be combined, and the operation of the panel lamp 21 may be controlled based on the combined data. In the case of such a configuration, all lamp scenario data to be combined is output from the effect control circuit 300 to the LED driver 16a, and the LED driver 16a generates combined data based on the input lamp control data. Generated.

The ROM of the effect control circuit 300 stores a lamp effect scenario table corresponding to each lamp effect number.
As shown in FIG. 41, in each lamp effect scenario table, one or a plurality of scenario control data are registered in time series. Each scenario control data includes a lamp scenario number and a duration.
Here, in FIGS. 41A and 41B, in each row where “No.” (specifically, “No. 1” or “No. 2”) is marked, one scenario control data is stored. Is defined.
In particular, each scenario control data includes at least one of a lamp scenario number corresponding to “Layer 1” and a lamp scenario number corresponding to “Layer 2” as a lamp scenario number.
When each lamp effect scenario table is selected and set, the scenario control data registered in the lamp effect scenario table is chronologically ordered from the top scenario control data (in order from the first scenario control data), Each scenario control data is selected and set sequentially. At this time, when the duration included in the scenario control data elapses from the selection / setting of each scenario control data, the selection / setting of the scenario control data is canceled and the scenario control data of the next rank is selected / set. The
During the period in which each scenario control data is selected and set, lamp output data is generated based on the lamp scenario data corresponding to the lamp scenario number included in the scenario control data.

For example, only “No. 1” scenario control data is registered in the “lamp effect scenario table 01” shown in FIG.
In the scenario control data “No. 1”, 1200 [frame] is defined as the duration. Here, in the present embodiment, 1 [frame] = 1/60 [s].
In the scenario control data “No. 1”, “lamp scenario 00” is defined as the lamp scenario number corresponding to “layer 1”, and “lamp scenario 01” is specified as the lamp scenario number corresponding to “layer 2”. Is defined.
Thus, when the “lamp effect scenario table 01” is selected and set, generation of lamp output data based on the scenario control data of “No. 1” is executed only for 1200 [frame].
At this time, the lamp control data included in “lamp scenario 00” is specified as “layer 1”, and the lamp control data included in “lamp scenario 01” is specified as “layer 2”.

On the other hand, “No. 1” scenario control data and “No. 2” scenario control data are registered in the “lamp effect scenario table 02” shown in FIG.
In the scenario control data “No. 1”, 120 [frame] is defined as the duration. Further, in the scenario control data “No. 1”, the lamp scenario number corresponding to “Layer 1” is not specified, and “Ramp scenario 02” is specified as the lamp scenario number corresponding to “Layer 2”. ing.
On the other hand, in the scenario control data of “No. 2”, 600 [frame] is defined as the duration. In the scenario control data “No. 2”, “lamp scenario 00” is defined as the lamp scenario number corresponding to “layer 1”, and “lamp scenario 02” is specified as the lamp scenario number corresponding to “layer 2”. Is defined.
Thus, when the “ramp effect scenario table 02” is selected and set, the generation of the lamp output data based on the scenario control data of “No. 1” is executed only for 120 [frame], and then “No. The generation of lamp output data based on the scenario control data of “.2” is executed only for 600 [frame].
When the lamp output data is generated based on the scenario control data “No. 1”, the lamp control data included in the “lamp scenario 02” is designated as “layer 2”.
On the other hand, when the lamp output data is generated based on the scenario control data of “No. 2”, the lamp control data included in “lamp scenario 00” is designated as “layer 1” and “lamp scenario 02”. The lamp control data included in “is designated as“ Layer 2 ”.
Here, selection / setting of each scenario control data is not influenced by the progress of the lamp scenario data included in the scenario control data.
For example, when “No. 1” scenario control data included in the “lamp effect scenario table 01” is selected and set, generation of lamp output data based on the “No. 1” scenario control data is started. If 1200 [frame] has passed, even if “Lamp scenario 00” (or “Lamp scenario 01”) included in the scenario control data of “No. 1” is in the middle, The generation of lamp output data based on the scenario control data of “.1” (generation of lamp output data based on “lamp scenario 00” and “lamp scenario 01”) is terminated.
Further, when the “No. 1” scenario control data included in the “Ramp effect scenario table 02” is selected and set, the “Ramp scenario 02” included in the “No. 1” scenario control data is displayed. Even if completed, the “lamp scenario 02” is repeated as long as 120 [frame] has not elapsed since the generation of the lamp output data based on the scenario control data of “No. 1”.

The ROM of the effect control circuit 300 stores lamp scenario data corresponding to each lamp scenario number.
Each lamp scenario data includes a driver address, one or a plurality of lamp control data, and an output time corresponding to each lamp control data.
When each lamp scenario data is selected and set, among the lamp control data included in the lamp scenario data, the lamp control data is chronologically ordered from the upper lamp control data (in order from the first lamp control data). Are selected and set sequentially. At this time, when the output time corresponding to the lamp control data elapses from the selection / setting of each lamp control data, the selection / setting of the lamp control data is canceled and the lamp control data of the next order is selected / set. The Further, when the selection / setting of the lowest-order lamp control data is canceled, the highest-order lamp control data is selected / set again.
In this embodiment, when generation of lamp output data based on each lamp control data is completed for all lamp control data included in each lamp scenario data, each lamp included in the lamp scenario data again. With respect to the control data, generation of lamp output data based on the lamp control data is started in order from the highest lamp control data (hereinafter referred to as “repetitive output”). However, when generation of lamp output data based on each lamp control data is completed for all lamp control data included in each lamp scenario data, the configuration / selection of the lamp scenario data is canceled (hereinafter, referred to as “lamp scenario data”). It is also possible to use “one-time output”). Alternatively, one of “repetitive output” and “single output” may be set for each lamp scenario data.
Then, during a period in which each lamp control data is selected and set, lamp output data is generated based on the lamp control data.
Each lamp control data includes control information corresponding to one or a plurality of LED elements.
In the present embodiment, one of “luminance value information” and “blank information NA” is included as control information.
“Luminance value information” is information for specifying a luminance value. In the present embodiment, any one of luminance values “0” to “255” is designated by “luminance value information”.
“Blank information NA” is information indicating that a luminance value is not specified (defined).

In the present embodiment, “ramp scenario data 00”, “lamp scenario data 01”, and “lamp scenario data” are used as lamp scenario data (hereinafter referred to as “panel lamp scenario data”) that defines the operation of the panel lamp 21. A plurality of panel lamp scenario data including "02" are stored.
Each panel lamp scenario data includes a driver address corresponding to the LED driver 16a.
As shown in FIGS. 42 to 44, each panel lamp scenario data includes control information corresponding to each output port a to x included in the LED driver 16a. In other words, each panel lamp scenario data includes control information corresponding to each LED element Lr, Lg, Lb included in the panel lamp 21.
Here, in FIG. 42 to FIG. 46, among the LED elements constituting each of the light emitting blocks L1 to L8, the LED element Lr is indicated by the symbol “R”, the LED element Lg is indicated by the symbol “G”, and the LED element Lb is indicated by the symbol “B”.
42 to 46, one lamp control data is defined in each row where “No.” (“No. 1” to “No. 24”) is marked. 42 to 46, the progress of the lamp control data is defined.
That is, each panel lamp scenario data includes control information corresponding to each LED element Lr constituting the light emission block L1, control information corresponding to each LED element Lg constituting the light emission block L1, and each information constituting the light emission block L1. Control information corresponding to the LED element Lb, control information corresponding to each LED element Lr constituting the light emission block L2, control information corresponding to each LED element Lg constituting the light emission block L2, and light emission block L2 Control information corresponding to each LED element Lb, control information corresponding to each LED element Lr constituting the light emission block L3, control information corresponding to each LED element Lg constituting the light emission block L3, and light emission block L3 Control information corresponding to each LED element Lb and the LED elements Lr constituting the light emission block L4. Corresponding to control information, control information corresponding to each LED element Lg constituting the light emission block L4, control information corresponding to each LED element Lb constituting the light emission block L4, and corresponding LED elements Lr constituting the light emission block L5 Control information corresponding to each LED element Lg constituting the light emission block L5, control information corresponding to each LED element Lb constituting the light emission block L5, and each LED element Lr constituting the light emission block L6. Corresponding control information, control information corresponding to each LED element Lg constituting the light emitting block L6, control information corresponding to each LED element Lb constituting the light emitting block L6, and each LED element Lr constituting the light emitting block L7 , Control information corresponding to each LED element Lg constituting the light emission block L7, and the light emission block 7, control information corresponding to each LED element Lb constituting the light emission block L 8, control information corresponding to each LED element Lr constituting the light emission block L 8, control information corresponding to each LED element Lg constituting the light emission block L 8, and light emission Control information corresponding to each LED element Lb constituting the block L8.

In particular, in this embodiment, basic lamp scenario data that defines the basic aspect of the lamp effect and additional lamp scenario data that defines the effect (effect) aspect to be added to the basic aspect are stored as the panel lamp scenario data. ing.
In addition, as basic lamp scenario data, a plurality of basic lamp scenario data having different operation modes (lamp effect modes) of the eight light emitting blocks L1 to L8 are stored. For example, in this embodiment, “lamp scenario data 01” and “lamp scenario data 02” are stored as basic lamp scenario data.
Furthermore, as additional lamp scenario data, a plurality of additional lamp scenario data having different operation modes (effects to be added (effects)) of the eight light emitting blocks L1 to L8 are stored. For example, in this embodiment, “lamp scenario data 00” is stored as additional lamp scenario data.

“Lamp scenario data 01” shown in FIG. 43 is basic lamp scenario data for executing a lamp effect in which the entire game area 30 emits “rainbow colors”.
Specifically, the “lamp scenario data 01” includes each of the light emitting blocks L1 to L8 among “red”, “orange”, “yellow”, “green”, “blue”, “blue”, and “purple”. The data is to emit light in any color. In particular, the “lamp scenario data 01” is data for changing the light emission colors of the light emission blocks L1 to L8 in a predetermined order every predetermined time.
“Lamp scenario data 01” includes lamp control data “No. 1” to “No. 24”. Further, 1 [frame] is defined as the output time corresponding to each lamp control data.
As a result, when “lamp scenario data 01” is selected and set, each lamp control data from among the lamp control data “No. 1” to “No. Sequentially selected and set. At this time, the lamp control data to be selected / set is changed every 1 [frame]. When the selection / setting of the lamp control data “No. 24” is cancelled, the lamp control data “No. 1” is selected / set again.

On the other hand, “lamp scenario data 02” shown in FIG. 44 is basic lamp scenario data for executing a lamp effect in which the entire game area 30 emits light in “red”.
Specifically, the “lamp scenario data 02” is data for causing each of the light emission blocks L1 to L8 to emit light in “red”.
The “lamp scenario data 02” includes only the lamp control data of “No. 1”. Further, 1 [frame] is defined as the output time corresponding to the lamp control data of “No. 1”.
Thus, when “lamp scenario data 02” is selected / set, the lamp control data “No. 1” is repeatedly selected / set. That is, the lamp control data “No. 1” is selected and set anew for each 1 [frame].

On the other hand, “lamp scenario data 00” shown in FIG. 42 is additional lamp scenario data for adding an effect (effect) in which a part of the game area 30 (partition area) blinks randomly.
Specifically, the “lamp scenario data 00” selects a part of the eight light-emitting blocks L1 to L8, causes the selected light-emitting block to emit light (lights), and then stops light emission (lights off). Data). In particular, the “lamp scenario data 00” is data that changes the selected light-emitting block in a predetermined pattern every predetermined time (in the present embodiment, 2 [frame]).
“Lamp scenario data 00” includes lamp control data “No. 1” to “No. 14”. Further, 1 [frame] is defined as the output time corresponding to each lamp control data.
As a result, when “lamp scenario data 00” is selected and set, each lamp control data from among lamp control data “No. 1” to “No. Sequentially selected and set. At this time, the lamp control data to be selected / set is changed every 1 [frame]. When the selection / setting of the “No. 14” lamp control data is canceled, the “No. 1” lamp control data is selected / set again.

The “lamp scenario data 00” includes a first lamp control data group and a second lamp control data group.
In the first lamp control data group, among the eight light-emitting blocks L1 to L8, the light-emitting block to be operated is changed in a predetermined pattern, and the light-emitting block that becomes the operation mode is changed to the first mode (in this embodiment, “ This is a data group to be operated in a mode of “emitting white light”.
On the other hand, in the second lamp control data group, among the eight light emission blocks L1 to L8, the light emission block to be operated is changed in the same pattern as the first lamp control data group, and the light emission block as the operation mode is changed. The data group is operated in the second mode (in this embodiment, “mode to stop light emission”).
That is, in the first lamp control data group, among the eight light-emitting blocks L1 to L8, the light-emitting block to be operated (specifically, the light-emitting block in which “luminance value information” is defined) is a predetermined pattern. Be changed. And in each lamp control data contained in the 1st lamp control data group, the light emission block used as operation object operates in the 1st mode.
On the other hand, in the second lamp control data group, among the eight light emission blocks L1 to L8, the light emission block to be operated is changed in a predetermined pattern. And in each lamp control data contained in the 2nd lamp control data group, the light emission block used as operation object operates in the 2nd mode.
In particular, in the first lamp control data group and the second lamp control data group, among the eight light emitting blocks L1 to L8, the light emitting block to be operated is changed by the same pattern.
In the “lamp scenario data 00”, the first lamp control data group and the second lamp control data group are arranged out of phase with each other.
Further, in the first lamp control data group and the second lamp control data group, the light emission block to be operated is operated in a different manner.

Specifically, the first lamp control data group includes “No. 1” lamp control data, “No. 3” lamp control data, “No. 5” lamp control data, and “No. 7”. Lamp control data, “No. 9” lamp control data, “No. 11” lamp control data, and “No. 13” lamp control data.
In the lamp control data “No. 1”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L1 and L4, and each of the light emission blocks constituting the other light emission blocks is defined. As the control information corresponding to the LED element, “blank information NA” is defined. Thereby, in the lamp control data of “No. 1”, the LED elements constituting the light emission blocks L1 and L4 are the operation targets.
On the other hand, in the lamp control data of “No. 3”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L3, L6, and L8, and other light emission blocks are configured. As the control information corresponding to each LED element to be performed, “blank information NA” is defined. Thereby, in the lamp control data of “No. 3”, the LED elements constituting the light emission blocks L3, L6, and L8 are to be operated.
On the other hand, in the lamp control data of “No. 5”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L2 and L7, and each of the light emission blocks constituting the other light emission blocks is defined. As the control information corresponding to the LED element, “blank information NA” is defined. Thereby, in the lamp control data of “No. 5”, the LED elements constituting the light emission blocks L2 and L7 are to be operated.
On the other hand, in the lamp control data of “No. 7”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L3 and L5, and each of the light emission blocks constituting the other light emission blocks is defined. As the control information corresponding to the LED element, “blank information NA” is defined. Accordingly, in the lamp control data of “No. 7”, each LED element constituting the light emission blocks L3 and L5 is an operation target.
On the other hand, in the lamp control data of “No. 9”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L4 and L8, and each of the light emission blocks constituting the other light emission blocks is defined. As the control information corresponding to the LED element, “blank information NA” is defined. Thus, in the lamp control data of “No. 9”, the LED elements constituting the light emission blocks L4 and L8 are the operation targets.
On the other hand, in the lamp control data of “No. 11”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L1 and L6, and each of the light emission blocks constituting the other light emission blocks is defined. As the control information corresponding to the LED element, “blank information NA” is defined. As a result, in the lamp control data “No. 11”, the LED elements constituting the light emission blocks L1 and L6 are to be operated.
On the other hand, in the lamp control data of “No. 13”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L2, L5, L7, and other light emission blocks are configured. As the control information corresponding to each LED element to be performed, “blank information NA” is defined. Accordingly, in the lamp control data of “No. 13”, the LED elements constituting the light emission blocks L2, L5, and L7 are to be operated.

As described above, in the first lamp control data group, the light emission blocks to be operated are “light emission blocks L1, L4” → “light emission blocks L3, L6, L8” → “light emission blocks L2, L7” → “light emission block L3”. The cycle changed in the order of “L5” → “light emission blocks L4, L8” → “light emission blocks L1, L6” → “light emission blocks L2, L5, L7” is repeated.
At this time, in the first lamp control data group, the light emission block to be operated is changed at intervals of 1 [frame].
And in the 1st lamp control data group, the control information corresponding to each LED element which comprises the light emission block used as an operation | movement aspect is prescribed | regulated so that the light emission block used as operation object may light-emit "white." Specifically, “luminance value information” that specifies luminance value = 255 is defined as control information corresponding to each LED element constituting the light-emitting block that is an operation mode.
Therefore, according to the first lamp control data group, a predetermined pattern (specifically, “light emission blocks L1, L4” → “light emission blocks L3, L6, L8” → “light emission blocks L2, L7” → “light emission block”). In order of “L3, L5” → “light emission blocks L4, L8” → “light emission blocks L1, L6” → “light emission blocks L2, L5, L7”), each light emission block is sequentially arranged with an interval of 1 [frame]. , “White” light is emitted.

The second lamp control data group includes “No. 2” lamp control data, “No. 4” lamp control data, “No. 6” lamp control data, and “No. 8” lamp control data. And “No. 10” lamp control data, “No. 12” lamp control data, and “No. 14” lamp control data.
In the “No. 2” lamp control data, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L1 and L4. As the control information corresponding to the LED element, “blank information NA” is defined. Thereby, in the lamp control data of “No. 2”, each LED element constituting the light emission blocks L1 and L4 is an operation target.
On the other hand, in the lamp control data of “No. 4”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L3, L6, and L8, and other light emission blocks are configured. As the control information corresponding to each LED element to be performed, “blank information NA” is defined. Thereby, in the lamp control data of “No. 4”, the LED elements constituting the light emission blocks L3, L6, and L8 are to be operated.
On the other hand, in the lamp control data of “No. 6”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L2 and L7, and each of the light emission blocks constituting the other light emission blocks is defined. As the control information corresponding to the LED element, “blank information NA” is defined. Thereby, in the lamp control data of “No. 6”, the LED elements constituting the light emission blocks L2 and L7 are to be operated.
On the other hand, in the lamp control data of “No. 8”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L3 and L5, and each of the light emission blocks constituting the other light emission blocks is defined. As the control information corresponding to the LED element, “blank information NA” is defined. As a result, in the lamp control data of “No. 8”, the LED elements constituting the light emission blocks L3 and L5 are to be operated.
On the other hand, in the lamp control data of “No. 10”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L4 and L8, and each of the light emission blocks constituting the other light emission blocks is defined. As the control information corresponding to the LED element, “blank information NA” is defined. As a result, in the lamp control data of “No. 10”, the LED elements constituting the light emission blocks L4 and L8 are to be operated.
On the other hand, in the lamp control data of “No. 12”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L1 and L6, and each of the light emission blocks constituting the other light emission blocks is defined. As the control information corresponding to the LED element, “blank information NA” is defined. Accordingly, in the lamp control data of “No. 12”, each LED element constituting the light emission blocks L1 and L6 is an operation target.
On the other hand, in the lamp control data of “No. 14”, “luminance value information” is defined as control information corresponding to each LED element constituting the light emission blocks L2, L5, L7, and other light emission blocks are configured. As the control information corresponding to each LED element to be performed, “blank information NA” is defined. Thus, in the lamp control data of “No. 14”, the LED elements constituting the light emission blocks L2, L5, and L7 are to be operated.

As described above, in the second lamp control data group, the light emission blocks to be operated are sequentially changed in the same pattern as the first lamp control data group. That is, in the second lamp control data group, the light emission blocks to be operated are “light emission blocks L1, L4” → “light emission blocks L3, L6, L8” → “light emission blocks L2, L7” → “light emission blocks L3, L5”. ”→“ light emission blocks L4, L8 ”→“ light emission blocks L1, L6 ”→“ light emission blocks L2, L5, L7 ”are repeated in this order.
At this time, in the second lamp control data group, the light emission block to be operated is changed at the same interval (specifically, 1 [frame] interval) as the first lamp control data group.
And in the 2nd lamp control data group, the control information corresponding to each LED element which comprises the light emission block used as an operation | movement aspect is prescribed | regulated so that the light emission block used as operation | movement object may stop light emission (light extinction). . Specifically, “brightness value information” that specifies luminance value = 0 is defined as control information corresponding to each LED element constituting the light-emitting block that is an operation mode.
Therefore, according to the second lamp control data group, the same pattern as the first lamp control data group (specifically, “light emission blocks L1, L4” → “light emission blocks L3, L6, L8” → “light emission block L2”). , L7 ”→“ light emission blocks L3, L5 ”→“ light emission blocks L4, L8 ”→“ light emission blocks L1, L6 ”→“ light emission blocks L2, L5, L7 ”in this order), the interval of 1 [frame] is set. Then, the light emission of each light emission block is stopped sequentially.

In the “lamp scenario data 00”, the first lamp control data group and the second lamp control data group are arranged with a phase shifted from each other by a predetermined time (in this embodiment, 1 [frame]). In the present embodiment, the phase of the second lamp control data is delayed by 1 [frame] from the first lamp control data.
Specifically, in “lamp scenario data 00”, lamp control data included in the first lamp control data group (hereinafter referred to as “first lamp control data”) and lamp control included in the second lamp control data group. Data (hereinafter, “second lamp control data”) are alternately arranged. The same light emission block is set as an operation target for each first lamp control data and second lamp control data arranged next to the first lamp control data.
Thus, according to “Lamp Scenario Data 00”, light emission is stopped for 1 [frame] immediately after “white” is emitted for 1 [frame] for each light emission block.
Therefore, according to the “lamp scenario data 00”, a predetermined pattern (specifically, “light emission blocks L1, L4” → “light emission blocks L3, L6, L8” → “light emission blocks L2, L7” → “light emission block”). L3, L5 ”→“ light emission blocks L4, L8 ”→“ light emission blocks L1, L6 ”→“ light emission blocks L2, L5, L7 ”in this order) Can be given.

Next, a method for generating lamp output data will be described.
In each scenario control data registered in the lamp effect scenario table, if the lamp scenario number is specified for only one of “layer 1” and “layer 2”, the specified one is specified. Lamp output data is generated based on the lamp control data corresponding to the lamp scenario number.
In this case, the lamp control data corresponding to one designated lamp scenario number is used as the lamp output data as it is.
For example, in the scenario control data “No. 1” included in the “ramp effect scenario table 02” shown in FIG. 41B, the lamp scenario number corresponding to “layer 1” is not specified, and “layer 2” "Lamp scenario 02" is designated as the lamp scenario number corresponding to "".
Thus, lamp output data is generated based on the lamp scenario data (“lamp scenario data 02”) during the period in which the scenario control data is selected and set. That is, each lamp control data included in the lamp scenario data (“lamp scenario data 02”) is sequentially set as lamp output data.

On the other hand, in each scenario control data registered in the lamp effect scenario table, when a lamp scenario number is specified for both “Layer 1” and “Layer 2”, a plurality of specified lamp scenarios Lamp output data is generated based on the lamp control data corresponding to the number.
In this case, the combined data of the lamp control data corresponding to the lamp scenario number designated as “Layer 1” and the lamp control data corresponding to the lamp scenario number designated as “Layer 2” is obtained. And lamp output data.
At this time, if there is an overlapping part between the lamp control data specified as “Layer 1” and the lamp control data specified as “Layer 2”, Lamp output data is generated with priority given to lamp control data designated as “1”.
Here, “there is an overlapping portion” means that the lamp control data designated as “Layer 1” and “Layer 2” as control information corresponding to one LED element (output ports a to x). "Luminance value information" is defined in both of the lamp control data designated as "".
Specifically, as the control information of one LED element, “brightness value information” is defined in the lamp control data designated as “layer 1”, and in the lamp control data designated as “layer 2”. When “luminance value information” is defined, “luminance value information” defined in the lamp control data designated as “layer 1” is selected as control information of the LED element.
On the other hand, as the control information of one LED element, “blank information NA” is defined in the lamp control data designated as “layer 1”, and “luminance” is designated in the lamp control data designated as “layer 2”. When “value information” is defined, “luminance value information” defined in the lamp control data designated as “layer 2” is selected as the control information of the LED element.
Thus, when generating the lamp output data, “brightness value information” is defined in the lamp control data designated as “Layer 1” as control information corresponding to each LED element (output port). When the “brightness value information” is selected and “brightness value information” is not defined in the lamp control data designated as “layer 1” (when “blank information NA” is defined) Is selected as “brightness value information” defined in the lamp control data designated as “layer 2”.

For example, in the scenario control data “No. 1” included in the “ramp effect scenario table 01” shown in FIG. 41A, “lamp scenario number 00” is designated as the lamp scenario number corresponding to “layer 1”. “Lamp scenario 01” is designated as the lamp scenario number corresponding to “Layer 2”.
Thus, lamp output data is generated based on “lamp scenario data 00” and “lamp scenario data 01” during a period in which the scenario control data is selected and set.
That is, lamp output data is generated by combining lamp control data included in “lamp scenario data 00” and lamp control data included in “lamp scenario data 01”.
At this time, as shown in FIG. 45, the lamp control data included in the “lamp scenario data 00” and the lamp control data included in the “lamp scenario data 01” overlap (the shaded display shown in FIG. 45). With respect to (), lamp output data is generated with priority given to lamp control data included in the “lamp scenario data 00”.
That is, among the LED elements included in the light emission blocks L1 to L8, for the LED element for which “luminance value information” is defined in the lamp control data included in the “lamp scenario data 00”, the control corresponding to the LED element is performed. As information, “luminance value information” defined in the lamp control data included in “lamp scenario data 00” is selected, and lamp output data is generated.
On the other hand, among the LED elements included in the light emission blocks L1 to L8, for the LED elements for which “blank information NA” is defined in the lamp control data included in the “lamp scenario data 00”, the control corresponding to the LED element is performed. As information, “luminance value information” defined in the lamp control data included in “lamp scenario data 01” is selected, and lamp output data is generated.
Thereby, during the period in which the scenario control data is selected and set, the eight light emitting blocks L1 to L8 emit light in “rainbow colors” in a predetermined pattern (operation based on “lamp scenario data 01”). During the execution of the above, an operation (an operation based on “lamp scenario data 00”) in which the eight light-emitting blocks L1 to L8 sequentially blink in a predetermined pattern is executed.

On the other hand, in the scenario control data “No. 2” included in the “lamp effect scenario table 01” shown in FIG. 41B, “lamp scenario number 00” is designated as the lamp scenario number corresponding to “layer 1”. “Lamp scenario 02” is designated as the lamp scenario number corresponding to “Layer 2”.
As a result, during the period in which the scenario control data is selected and set, lamp output data is generated based on “lamp scenario data 00” and “lamp scenario data 02”.
That is, lamp output data is generated by combining lamp control data included in “lamp scenario data 00” and lamp control data included in “lamp scenario data 02”.
At this time, as shown in FIG. 46, the lamp control data included in the “lamp scenario data 00” and the lamp control data included in the “lamp scenario data 02” overlap each other (the shaded display shown in FIG. 46). With respect to (), lamp output data is generated with priority given to lamp control data included in “lamp scenario data 00”.
That is, among the LED elements included in the light emission blocks L1 to L8, for the LED element for which “luminance value information” is defined in the lamp control data included in the “lamp scenario data 00”, the control corresponding to the LED element is performed. As information, “luminance value information” defined in the lamp control data included in “lamp scenario data 00” is selected, and lamp output data is generated.
On the other hand, among the LED elements included in the light emission blocks L1 to L8, for the LED element for which “blank information NA” is defined in the lamp control data included in the “lamp scenario data 00”, the control corresponding to the LED element is performed. As information, “luminance value information” defined in the lamp control data included in “lamp scenario data 02” is selected, and lamp output data is generated.
Thereby, during the period in which the scenario control data is selected and set, the eight light-emitting blocks L1 to L8 emit light “red” in a predetermined pattern (operation based on “lamp scenario data 02”). During execution, an operation (an operation based on “lamp scenario data 00”) in which the eight light-emitting blocks L1 to L8 sequentially blink in a predetermined pattern is executed.

When the lamp effect request information is input, the lamp control unit selects and sets a lamp effect scenario table corresponding to the lamp effect number specified by the input lamp effect request information. In addition, lamp output data is generated according to the selected / set lamp effect scenario table. The generated lamp output data is stored in the lamp data buffer area.
The lamp output data stored in the lamp data buffer area is output from the predetermined output port provided in the effect control circuit 300 to each of the electrical decoration boards 15 and 16.
An LED driver (not shown) is executed on the frame illumination board 15. In addition, as shown in FIG. 47, an LED driver 16 a is mounted on the panel surface decoration board 16. In addition, the structure of the LED driver mounted in the frame electrical decoration board | substrate 15 and the LED driver 16a is the same. Therefore, hereinafter, the configuration of the LED driver 16a will be described, and the description of the configuration of the LED driver mounted on the frame electrical decoration board 15 will be omitted.
The effect control circuit 300 and the LED driver 16a are connected to each other via a harness for serial communication. Then, the effect control circuit 300 outputs lamp output data to the LED driver 16a by serial communication.
The LED driver 16a includes a serial bus interface, a data buffer (shift register), a controller, and a predetermined number (24 channels in this embodiment) of output ports a to x.
The serial bus interface takes in the lamp output data output by the effect control circuit 300 and converts the fetched lamp output data into parallel data. The converted lamp output data is stored in the data buffer.
Based on the lamp output data stored in the data buffer, the controller sets the luminance value (control value) of the LED element connected to each of the output ports a to x in a register corresponding to the output port. As a result, a drive signal (current) corresponding to the luminance value set in the register corresponding to each output port a to x is generated, and the generated drive signal is connected to each LED element connected to the output port. Is output for. That is, the operation of each LED element connected to the output port is controlled (PWM control) in accordance with the luminance value set in the register corresponding to each output port a to x.

One or a plurality of LED elements Lr, Lg, and Lb are electrically connected to the output ports a to x of the LED driver 16a.
Specifically, as shown in FIG. 47, the LED element Lr of each light emitting element L constituting the light emitting block L1 is connected to the output port a, and each light source constituting the light emitting block L1 is connected to the output port b. The LED element Lg of the light emitting element L is connected, and the LED element Lb of each light emitting element L constituting the light emitting block L1 is connected to the output port c. Thereby, the light emission block L1 is comprised by the LED element connected to output port ac. And operation | movement of each light emitting element L which comprises the light emission block L1 is controlled by the drive signal output from output port ac.
On the other hand, the LED element Lr of each light emitting element L constituting the light emitting block L2 is connected to the output port d, and the LED element Lg of each light emitting element L constituting the light emitting block L2 is connected to the output port e. The LED element Lb of each light emitting element L constituting the light emitting block L2 is connected to the output port f. Thereby, the light emission block L2 is comprised by the LED element connected to the output ports df. And operation | movement of each light emitting element L which comprises the light emission block L2 is controlled by the drive signal output from output port df.
On the other hand, the LED element Lr of each light emitting element L constituting the light emitting block L3 is connected to the output port g, and the LED element Lg of each light emitting element L constituting the light emitting block L3 is connected to the output port h. The LED element Lb of each light emitting element L constituting the light emitting block L3 is connected to the output port i. Thereby, the light emission block L3 is comprised by the LED element connected to the output ports gi. And operation | movement of each light emitting element L which comprises the light emission block L3 is controlled by the drive signal output from the output ports gi.
On the other hand, the LED element Lr of each light emitting element L constituting the light emitting block L4 is connected to the output port j, and the LED element Lg of each light emitting element L constituting the light emitting block L4 is connected to the output port k. The LED element Lb of each light emitting element L constituting the light emitting block L4 is connected to the output port l. Thus, the light emitting block L4 is configured by the LED elements connected to the output ports j to l. The operation of each light emitting element L constituting the light emitting block L4 is controlled by the drive signal output from the output ports j to l.
On the other hand, the LED element Lr of each light emitting element L constituting the light emitting block L5 is connected to the output port m, and the LED element Lg of each light emitting element L constituting the light emitting block L5 is connected to the output port n. The LED element Lb of each light emitting element L constituting the light emitting block L5 is connected to the output port o. Thus, the light emitting block L5 is configured by the LED elements connected to the output ports m to o. And operation of each light emitting element L which constitutes light emission block L5 is controlled by a drive signal outputted from output ports m-o.
On the other hand, the LED element Lr of each light emitting element L constituting the light emitting block L6 is connected to the output port p, and the LED element Lg of each light emitting element L constituting the light emitting block L6 is connected to the output port q. The LED element Lb of each light emitting element L constituting the light emitting block L6 is connected to the output port r. Thereby, the light emission block L6 is comprised by the LED element connected to the output ports pr. The operation of each light emitting element L constituting the light emitting block L6 is controlled by the drive signal output from the output ports p to r.
On the other hand, the LED element Lr of each light emitting element L constituting the light emitting block L7 is connected to the output port s, and the LED element Lg of each light emitting element L constituting the light emitting block L7 is connected to the output port t. The LED element Lb of each light emitting element L constituting the light emitting block L7 is connected to the output port u. Thus, the light emitting block L7 is configured by the LED elements connected to the output ports s to u. The operation of each light emitting element L constituting the light emitting block L7 is controlled by the drive signal output from the output ports s to u.
On the other hand, the LED element Lr of each light emitting element L constituting the light emitting block L8 is connected to the output port v, and the LED element Lg of each light emitting element L constituting the light emitting block L8 is connected to the output port w. The LED element Lb of each light emitting element L constituting the light emitting block L8 is connected to the output port x. Thus, the light emitting block L8 is configured by the LED elements connected to the output ports v to x. And operation of each light emitting element L which constitutes light emission block L8 is controlled by a drive signal outputted from output ports v-x.

(About various lotteries)
Next, various lotteries executed by the pachinko machine 1 will be described.
In the pachinko machine 1, a normal symbol lottery is executed in response to the passage of the start gate 41 by a game ball. When a normal symbol lottery is won, a gaming state is generated per regular drawing. In the normal game state, the ordinary electric accessory 52a is displaced (opened) from the closed state to the open state, so that the game ball can enter the second start port 52.
In the present embodiment, one type of “per ordinary figure” is set as the type of game state per ordinary figure that occurs when the normal symbol lottery is won.

In the case of winning the “per symbol” (winning the normal symbol lottery), the normal symbol display device controls the normal symbol to be stopped and displayed as “per symbol”.
On the other hand, when the normal symbol lottery is lost, the normal symbol display device controls the normal symbol to be stopped and displayed as “offset symbol”.
In the pachinko machine 1, it is possible to execute time reduction control as auxiliary control that is advantageous to the player.
During execution of the time reduction control, the time for displaying the variation of the special symbol (hereinafter referred to as “variation time”) is shortened as compared to when the time reduction control is stopped. In the present embodiment, during the execution of the time reduction control, the winning probability of the normal symbol lottery is improved and the time for displaying the fluctuation of the normal symbol is shortened as compared to when the time reduction control is stopped. In addition, during execution of the time reduction control, the number of times of opening of the ordinary electric accessory 52a is increased and the opening time of the ordinary electric accessory 52a is increased in the gaming state per figure as compared to when the time reduction control is stopped. Extended.
In the case of winning the “per ordinary map”, the number of times of opening of the ordinary electric accessory 52a is set to 1 [times] or 3 [times], and the opening time of the ordinary electric accessory 52a at each time is 0.5. [S] or 2.0 [s] is set. At this time, during the execution of the short-time control, the number of times of opening of the ordinary electric accessory 52a is set to 3 [times], and the opening time of the ordinary electric accessory 52a at each time is set to 2.0 [s]. Is set. On the other hand, while the short-time control is stopped, the number of times of opening the ordinary electric accessory 52a is set to 1 [times], and the opening time of the ordinary electric accessory 52a at each time is set to 0.5 [s]. Is done.

Further, in the pachinko machine 1, the first special symbol lottery is executed in response to the game ball entering the first start port 51, and the second ball is input in response to the game ball entering the second start port 52. A special symbol lottery is executed. When the first special symbol lottery or the second special symbol lottery is won, a big hit gaming state is generated. In the big hit game state, a round game in which the special electric accessory 53a is displaced from the closed state to the open state is executed, and the game ball can enter the big winning opening 53.
In the present embodiment, “big hit 1” and “big hit 2” are set as the types of jackpot gaming state that are generated when the first special symbol lottery is won, and are generated when the second special symbol lottery is won. As the types of the big hit gaming state, “big hit 3” to “big hit 6” are set.

When the “big hit 1” is won, the special symbol 1 display device stops and displays the stop symbol (display mode) corresponding to the “big hit one symbol”. In the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the “probability variable symbol” is stopped and displayed.
Here, the “probable change symbol” is the same as the first effect symbol z1 that is stopped and displayed at the lottery result display positions in the three first effect symbol display areas a1 to a3, for example, “7, 7, 7”, etc. A display mode in which “numbered symbols” indicating odd numbers are arranged and the second effect symbol z2 stopped and displayed in the second effect symbol display area a4 indicates a predetermined color.
When the “big hit 2” is won, the special symbol 1 display device stops and displays the stop symbol (display mode) corresponding to the “big hit 2 symbols”. In the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the “normal symbol” is stopped and displayed.
Here, the “normal symbol” is the same as the first effect symbol z1 that is stopped and displayed at the lottery result display positions in the three first effect symbol display areas a1 to a3, for example, “2, 2, 2”, etc. A display mode is provided in which “number symbols” indicating even numbers are aligned and the second effect symbol z2 stopped and displayed in the second effect symbol display area a4 indicates a predetermined color.
When the “big hit 3” is won, the special symbol 2 display device stops and displays the stop symbol (display mode) corresponding to the “big hit 3 symbols”. In the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the “probability variable symbol” is stopped and displayed.
When the “big hit 4” is won, the special symbol 2 display device stops and displays the stop symbol (display mode) corresponding to the “big hit 4 symbols”. In the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the “probability variable symbol” is stopped and displayed.
When the “big hit 5” is won, the special symbol 2 display device stops and displays the stop symbol (display mode) corresponding to the “big hit 5 symbols”. In the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the “latent symbol” is stopped and displayed.
Here, the “latent symbol” is a predetermined symbol such as “1, 2, 3” in which the first effect symbol z1 stopped and displayed at the lottery result display positions of the three first effect symbol display areas a1 to a3 is, for example, In addition to the combination having regularity, the second effect symbol z2 stopped and displayed in the second effect symbol display area a4 is set to a display mode in which a predetermined color is displayed.
When the “big hit 6” is won, the special symbol 2 display device stops and displays the stop symbol (display mode) corresponding to the “big hit 6 symbols”. In the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the “latent symbol” is stopped and displayed.

On the other hand, when the special symbol lottery is lost (in the case of “missing”), on the display devices 61 and 62, the stop symbol (display mode) corresponding to the “missing symbol” is stopped and displayed. In addition, in the effect symbol display areas a1 to a4, the stop symbol (display mode) corresponding to the “out of symbol” is stopped and displayed.
Here, for example, the “offset symbol” indicates that the first effect symbol z1 stopped and displayed in the three first effect symbol display areas a1 to a3 is stopped and displayed in at least one area, such as “1, 6, 9” The number indicated by the “numerical symbol” is a combination different from the number indicated by the “numeric symbol” stopped and displayed in the other area, and the second effect symbol z2 stopped and displayed in the second effect symbol display area a4. Is a display mode showing a predetermined color.

In the case of winning from “big hit 1” to “big hit 6”, a predetermined number of round games are executed in the big hit gaming state.
In the present embodiment, when winning “big hit 1”, “big hit 2”, “big hit 5” or “big hit 6”, the number of round games is set to 5 [times]. On the other hand, when the “big hit 3” is won, the number of round games is set to 15 [times]. On the other hand, when “big hit 4” is won, the number of round games is set to 10 [times].
When winning from “big hit 1” to “big hit 6”, the longest opening time of the special electric accessory 53a in each round game is set to a predetermined time (29.0 [s] in this embodiment). The In each round game, the longest open time set after the special electric accessory 53a is opened, and the number of game balls entering the big prize opening 53 in the round game is Of the fact that the predetermined upper limit number (10 [sphere] in the present embodiment) has been reached, the process is terminated when one of the conditions is satisfied.

Moreover, in the pachinko machine 1, as the gaming state related to the winning probability of the special symbol lottery (the first special symbol lottery and the second special symbol lottery), the “special symbol low probability state”, the “special symbol high probability state”, Is stipulated.
During the occurrence of the “special figure low probability state”, the winning probability of the special symbol lottery is set to the first probability (hereinafter referred to as “low probability”).
During the occurrence of the “special drawing high probability state”, the winning probability of the special symbol lottery is set to a second probability higher than the first probability (hereinafter referred to as “high probability”).
The main control circuit 200 sets the winning probability of each lottery so that the winning probability of the first special symbol lottery is synchronized with the winning probability of the second special symbol lottery. Here, the winning probability of the special symbol lottery means the probability of winning the “hit” (“hit 1” to “hit 6”) in which the big hit gaming state occurs.
In particular, in the pachinko machine 1, the winning probability of the special symbol lottery is a set of a value (setting value) set in the setting information storage area and a gaming state (a special figure low probability state or a special figure high probability state). Probability according to the match.

Specifically, during the occurrence of the set value = “1” and the “special figure low probability state”, the winning probability (big hit probability) of the special symbol lottery is 1 / 319.69. On the other hand, during the occurrence of the set value = “1” and the “special figure high probability state”, the winning probability (big hit probability) of the special symbol lottery is 1 / 32.13.
On the other hand, during the occurrence of the set value = “2” and the “special figure low probability state”, the winning probability (big hit probability) of the special symbol lottery is 1 / 312.08. On the other hand, during the occurrence of the set value = “2” and the “special figure high probability state”, the winning probability (big hit probability) of the special symbol lottery becomes 1 / 31.36.
On the other hand, during the occurrence of the set value = “3” and the “special figure low probability state”, the winning probability (big hit probability) of the special symbol lottery becomes 1 / 304.82. On the other hand, during the occurrence of the set value = “3” and the “special figure high probability state”, the winning probability (big hit probability) of the special symbol lottery becomes 1 / 30.62.
On the other hand, during the occurrence of the set value = “4” and the “special figure low probability state”, the winning probability (big hit probability) of the special symbol lottery is 1 / 297.89. On the other hand, during the occurrence of the setting value = “4” and the “special figure high probability state”, the winning probability (big hit probability) of the special symbol lottery is 1 / 29.93.
On the other hand, during the occurrence of the set value = “5” and the “special figure low probability state”, the winning probability (big hit probability) of the special symbol lottery is 1 / 291.27. On the other hand, during the occurrence of the set value = “5” and the “special figure high probability state”, the winning probability (big hit probability) of the special symbol lottery is 1 / 29.26.
On the other hand, during the occurrence of the set value = “6” and the “special figure low probability state”, the winning probability (big hit probability) of the special symbol lottery is 1 / 284.94. On the other hand, during the occurrence of the set value = “6” and the “special figure high probability state”, the winning probability (big hit probability) of the special symbol lottery is 1 / 28.62.

In the case of winning the “hit 2” or “hit 6”, the “special figure low probability state” is generated in the period from the end of the big hit gaming state to the occurrence of the next big hit gaming state.
On the other hand, when winning “big hit 1” or “big hit 3” to “big hit 5”, a “special figure high probability state” is generated in accordance with the end of the big hit gaming state. In the present embodiment, the “special figure high probability state” is started in response to the end of the jackpot gaming state, and is ended in response to the start of the next jackpot gaming state (end of the “big hit symbol” stop display).
The “special figure high probability state” is started in response to the end of the jackpot gaming state, and the number of special symbol lotteries executed during the occurrence of the “special figure high probability state” is a predetermined number (for example, 10000 [ It is also possible to adopt a configuration in which the process is terminated in response to reaching (time) ”(a“ special figure low probability state ”occurs).
In the case of winning from “big hit 1” to “big hit 6”, the time reduction control is executed after the big hit gaming state is finished.
Time-shortening control is started in response to the end of the jackpot gaming state, winning a special symbol lottery ("Big jackpot symbol" is stopped and displayed), and notification display (variable display) of a predetermined number of short-time special symbols And the stop display) are executed when one of the conditions is satisfied.
In the case of winning “big hit 2” or “big hit 6”, 100 [times] is set as the predetermined number of times.
on the other hand. When winning “big hit 1” or “big hit 3” to “big hit 5”, 10000 [times] is set as the predetermined number of times.

(About control commands)
Next, control commands transmitted from the main control circuit 200 to the effect control circuit 300 and control commands transmitted / received between the main control circuit 200 and the payout control circuit 400 will be described.
The main control circuit 200 and the effect control circuit 300 are connected to each other via a serial communication harness. Here, communication between the main control circuit 200 and the effect control circuit 300 is performed only in one direction from the main control circuit 200 to the effect control circuit 300, and communication from the effect control circuit 300 to the main control circuit 200 is performed. Not done.
Each control command transmitted from the main control circuit 200 to the effect control circuit 300 is composed of 1-byte upper data indicating the type of the control command and 1-byte lower data indicating the contents of the control command. Yes.
Then, the main control circuit 200 transmits a control command composed of upper data and lower data to the effect control circuit 300 by serial communication. When the production control circuit 300 receives a control command from the main control circuit 200, a serial communication reception interruption occurs, and the data of the control command is stored in a predetermined area of the RAM by this interruption process.

In the pachinko machine 1, as control commands transmitted from the main control circuit 200 to the effect control circuit 300, a symbol type designation command, a variation mode designation command, a variation pattern designation command, a stop designation command, a game state designation command, the number of holds A designation command, an opening designation command, a round start designation command, a round end designation command, an ending designation command, a first prefetch designation command, a second prefetch designation command, a third prefetch designation command, and the like are set.
The symbol type designation command is a command for designating the type of the symbol to be stopped (one of the “missing symbols” and “one jackpot symbol” to “six jackpot symbols”). The symbol type designation command is transmitted when the special symbol variable display is started. In the present embodiment, symbols corresponding to the first special symbol lottery and the second special symbol lottery are set as the symbol type designation command.
The variation mode designation command is a command for designating the type of variation mode (variation mode number). The variation mode designation command designates the variation time associated with the variation mode number by designating the variation mode number. The variation mode designation command designates the variation time of the first half period (a mode of the first half period of the variation effect) of the special symbol variation display (variation effect).
In the present embodiment, m (plural) types of variation modes associated with different variation times are set as the variation mode types. The variation mode designation command designates one of the m types of variation modes (variation mode number) (“variation mode m”).
The variation pattern designation command is a command for designating a variation pattern type (variation pattern number). The variation pattern designation command designates the variation time associated with the variation pattern number by designating the variation pattern number. The variation pattern designation command designates the variation time of the latter half period (the aspect of the second half period of the variation effect) of the variation display (variation effect) of the special symbol.
In the present embodiment, n (plural) types of variation patterns associated with different variation times are set as the variation pattern types. Then, the variation pattern designation command designates one of the n types of variation patterns (variation pattern number) (“variation pattern n”).
The variation mode designation command and the variation pattern designation command are transmitted at the start of variation display of the special symbol.

The stop designation command is a command for designating stop display of a special symbol (effect symbols z1, z2). The stop designation command is transmitted at the start of the special symbol stop display.
The game state designation command is a command for designating a game state (game state offset value).
Here, the “gaming state offset value” is information for designating the gaming state. In the present embodiment, as the gaming state offset value, each of the combinations of the value of the short-time control flag, the value of the special figure high probability state flag, the value of the previous big hit symbol flag, and the value of the big hit after rotation counter Corresponding numerical value is set.
The gaming state designation command designates one gaming state offset value. The game state designation command is transmitted when the power is turned on or when a special game phase to be described later is changed.
Here, as the gaming state offset value, the value of the short time control flag, the value of the special figure high probability state flag, the value of the previous big hit symbol flag, the value of the big hit after rotation counter, and the setting information storage area are stored. A numerical value corresponding to each of the combinations of the values (set values) being set may be set. Then, when transmitting the game state designation command, the value of the short time control flag, the value of the special figure high probability state flag, the value of the previous big hit symbol flag, the rotation number after the big hit, which are set in a predetermined area of the RAM 230 Checking the counter value and the value stored in the setting information storage area, calculating a gaming state offset value corresponding to the confirmation result, and a gaming state designation command for designating the calculated gaming state offset value The sub-command output request buffer of the RAM 230 may be stored (transmitted to the effect control circuit 300).

The hold number designation command is a command for designating the hold number. In the present embodiment, the number-of-holds designation command designates that the number of holds (the special figure 1 hold number or the special figure 2 hold number) has increased by “1”, that the hold number has decreased by “1”, the hold number, etc. .
Here, the “special figure 1 hold number” refers to the number of the notice display (variation display and stop display) of the first special symbol on the special figure 1 display device. Also, the “special figure 2 hold number” means the number of the second special symbol notification display (fluctuation display and stop display) held on the special figure 2 display device.
The number-of-holds designation command is transmitted when the power is turned on, when starting information is stored, when a special symbol variation display is started, or the like. In the present embodiment, commands corresponding to the first special symbol lottery and the second special symbol lottery are set as the hold number designation commands.

The opening designation command is a command for designating the start of the opening period (start of the big hit gaming state). The opening designation command designates the type of the big hit gaming state to be started (= the type of stop symbol (one of the “big hit 1 symbol” to “big hit 6 symbols”)). The opening designation command is transmitted at the start of the opening period (at the start of the big hit gaming state).
The round start designation command is a command for designating the start of a round game. The round start designation command is transmitted at the start of the round game.
The round end designation command is a command for designating the end of the round game. The round end designation command is transmitted at the end of the round game.
The ending designation command is a command for designating the start of the ending period. The ending designation command is transmitted at the start of the ending period.

The first look-ahead designation command is a command for designating a stop symbol type (one of the “missing symbols” and “one jackpot symbol” to “six jackpot symbols”). In the present embodiment, the first prefetch designation command is set corresponding to each of the first special symbol lottery and the second special symbol lottery.
The second prefetch designation command is a command for designating the contents of the variation mode. Specifically, the second look-ahead designation command indicates that the type of variation mode is undefined (“undefined value”), or one of m types of variation modes (variation mode number) (“variation mode m”). ) Is specified. The second prefetch designation command is transmitted when starting information is stored.
The third prefetch designation command is a command for designating the contents of the variation pattern. Specifically, the third look-ahead designation command indicates that the type of variation pattern is undefined (“undefined value”) or one of n types of variation patterns (variation pattern numbers) (“variation pattern n”). ) Is specified. The third prefetch designation command is transmitted when starting information is stored.

The main control circuit 200 and the payout control circuit 400 are connected to each other via a harness for serial communication. Here, communication between the main control circuit 200 and the payout control circuit 400 is performed in both directions. Each control command transmitted / received between the main control circuit 200 and the payout control circuit 400 is composed of 1-byte data.
The main control circuit 200 transmits a control command to the payout control circuit 400 by serial communication. In the payout control circuit 400, when a control command is received from the main control circuit 200, a serial communication reception interrupt is generated, and the data of the control command is stored in a predetermined area of the RAM by this interrupt processing. Also, the payout control circuit 400 transmits a control command to the main control circuit 200 by serial communication. In the main control circuit 200, when a control command is received from the payout control circuit 400, a serial communication reception interrupt is generated, and the data of the control command is stored in a predetermined area of the RAM 230 by this interrupt processing.
In the pachinko machine 1, a prize ball number designation command or the like is set as a control command transmitted from the main control circuit 200 to the payout control circuit 400.
The prize ball number designation command is a command for designating the number of prize balls to be paid out. In the present embodiment, the prize ball number designation command designates the payout of n (n = 1 to 15) prize balls. The award ball number designation command is transmitted when the payout control circuit 400 executes the award ball payout operation.
Further, in the pachinko machine 1, control commands transmitted from the payout control circuit 400 to the main control circuit 200 include occurrence / release of payout errors, occurrence / release of full tank errors, occurrence / release of ball clogging errors, etc. Control commands that specify each are set. Each control command is transmitted upon detection of occurrence / release of various errors.

(Processing executed by main control circuit 200)
Next, processing executed by the main control circuit 200 will be described.
First, the functions of the hardware configured in the main control circuit 200 will be described.
When the pachinko machine 1 is powered on, the hard random number generation circuit 270 starts a hard random number update process.
In the hard random number update process, every time one clock is input from the frequency generation circuit 260 (in this embodiment, every 0.083 [μs]), the values of the first to third loop counters are within a predetermined range. Within the range (in the range of 0 to 65535 in this embodiment), it is updated by “1”.
In addition, in the hard random number update processing, every time 32 clocks are input from the frequency generation circuit 260 (in this embodiment, every 2.666 [μs]), the value of the fourth loop counter is within a predetermined range (this In the embodiment, “1” is updated in the range of 0 to 10006.
Then, the hard random number update process updates the normal symbol lottery random number, the first special symbol lottery big hit random number, the second special symbol lottery big hit random number, and the reach group random number. The hard random number update processing is executed as a function of the hard random number generation circuit 270 (hardware), and is executed independently of processing executed by the CPU 210 described later based on software.
When the power is turned on to the pachinko machine 1, the transmission shift register of the command output ports 1 and 2 transmits the control command stored in the FIFO buffer to the effect control circuit 300 or the payout control circuit 400. Starts the control command transmission process. The control command transmission process is executed as a function of the command output ports 1 and 2 (hardware), and is executed independently of the process executed by the CPU 210 described later based on software.

Next, game control processing executed by the CPU 210 of the main control circuit 200 based on a program (software) stored in the ROM 220 will be described.
FIG. 5 is a flowchart showing the CPU initialization process.
When the pachinko machine 1 is powered on, the CPU 210 starts the CPU initialization process shown in FIG. The CPU initialization process is a process based on a program for controlling the progress of the game. That is, the CPU initialization process is based on a program stored in the use area m1 (program area) of the ROM 220.
When the CPU initialization process is started, first, the process proceeds to step S1-1.
In step S1-1, an initial setting process is executed, and the process proceeds to step S1-2. In the initial setting process, a startup program is read from the ROM 220 and settings necessary for executing various processes are performed.
In step S1-2, a wait processing time setting process is executed, and the process proceeds to step S1-3. In the wait processing time setting process, a predetermined wait processing time is set in the timer counter. Then, measurement of the set wait processing time by the timer counter is started. Also, the RAM clear signal is read.
Here, the pachinko machine 1 is provided with a ram clear switch (not shown). When the power is turned on while the ram clear switch is pressed, a ram clear signal is input to the input port 240 (input port 1).
In the RAM clear signal reading process, a value (“1” or “0”) set in the reception storage area corresponding to the ram clear signal of the input port 240 is read.

In step S1-3, it is determined whether or not the wait processing time set in step S1-2 has elapsed. If it is determined that the wait processing time has elapsed (Yes), the process proceeds to step S1-4. If it is determined that the wait processing time has not elapsed (No), the process of step S1-3 is repeated.
In step S1-4, a RAM access permission process is executed, and the process proceeds to step S1-5. In the RAM access permission processing, processing necessary for permitting access to the work area of the RAM 230 is executed.
Specifically, in the RAM access permission process, a value corresponding to access permission is stored as a RAM protect value in a predetermined area of the RAM 230. As a result, access to the RAM 230 by the CPU 210 is permitted.
In step S1-5, it is determined whether or not “1” is set in the backup effective flag area of the RAM 230, and if it is determined that “1” is set in the backup effective flag area (Yes), If the process proceeds to step S1-6 and it is determined that “0” is set in the backup valid flag area (No), the process proceeds to step S1-17.

In step S1-6, a used area checksum calculation process is executed, and the process proceeds to step S1-7. In the used area checksum calculation process, the checksum is calculated based on information stored in the used area M1 (F000H to F1FFH) of the RAM 230 among the backup information.
In step S1-7, a non-use area checksum calculation process is executed, and the process proceeds to step S1-8. In the non-use area checksum calculation process, the checksum is calculated based on the information stored in the non-use area M2 (F210H to F228H) of the RAM 230 in the backup information.
In step S1-8, it is determined whether or not the checksum calculated in steps S1-6 and S1-7 is normal. If it is determined that the checksum is normal (Yes), step S1-9 is performed. If it is determined that the checksum is not normal (No), the process proceeds to step S1-17.
Here, “the checksum value of the use area M1 calculated in step S1-6 matches the checksum value of the use area M1 stored in the checksum buffer area” and “step S1- When the checksum value of the non-use area M2 calculated in step 7 matches the checksum value of the non-use area M2 stored in the checksum buffer area " It is determined that the checksum is normal.
On the other hand, “the checksum value of the use area M1 calculated in step S1-6 matches the checksum value of the use area M1 stored in the checksum buffer area” and “step S1-7. The checksum value of the non-use area M2 calculated in step 1 matches the checksum value of the non-use area M2 stored in the checksum buffer area ”. If not, it is determined that the checksum is not normal.

In step S1-9, based on the value read in step S1-2 (value set in the reception storage area corresponding to the ram clear signal), it is determined whether or not the ram clear signal is input. If it is determined that no input has been made (No), the process proceeds to step S1-10. If it is determined that a ram clear signal has been input (Yes), the process proceeds to step S1-18.
In step S1-10, a backup valid flag release process is executed, and the process proceeds to step S1-11. In the backup valid flag release process, “0” is set in the backup valid flag area of the RAM 230.
In step S1-11, initialization processing at the time of power recovery is executed, and the process proceeds to step S1-12. In the power recovery initialization process, the RAM 230 initializes data to be initialized (cleared) when the power is restored (when the data before the power is shut off) is maintained.
In step S1-12, a power recovery subcommand transmission process is executed, and the process proceeds to step S1-13. In the subcommand transmission process at the time of power recovery, a subcommand (control command transmitted from the main control circuit 200 to the effect control circuit 300) specifying that the power supply has been recovered is stored in the subcommand output request buffer of the RAM 230. To do. Further, a subcommand for designating a value set in the setting information storage area is stored in the subcommand output request buffer of the RAM 230.
In step S1-13, a power supply return payout command transmission process is executed, and the process proceeds to step S1-14. In the power return payout command transmission process, a payout command (control command transmitted from the main control circuit 200 to the payout control circuit 400) designating that the power supply has been recovered from the power shutdown is stored in the payout command output request buffer of the RAM 230. To do.

In step S1-14, an effect return subcommand transmission process is executed, and the process proceeds to step S1-15. In the effect return subcommand transmission process, the effect return subcommand (power recovery return phase designation command, gaming state designation command, power supply restoration designation command, etc.) is stored in the subcommand output request buffer of the RAM 230.
Here, the “power supply restoration phase designation command” is a control command for designating a special game phase in which the performance is restored.
In the effect return subcommand transmission process, first, the current special game phase is confirmed based on the value of the special game phase flag set in a predetermined area of the RAM 230. Then, a power return phase designation command for designating the confirmed special game phase is stored in the subcommand output request buffer of the RAM 230.
Also, a gaming state offset value is calculated based on the current gaming state. Specifically, the value of the time reduction control flag set in a predetermined area of the RAM 230, the value of the special figure high probability state flag, the value of the previous big hit symbol flag, and the value of the rotation number counter after the big hit are confirmed. Then, a gaming state offset value corresponding to the confirmation result is calculated. Then, a gaming state designation command that designates the calculated gaming state offset value is stored in the subcommand output request buffer of the RAM 230.
In step S1-15, an interrupt setting process is executed, and the process proceeds to step S1-16. In the interrupt initial setting process, the CTC (counter / timer circuit), which is a peripheral device, is initialized.
Specifically, the CPU 210 sets an interrupt vector register, and sets an interrupt count value (4.0 [ms] in the present embodiment) in the CTC.

In step S1-16, a set value change permission process is executed, and the process proceeds to a main loop process (step S2-1).
In the set value change permission process, first, it is determined whether or not a set value change permission condition is satisfied. If it is determined that the set value change permission condition is satisfied, “1” is set in the set value change permission flag area of the RAM 230. On the other hand, when it is determined that the set value change permission condition is not satisfied, “0” is set in the set value change permission flag area of the RAM 230.
In the present embodiment, both “the detection signal is input from the key rotation detection switch 111” and “the inner frame unit 3 is opened (or the integrated door unit 4 is opened)”. If the above condition is satisfied, it is determined that the set value change condition is satisfied.
On the other hand, at least one of “the detection signal is input from the key rotation detection switch 111” and “the inner frame unit 3 is opened (or the integrated door unit 4 is opened)”. If the above condition is not satisfied, it is determined that the set value change condition is not satisfied.
In addition, when both the conditions that “the detection signal is input from the key rotation detection switch 111” and “the door opening information (external signal) is being output” are satisfied, the setting value change condition is satisfied. Determined and set when at least one of the conditions that "the detection signal is input from the key rotation detection switch 111" and "the door opening information (external signal) is being output" is not satisfied It may be configured to determine that the value change condition is not satisfied.

In step S1-17, a non-use area initialization process is executed, and the process proceeds to step S1-18. In the unused area initialization process, the unused area M2 in the RAM 230 is initialized.
Specifically, in the unused area initialization process, information stored in the unused area M2 is cleared (initialized). As a result, the work area and the stack area of the non-use area M2 are all initialized, and even if valid backup information is stored, the contents are erased.
In step S1-18, a use area initialization process is executed, and the process proceeds to step S1-19. In the use area initialization process, the use area M1 in the RAM 230 is initialized.
Specifically, in the use area initialization process, information stored in the use area M1 is cleared (initialized). As a result, the work area and the stack area of the use area M1 are all initialized, and even if valid backup information is stored, the contents are erased.
That is, predetermined initial values are set as values of various flag areas (time-short control flag area, special figure high probability state flag area, previous big hit symbol flag area, special game phase flag area, normal game phase flag area, etc.) . Also, predetermined initial values (“0” in the present embodiment) are set as the values of various counter areas (time-short counter area, big hit post-rotation counter area, etc.). Further, a predetermined initial value (“3” in the present embodiment) is set in the setting information storage area.
In this embodiment, when the checksum is not normal, the use area M1 is initialized after the non-use area M2 is initialized. On the other hand, when the checksum is normal, the use area M1 is initialized only when the RAM clear signal is input.
As a result, as long as the checksum is normal, even if the RAM clear signal is input, the non-use area M2 is not initialized. Therefore, even if the RAM clear switch is operated, information on the base ratio (not used) Information stored in the area M2) can be maintained.

In step S1-19, a RAM clear subcommand transmission process is executed, and the process proceeds to step S1-20. In the RAM clear subcommand transmission process, a subcommand designating that the RAM clear has been executed is stored in the subcommand output request buffer of the RAM230. In addition, a subcommand designating a value (setting value = “3”) set in the setting information storage area is stored in the subcommand output request buffer of the RAM 230.
In step S1-20, a RAM clear payout command transmission process is executed, and the process proceeds to step S1-14. In the RAM clear payout command transmission process, a payout command designating that the RAM clear has been executed is stored in the payout command output request buffer of the RAM 230.

Next, main loop processing executed by the CPU 210 will be described.
FIG. 6 is a flowchart showing the main loop process.
When the CPU initialization process (step S1-16) shown in FIG. 5 ends, the CPU 210 starts the main loop process shown in FIG. The main loop process is a process based on a program for controlling the progress of the game. That is, the main loop process is a process based on a program stored in the use area m1 (program area) of the ROM 220.
When the main loop process is started, first, the process proceeds to step S2-1.
In step S2-1, an interrupt prohibition process is executed and the process proceeds to step S2-2. In the interrupt prohibition process, an interrupt prohibition state for prohibiting interrupts of other processes is set. As a result, during a period in which the interrupt disabled state is set, execution of power-off saving processing, timer interrupt processing, and the like, which will be described later, is prohibited.
In step S2-2, an initial value random number update process is executed, and the process proceeds to step S2-3. In the initial value random number update process, the value of the loop counter for generating the initial value random number is updated.
Here, the “initial value random number” is a random number for determining an initial value and an end value of a soft random number (a winning design random number, a reach mode random number, a variation pattern random number, etc.) that is a random number generated in the program.
That is, the value of the loop counter that generates the soft random number is updated within a range from a preset initial value to an end value. The initial value and end value of the loop counter that generates the soft random number are changed every time the value of the loop counter reaches the end value. At this time, the initial value and end value of the loop counter are determined based on the initial value random number.

In step S2-3, main command analysis processing is executed, and the process proceeds to step S2-4. In the main command analysis process, a main command received from the payout control circuit 400 (a control command transmitted from the payout control circuit 400 to the main control circuit 200) is analyzed, and a process according to the analysis result is executed.
In step S2-4, a subcommand transmission process is executed, and the process proceeds to step S2-5. In the subcommand transmission process, the subcommand stored in the subcommand output request buffer of the RAM 230 is output to the transmission data register of the output port 250 (command output port 1).
As a result, the subcommand input to the transmission data register is stored (stored) in the FIFO buffer. Then, the subcommands stored in the FIFO buffer are transmitted to the effect control circuit 300 in a predetermined order by the transmission shift register.
In step S2-5, an interrupt permission process is executed, and the process proceeds to step S2-6. In the interrupt enable process, the interrupt disabled state is canceled. As a result, during the period from the execution of the interrupt permission process in step S2-5 to the execution of the interrupt prohibition process in step S2-1, execution of the power-off saving process, timer interrupt process, etc. is permitted. Interrupt enabled period.
In step S2-6, other random number update processing is executed, and the process proceeds to step S2-1. In the other random number update process, soft random numbers excluding the winning design random numbers (reach mode random numbers, fluctuation pattern random numbers, etc.) are updated.

Next, the power-off saving process executed by the CPU 210 will be described.
FIG. 7 is a flowchart showing the power-off saving process.
The power supply circuit 600 is connected to a power cutoff detection circuit (not shown). The power shutdown detection circuit monitors the power supply voltage supplied by the power supply circuit 600 and outputs a power shutdown notice signal to the main control circuit 200 when the value of the power supply voltage falls below a predetermined reference value. .
When the CPU 210 receives the power shutdown notice signal, the CPU 210 starts the power shutdown process shown in FIG. 7 during the interrupt permission period of the main loop process. The power saving shutdown process is a process based on a program for controlling the progress of the game. That is, the power-off saving process is a process based on a program stored in the use area m1 (program area) of the ROM 220.
When the power saving shutdown process is started, first, the process proceeds to step S3-1.
In step S3-1, a register saving process is executed, and the process proceeds to step S3-2. In the register saving process, the register value used during the execution of the main loop process is saved in the saving area of the RAM 230.
In step S3-2, a power-off notice signal reading process is executed, and the process proceeds to step S3-3. In the power shutdown notice signal reading process, the power shutdown notice signal is read from the power shutdown detection circuit.
Specifically, in the power shutdown notice signal reading process, a value (“1” or “0”) set in the reception storage area corresponding to the power shutdown notice signal of the input port 240 is read.
In step S3-3, based on the value read in step S3-2 (value set in the reception storage area corresponding to the power shutdown notice signal), is the power shutdown notice signal input from the power shutdown detection circuit? If it is determined (bit check) and it is determined that the power shutdown notice signal is input (Yes), the process proceeds to step S3-4, and it is determined that the power shutdown notice signal is not input. In (No), it transfers to step S3-14.

In step S3-4, an output port stop process is executed, and the process proceeds to step S3-5. In the output port stop process, output of control signals and control commands by the output port 250 (output port 0 to output port 4) is stopped. Further, the detection signal input to the input port 240 (input port 0 to input port 3) is stopped.
In step S3-5, a used area checksum storage process is executed, and the process proceeds to step S3-6. In the used area checksum storage process, a checksum is calculated based on information stored in the used area M1 (F000H to F1FFH) of the RAM 230. Then, the calculated checksum value is stored in the checksum buffer area.
In step S3-6, a non-use area checksum storage process is executed, and the process proceeds to step S3-7. In the non-use area checksum saving process, the checksum is calculated based on the information stored in the non-use area M2 (F210H to F228H) of the RAM 230. Then, the calculated checksum value is stored in the checksum buffer area.
In step S3-7, a backup valid flag setting process is executed, and the process proceeds to step S3-8. In the backup valid flag setting process, “1” is set in the backup valid flag area of the RAM 230.
In step S3-8, a RAM access prohibition process is executed, and the process proceeds to step S3-9. In the RAM access prohibition process, a process for prohibiting access to the work area of the RAM 230 is executed.
Specifically, in the RAM access prohibition process, a value corresponding to access prohibition is stored as a RAM protect value in a predetermined area of the RAM 230. As a result, access to the work area (including the use-prohibited area and the stack area) of the RAM 230 by the CPU 210 is prohibited.

In step S3-9, a loop counter setting process is executed, and the process proceeds to step S3-10. In the loop counter setting process, a predetermined number of times of power-off notice signal reading is set as the value of the return determination loop counter.
In step S3-10, a power-off notice signal reading process is executed, and the process proceeds to step S3-11. In the power shutdown notice signal reading process, the power shutdown notice signal is read from the power shutdown detection circuit.
Specifically, in the power shutdown notice signal reading process, a value (“1” or “0”) set in the reception storage area corresponding to the power shutdown notice signal of the input port 240 is read.
In step S3-11, based on the value read in step S3-10 (value set in the reception storage area corresponding to the power-off notice signal), is the power-off notice signal input from the power-off detection circuit? If it is determined that the power-off notice signal is not input (No), the process proceeds to step S3-12, and if it is determined that the power-off notice signal is input (Yes). Shifts to Step S3-9.
In step S3-12, loop counter update processing is executed, and the flow proceeds to step S3-13. In the loop counter update process, a value obtained by subtracting “1” from the value set in the return determination loop counter is newly set in the return determination loop counter.
In step S3-13, it is determined whether or not the value of the return determination loop counter is “0”. If it is determined that the value of the return determination loop counter is “0” (Yes), the CPU When the process proceeds to the initialization process (step S1-1) and it is determined that the value of the return determination loop counter is not “0” (No), the process proceeds to step S3-10.
In step S3-14, a register return process is executed, a series of processes are terminated, and the process returns to the original process. In the register restoration process, the register value saved in step S3-1 is restored. Then, after the completion of the register restoration process, the process returns to the main loop process (program address indicated by the stack pointer).

Next, timer interrupt processing executed by the CPU 210 will be described.
FIG. 8 is a flowchart showing timer interrupt processing.
The frequency generation circuit 260 generates an interrupt request signal every predetermined interrupt cycle (4.0 [ms] in the present embodiment).
In response to the generation of the interrupt request signal, the CPU 210 starts the timer interrupt process shown in FIG. 8 during the interrupt permission period of the main loop process. The main loop process is a process based on a program for controlling the progress of the game. That is, the main loop process is a process based on a program stored in the use area m1 (program area) of the ROM 220.
When the timer interrupt process is started, first, the process proceeds to step S4-1.
In step S4-1, a register saving process is executed, and the process proceeds to step S4-2. In the register saving process, all register values used during the execution of the main loop process are saved in the saving area of the RAM 230.
In step S4-2, an interrupt permission process is executed, and the process proceeds to step S4-3. In the interrupt permission process, an interrupt is permitted.
In step S4-3, a set value management process is executed, and the process proceeds to step S4-4. The set value management process will be described later.

In step S4-4, dynamic port output processing is executed, and the process proceeds to step S4-5. In the dynamic port output process, a control signal is output to each LED constituting the main display device 60 and the performance display device 61.
Specifically, in the dynamic port output process, first, the values of all bits included in the port register of the output port 0 are initialized. As a result, the output of each data signal (“SEGDATA0” to “SEGDATA7”) is stopped (becomes a low level).
Next, the values of all the bits included in the port register of the output port 4 are initialized. As a result, the output of each data signal (“7SEGDATA0” to “7SEGDATA7”) is stopped (becomes a low level).
Next, the common signal control data set in the common signal control data setting area included in the dynamic port output request buffer of the RAM 230 is updated. Thus, each time the dynamic port output process is executed, the common signal to be output (common signal to be high level) is switched. In the present embodiment, lighting of the main display 60 and the performance display device 61 is controlled by a common common signal.
Next, the output of each common signal (each of “COM0” to “COM3”) by the output port 1 is controlled in accordance with the common signal control data set in the common signal control data setting area.
Next, according to the main display data signal control data set in the main display data signal control data setting area included in the dynamic port output request buffer of the RAM 230, each data signal (“SEGDATA0” to “SEGDATA0” to “ SEGDATA7 ") output is controlled.
Next, according to the performance display device data signal control data set in the performance display device data signal control data setting area included in the dynamic port output request buffer of the RAM 230, each data signal ("7SEGDATA0" to "7SEGDATA0" to "" 7SEGDATA7 ") is controlled.

In step S4-5, port input processing is executed, and the process proceeds to step S4-6. In the port input process, the latest switch state is accurately acquired.
Specifically, in the port input process, it is determined whether or not an ON state has occurred for each detection signal input to the input port 240 (input port 0 to input port 3). At this time, based on the information set in the reception storage area corresponding to each detection signal (each detection switch / detection sensor), it is determined whether or not the detection signal is on. When it is determined that an ON state has occurred for each detection signal, information indicating that the ON state has occurred (detected) for the detection signal is stored in a predetermined area of the RAM 230.
Here, the “on state” refers to a state in which the detection signal is not input (low level) to a state where the detection signal is input (high level).

In step S4-6, timer update processing is executed, and the process proceeds to step S4-7. In the timer update process, various timers are updated. Specifically, in the timer update process, the values of various timer counters (special game timer, normal game timer, external information timer, etc.) are updated.
In step S4-7, an initial value random number update process is executed, and the process proceeds to step S4-8. The initial value random number update process in step S4-7 is the same process as the initial value random number update process in step S2-2. Specifically, in the initial value random number update process, the value of the loop counter for generating the initial value random number is updated.
In step S4-8, a winning symbol random number update process is executed, and the process proceeds to step S4-9. In the winning symbol random number update process, the value of the loop counter for generating the winning symbol random number among the soft random numbers is updated.
In step S4-9, switch management processing is executed, and the process proceeds to step S4-10. In the switch management processing, processing (acquisition of various random numbers, etc.) corresponding to the state of each switch 101, 102, 104 (whether or not an on state is detected) is executed. The switch management process will be described later.

In step S4-10, an addition number calculation process is executed, and the process proceeds to step S4-11. In the addition number calculation process, a value to be added to an out-ball number counter described later and a value to be added to a payout number counter described later are calculated and set.
That is, in the addition number calculation process, first, it is determined whether or not a predetermined gaming state. And when it determines with it not being a predetermined | prescribed gaming state, the non-predetermined gaming state addition number calculation process mentioned later is performed. On the other hand, when it is determined that the game state is the predetermined game state, an addition number calculation process for a predetermined game state described later is executed.
In the present embodiment, when the “special figure low probability state” is occurring and when the time reduction control is stopped, it is determined that the game state is the predetermined game state. On the other hand, if at least one of the “special figure high probability state” is being generated and the time-shortening control is being executed, it is determined that the game state is not the predetermined game state.

In the non-predetermined gaming state addition number calculation process, first, the value stored in the out-ball number addition value storage area is cleared, and the value stored in the payout number addition value storage area is cleared.
Next, “0” is set as a value to be added to the out ball number counter in the out ball number addition value storage area of the RAM 230.
Next, “0” is set as a value to be added to the payout number counter in the payout number addition value storage area of the RAM 230.

On the other hand, in the predetermined gaming state addition number calculation process, first, the value stored in the out-ball number addition value storage area is cleared, and the value stored in the payout number addition value storage area is cleared. Also, “0” is set as the value of the payout number calculation counter.
Next, it is determined whether or not the ON state of the out switch 109 has been detected. If it is determined that the ON state of the out switch 109 has been detected, “1” is set as a value to be added to the out ball number counter in the out ball number addition value storage area of the RAM 230. On the other hand, if it is determined that the ON state of the out switch 109 has not been detected, “0” is set as a value to be added to the out ball number counter in the out ball number addition value storage area of the RAM 230.
Next, it is determined whether or not the ON state of the right winning opening switch winning ball 105 is detected. When it is determined that the ON state of the right winning opening switch winning ball 105 has been detected, the winning ball paid out in accordance with the game ball entering the right other winning port 54 as the value of the payout number calculation counter The number “10” is added. On the other hand, when it is determined that the ON state of the right winning opening switch winning ball 105 is not detected, addition to the value of the payout number calculation counter is not executed.
Next, it is determined whether or not the on state of the left winning port switch winning ball 106 is detected. If it is determined that the on state of the left winning port switch winning ball 106 has been detected, the value of the payout number calculation counter is paid out according to the game ball entering the left other winning ports 55-57. Add “10” which is the number of prize balls. On the other hand, when it is determined that the ON state of the left winning opening switch winning ball 106 is not detected, the addition to the value of the payout number calculation counter is not executed.
Next, it is determined whether or not the ON state of the special figure 1 start port switch 101 is detected. When it is determined that the ON state of the special figure 1 start port switch 101 has been detected, a prize ball is paid out in accordance with the game ball entering the first start port 51 as the value of the payout number calculation counter. The number “3” is added. When it is determined that the on-state of the special opening 1 is not detected, addition to the value of the payout number calculation counter is not executed.
Next, it is determined whether or not the ON state of the special figure 2 start port switch 102 is detected. When it is determined that the ON state of the special figure 2 start port switch 102 is detected, a prize ball that is paid out in accordance with the game ball entering the second start port 52 as the value of the payout number calculation counter. The number “1” is added. When it is determined that the ON state of the special figure 2 start port switch 102 is not detected, the addition to the value of the payout number calculation counter is not executed.
Next, in the payout amount addition value storage area of the RAM 230, the value of the payout number calculation counter is set as a value to be added to the payout number counter.

In step S4-11, a special game management process is executed, and the process proceeds to step S4-12. In the special game management process, the operation of the special figure display device and the operation of the special electric accessory 53a are managed. The special game management process will be described later.
In step S4-12, a normal game management process is executed, and the process proceeds to step S4-13. In the ordinary game management process, the operation of the general-purpose display device and the operation of the ordinary electric accessory 52a are managed. The normal game management process will be described later.

In step S4-13, error management processing is executed, and the process proceeds to step S4-14. In the error management process, various errors (abnormal conditions) are determined, and settings are made according to the determination results.
In step S4-14, a winning opening switch process is executed, and the process proceeds to step S4-15. In the winning opening switch processing, processing (update of various counters, etc.) corresponding to the state of each switch 101 to 103, 105, 106 (whether or not an on state is detected) is executed.
In step S4-15, a payout control management process is executed, and the process proceeds to step S4-16. In the payout control management process, a payout command is generated based on the value of the prize ball control counter set in step S4-14, and the generated payout command is transmitted.
In the present embodiment, as the prize ball control counter, the prize ball control counter 1 that stores the number of ball game balls that have entered the big prize opening 53 and the number of ball game balls that have entered the right other prize opening 54 are stored. The prize ball control counter 2, the prize ball control counter 3 in which the number of ball game balls entered in the upper left / left middle / lower left winning holes 55 to 57 are stored, and the ball game ball entered in the first start opening 51 And the prize ball control counter 4 in which the number of ball game balls that have entered the second start port 52 are stored.

In the payout control management process, first, it is determined whether or not the value of the prize ball control counter 1 is “1” or more. When it is determined that the value of the prize ball control counter 1 is “1” or more, a payout command for designating a predetermined number (15 balls in this embodiment) of payout balls is generated, The generated payout command is stored in the payout command output request buffer of the RAM 230. As a result, a payout command designating the payout of a predetermined number of prize balls is transmitted to the payout control circuit 400. Then, when the payout control circuit 400 completes the payout of the prize ball by the game ball payout device 440, the payout control circuit 400 transmits a main command designating the completion of the payout to the main control circuit 200. Then, “1” is subtracted from the value of the prize ball control counter 1 in response to reception of the main command designating completion of the payout.
Next, it is determined whether or not the value of the prize ball control counter 2 is “1” or more. If it is determined that the value of the prize ball control counter 2 is “1” or more, a payout command for designating a predetermined number (in this embodiment, 10 [balls]) of payout balls is generated, The generated payout command is stored in the payout command output request buffer of the RAM 230. As a result, a payout command designating the payout of a predetermined number of prize balls is transmitted to the payout control circuit 400. Thereafter, “1” is subtracted from the value of the prize ball control counter 2 in response to reception of the main command designating completion of the payout.
Next, it is determined whether or not the value of the prize ball control counter 3 is “1” or more. When it is determined that the value of the prize ball control counter 3 is “1” or more, a payout command for designating a predetermined number (10 balls in this embodiment) of prize balls is generated, The generated payout command is stored in the payout command output request buffer of the RAM 230. As a result, a payout command designating the payout of a predetermined number of prize balls is transmitted to the payout control circuit 400. Thereafter, “1” is subtracted from the value of the prize ball control counter 3 in response to reception of the main command designating completion of the payout.
Next, it is determined whether or not the value of the prize ball control counter 4 is “1” or more. When it is determined that the value of the prize ball control counter 4 is “1” or more, a payout command for designating a predetermined number (3 [balls] in this embodiment) of payout of prize balls is generated, The generated payout command is stored in the payout command output request buffer of the RAM 230. As a result, a payout command designating the payout of a predetermined number of prize balls is transmitted to the payout control circuit 400. Thereafter, “1” is subtracted from the value of the prize ball control counter 4 in response to reception of the main command designating completion of the payout.
Next, it is determined whether or not the value of the prize ball control counter 5 is “1” or more. When it is determined that the value of the prize ball control counter 5 is “1” or more, a payout command for designating a predetermined number (1 [ball] in the present embodiment) of payout balls is generated, The generated payout command is stored in the payout command output request buffer of the RAM 230. As a result, a payout command designating the payout of a predetermined number of prize balls is transmitted to the payout control circuit 400. Thereafter, “1” is subtracted from the value of the prize ball control counter 5 in response to reception of the main command designating completion of the payout.

In step S4-16, a launch position designation management process is executed, and the process proceeds to step S4-17. In the launch position designation management process, a process related to launch position designation is executed.
Specifically, in the launch position designation management process, when changing from a state in which the launch of the game ball to the left route is designated to a state in which the launch of the game ball to the right route is designated (at the start of the big hit gaming state, etc.) In addition, a subcommand for designating the game ball to be placed on the right path is stored in the subcommand output request buffer of the RAM 230. As a result, a subcommand for designating the launch of the game ball on the right path is transmitted to the effect control circuit 300.

In step S4-17, an external information management process is executed, and the process proceeds to step S4-18. In the external information management process, external information (external signal) to be output to the hall computer 450 (or data display device) is set.
In the present embodiment, as the external information output from the pachinko machine 1 to the external device (the electronic device such as the hall computer 450 and the data display device), the symbol determination number information (OUT1), the start port information (OUT2), the jackpot Information (OUT3 to OUT6), security information, out-payout number information (OUT8), setting value changing information, and the like are defined.
The “symbol determined number information” is external information regarding the number of executions of the special symbol lottery (special symbol variation display and stop display). The CPU 210 outputs an external signal corresponding to the symbol determination number information to the hall computer 450 (or the data display device) every time the number of executions of the special symbol stop display reaches a predetermined number.
“Starting port information” is external information relating to the entrance of game balls into the starting ports 51 and 52. The CPU 210 outputs an external signal corresponding to the start port information to the hall computer 450 (or the data display device) every time an on state of the detection signals input from the start port switches 101 and 102 is detected. .
The “hit information” is external information regarding the occurrence of the big hit gaming state. The main control circuit 200 outputs an external signal corresponding to the jackpot information to the hall computer 450 (or data display device) every time a jackpot gaming state is generated.
The “out port payout information” is external information regarding the number of game balls discharged from the discharge path (or the number of game balls discharged from the out port 58). The CPU 210 outputs an external signal corresponding to the out-payout number information to the hall computer 450 every time the value of the external information out-ball number counter reaches a predetermined value.
“Setting value changing information” is external information indicating that the setting value is being changed (that the setting value change permission condition is satisfied). The CPU 210 always outputs an external signal corresponding to the setting value changing information to the hall computer 450 during the period in which “1” is set in the setting value changing flag area.

In the external information management process, it is determined whether or not the value of the external information confirmation number counter has reached a predetermined value (1 [times] in this embodiment). When it is determined that the value of the external information determination number counter has reached a predetermined value, the symbol determination number information (external signal) is stored in the port output request buffer of the RAM 230. Thereafter, a predetermined value (1 [times] in the present embodiment) is subtracted from the value of the external information determination number counter. As a result, symbol determination frequency information (external signal) is output to the hall computer 450.
Further, in the external information management process, it is determined whether or not the value of the external information start entrance ball number counter has reached a predetermined value (1 [times] in the present embodiment). Then, when it is determined that the value of the external information start opening ball count counter has reached a predetermined value, the start opening information (external signal) is stored in the port output request buffer of the RAM 230. Thereafter, a predetermined value (1 [times] in the present embodiment) is subtracted from the value of the external information start entrance ball number counter. Thereby, start port information (external signal) is output to the hall computer 450.
In the external information management process, it is determined whether or not the value of the external information jackpot counter has reached a predetermined value (1 [times] in this embodiment). If it is determined that the value of the external information jackpot counter has reached a predetermined value, the jackpot information (external signal) is stored in the port output request buffer of the RAM 230. Thereafter, a predetermined value (1 [times] in the present embodiment) is subtracted from the value of the external information jackpot counter. As a result, jackpot information (external signal) is output to the hall computer 450.
Further, in the external information management process, it is determined whether or not the value of the external information out ball counter reaches a predetermined value (10 [sphere] in the present embodiment). When it is determined that the value of the external information out ball counter has reached a predetermined value, the outlet payout information (external signal) is stored in the port output request buffer of the RAM 230. Thereafter, a predetermined value (10 [spheres] in the present embodiment) is subtracted from the value of the external information out ball counter. As a result, out-port payout information (external signal) is output to the hall computer 450.
Further, in the external information management process, it is determined whether or not “1” is set in the setting value changing flag area. If it is determined that “1” is set in the setting value changing flag area, the setting value changing information (external signal) is stored in the port output request buffer of the RAM 230. As a result, the setting value changing information (external signal) is output to the hall computer 450.

In step S4-18, a test signal management process is executed, and the process proceeds to step S4-19. In the test signal management process, test information (test signal) is set.
The test signal management process is a process based on a program for executing a process related to a test defined by the gaming machine rules. That is, the test signal management process is a process based on a program stored in the non-use area m2 (program area) of the ROM 220. The test signal tube is called during execution of the timer interrupt process.
Specifically, in the test signal management process, test information (test signal) indicating the internal state (big hit gaming state, execution state of short-time control, probability state of special symbol lottery, etc.) is stored in the port output request buffer of the RAM 230. To remember.
In step S4-19, a performance display device control process is executed, and the process proceeds to step S4-20. The performance display device control process will be described later.
In step S4-20, an LED display setting process is executed, and the process proceeds to step S4-21. In the LED display setting process, control data (drive data) for controlling lighting of a predetermined display device is set in the dynamic port output request buffer of the RAM 230.
In step S4-21, a solenoid data setting process is executed, and the process proceeds to step S4-22. In the solenoid data setting process, control data (drive data) output to the solenoids 64 and 65 is stored (set) in the port output request buffer of the RAM 230.

In step S4-22, port output processing is executed, and the process proceeds to step S4-23. In the port output process, various signals are output to the hall computer 450, the solenoids 64 and 65, and the like.
Specifically, in the port output process, various information (external signals, control signals, etc.) set in the port output request buffer is output to the output port 250 (output port 2, output port 3). As a result, the external signal set in the port output request buffer is output to the hall computer 450. Further, the solenoids 64 and 65 are driven and controlled based on the drive signal set in the port output request buffer.
In step S4-23, a register return process is executed, a series of processes are terminated, and the process returns to the original process. In the register restoration process, the register value saved in step S4-1 is restored. Then, after the completion of the register restoration process, the process returns to the main loop process (program address indicated by the stack pointer).

Next, the setting value management process in step S4-3 will be described.
FIG. 9 is a flowchart showing the set value management process.
When the set value management process is executed in step S4-3, as shown in FIG. 9, first, the process proceeds to step S29-1.
In step S29-1, it is determined whether or not “1” is set in the setting value change permission flag area, and when it is determined that “1” is set in the setting value change permission flag area (Yes). Shifts to step S29-2, and when it is determined that “0” is set in the set value change permission flag area (No), the series of processes is terminated and the next process (step S4-4) is performed. ).
In step S29-2, it is determined whether or not the set value change permission condition is satisfied. If it is determined that the set value change permission condition is satisfied (Yes), the process proceeds to step S29-3 and the set value is changed. If it is determined that the change permission condition is not satisfied (No), the process proceeds to step S29-6.
As described above, both “the detection signal is input from the key rotation detection switch 111” and “the inner frame unit 3 is opened (or the integrated door unit 4 is opened)”. If this condition is satisfied, it is determined that the setting value change condition is satisfied.
On the other hand, at least one of “the detection signal is input from the key rotation detection switch 111” and “the inner frame unit 3 is opened (or the integrated door unit 4 is opened)”. If this condition is not satisfied, it is determined that the set value change condition is not satisfied.
Note that when both the conditions that “the detection signal is input from the key rotation detection switch 111” and “the door opening information (external signal) is being output” are satisfied, the setting value change condition is satisfied. If “a detection signal is input from the key rotation detection switch 111” and “the door opening information (external signal) is being output” is not satisfied, The configuration may be such that it is determined that the set value change condition is not satisfied.

In step S29-3, it is determined whether or not a detection signal is input from the set value selection switch 112. If it is determined that a detection signal is input from the set value selection switch 112 (Yes), step S29 is performed. If it is determined that the detection signal is not input from the set value selection switch 112 (No), the series of processes is terminated and the process proceeds to the next process (step S4-4).
In step S29-4, a setting value changing process is executed, and the process proceeds to step S29-5. In the setting value changing process, the value (setting value) set in the setting information storage area is changed. Here, in this embodiment, every time a detection signal is input from the set value selection switch 112, a predetermined order (for example, set value = “1”, set value = “2”, set value = “3”, set value). Value = “4”, setting value = “5”, setting value = “6”, setting value = “1”, setting value = “2”.
In step S29-5, a set value display update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-4). In the set value display update process, the display of the set value on the set value display device 62 is updated.
Specifically, in the set value display update process, first, a subcommand for specifying a value (set value after change) set in the setting information storage area is stored in the subcommand output request buffer of the RAM 230.
In the set value display update process, next, the same value as the value (set value after change) set in the setting information storage area is set in the set value display counter. As a result, among the predetermined number of segments constituting the set value display device 62, the segment corresponding to the value of the set value display counter is controlled to be lit.
In the present embodiment, the display of the set value on the set value display device 62 is executed only during the period in which the set value change permission condition is satisfied.

In step S29-6, set value change end processing is executed, a series of processing ends, and the process proceeds to the next processing (step S4-4).
In the set value change end process, “0” is set in the set value change permission flag area. Also, the value of the set value display counter is initialized (cleared). As a result, all the segments constituting the set value display device 62 are extinguished (the display of the set value on the set value display device 62 ends).

Next, the switch management process in step S4-9 will be described.
FIG. 10 is a flowchart showing the switch management process.
When the switch management process is executed in step S4-9, the process proceeds to step S5-1 as shown in FIG.
In step S5-1, it is determined whether or not the on state of the gate switch 104 has been detected. If it is determined that the on state of the gate switch 104 has been detected (Yes), the process proceeds to step S5-2. If it is determined that the ON state of the switch 104 has not been detected (No), the process proceeds to step S5-3.
In step S5-2, a normal start ball detection process is executed, and the process proceeds to step S5-3. The normal start ball detection process will be described later.

In step S5-3, it is determined whether or not the ON state of the special figure 1 start opening switch 101 is detected. If it is determined that the ON state of the special figure 1 start opening switch 101 is detected (Yes), If the process proceeds to S5-4 and it is determined that the ON state of the special figure 1 start port switch 101 is not detected (No), the process proceeds to Step S5-5.
In step S5-4, the special figure 1 starting ball detection process is executed, and the process proceeds to step S5-5. The special figure 1 starting ball detection process will be described later.
In step S5-5, it is determined whether or not the ON state of the special figure 2 start port switch 102 has been detected. If it is determined that the ON state of the special figure 2 start port switch 102 has been detected (Yes), If the process proceeds to S5-6 and it is determined that the ON state of the special figure 2 start port switch 102 has not been detected (No), the series of processes is terminated and the process proceeds to the next process (Step S4-10). To do.
In step S5-6, the special figure 2 starting ball detection process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-10). The special figure 2 starting ball detection process will be described later.

Next, the normal starting ball detection process in step S5-2 will be described.
FIG. 11 is a flowchart showing a general-purpose starting ball detection process.
When the normal starting ball detection process is executed in step S5-2, as shown in FIG. 11, first, the process proceeds to step S6-1.
In step S6-1, a normal random number acquisition process is executed, and the process proceeds to step S6-2. In the normal random number acquisition process, a random number (random value) is acquired (loaded) from a loop counter corresponding to the normal symbol lottery.
In step S6-2, it is determined whether or not the value of the general-purpose hold number counter is the upper limit value (in this embodiment, “1”), and it is determined that the value of the general-purpose hold number counter is not the upper limit value In (No), the process proceeds to step S6-3, and when it is determined that the value of the general-purpose hold number counter is the upper limit value (Yes), the series of processes is terminated and the next process (step S5- Move to 3).
In step S6-3, the usual figure holding number counter update process is executed, and the process proceeds to step S6-4. In the usual figure pending number counter update process, a value obtained by adding "1" to the value set in the usual figure pending number counter is newly set in the usual figure pending number counter.
In step S6-4, a regular random number storage process is executed, a series of processes are terminated, and the process proceeds to the next process (step S5-3). In the usual random number saving process, the winning random number acquired in step S6-1 is stored in the usual figure starting information storage area of the RAM 230 as ordinary figure starting information.

Next, the special figure 1 starting ball detection process of step S5-4 will be described.
FIG. 12 is a flowchart showing the special figure 1 starting ball detection process.
When the special figure 1 starting ball detection process is executed in step S5-4, as shown in FIG. 12, first, the process proceeds to step S7-1.
In step S7-1, a special symbol identification value setting process is executed, and the process proceeds to step S7-2. In the special symbol identification value setting process, a special symbol identification value corresponding to the first special symbol lottery is set in the special symbol identification value setting area of the RAM 230. Also, “1” is added to the value of the external information start opening ball entry counter.
In step S7-2, a holding number counter address setting process is executed, and the process proceeds to step S7-3. In the holding number counter address setting process, the address of the special figure 1 holding number counter is set in the holding number counter address setting area of the RAM 230.
In step S7-3, a special symbol random number acquisition process is executed, a series of processes are terminated, and the process proceeds to the next process (step S5-5). The special symbol random number acquisition process will be described later.

Next, the special figure 2 starting ball detection process of step S5-6 will be described.
FIG. 13 is a flowchart showing the special figure 2 starting ball detection process.
When the special figure 2 starting ball detection process is executed in step S5-6, as shown in FIG. 13, first, the process proceeds to step S8-1.
In step S8-1, a special symbol identification value setting process is executed, and the process proceeds to step S8-2. In the special symbol identification value setting process, a special symbol identification value corresponding to the second special symbol lottery is set in the special symbol identification value setting area of the RAM 230. Also, “1” is added to the value of the external information start opening ball entry counter.
In step S8-2, a holding number counter address setting process is executed, and the process proceeds to step S8-3. In the holding number counter address setting process, the address of the special figure 2 holding number counter is set in the holding number counter address area of the RAM 230.
In step S8-3, a special symbol random number acquisition process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-10). The special symbol random number acquisition process will be described later.

Next, the special symbol random number acquisition process in steps S7-3 and S8-3 will be described.
FIG. 14 is a flowchart showing a special symbol random number acquisition process.
When the special symbol random number acquisition process is executed in steps S7-3 and S8-3, as shown in FIG. 14, first, the process proceeds to step S9-1.
In step S9-1, a special symbol identification value acquisition process is executed, and the process proceeds to step S9-2. In the special symbol identification value acquisition process, the special symbol identification value set in the special symbol identification value setting area of the RAM 230 is acquired (loaded).
In step S9-2, a special figure hold number acquisition process is executed, and the process proceeds to step S9-3. In the special figure hold number acquisition process, the value of the special figure hold number counter (the special figure 1 hold number counter or the special figure 2 hold number counter) specified by the address set in the hold number counter address area (the special figure 1 hold number) Number or special figure 2 hold number) is acquired (loaded).

In step S9-3, a special figure random number acquisition process is executed, and the process proceeds to step S9-4. In the special figure random number acquisition process, various random numbers (random values) such as big hit random numbers, hit design random numbers, reach group random numbers, reach mode random numbers, variation pattern random numbers are acquired (loaded) from the loop counter corresponding to each lottery. At this time, the corresponding loop counter is selected based on the special symbol identification value acquired in step S9-1.
In step S9-4, it is determined whether or not the special figure hold number (special figure 1 hold number or special figure 2 hold number) acquired in step S9-2 is an upper limit value ("4" in the present embodiment). If it is determined that the special figure hold number is not the upper limit value (No), the process proceeds to step S9-5. If it is determined that the special figure hold number is the upper limit value (Yes), a series of processes is performed. And the process proceeds to the next process (step S4-10 or S5-5).
In step S9-5, a special figure holding number counter update process is executed, and the process proceeds to step S9-6. In the special figure hold number counter update process, the value set in the special figure hold number counter (special figure 1 hold number counter or special figure 2 hold number counter) specified by the address set in the hold number counter address area A value obtained by adding “1” to is newly set in the special figure holding number counter.

In step S9-6, a special figure random number storage process is executed, and the process proceeds to step S9-7. In the special figure random number storage process, the various random numbers acquired in step S9-3 are used as special figure start information (special figure 1 start information or special figure 2 start information) as a special figure start information storage area (special figure 1 start). Information storage area or special figure 2 start information storage area).
Specifically, the RAM 230 stores a changing start information storage area in which start information during execution of special symbol notification display is stored, and a special figure 1 start information in which start determination is suspended. It includes a start information storage area and a special figure 2 start information storage area where start determination is suspended.
The special figure 1 start information storage area includes a first storage part to a fourth storage part as a storage part capable of storing the special figure 1 start information. Different priority orders are defined in the first storage unit to the fourth storage unit. That is, the priority order of each storage unit is defined to be the first storage unit, the second storage unit, the third storage unit, and the fourth storage unit (upper order → lower order) in descending order of priority. . The special figure 1 start information stored in the special figure 1 start information storage area is subjected to start determination in order from the special figure 1 start information stored in the higher priority storage unit.
The special figure 2 start information storage area includes a first storage part to a fourth storage part as a storage part capable of storing the special figure 2 start information. Different priority orders are defined in the first storage unit to the fourth storage unit. That is, the priority order of each storage unit is defined to be the first storage unit, the second storage unit, the third storage unit, and the fourth storage unit (upper order → lower order) in descending order of priority. . And the special figure 2 starting information memorize | stored in the special figure 2 starting information storage area performs starting determination in an order from the special figure 2 starting information memorize | stored in the memory | storage part with a high priority.

If the special symbol identification value acquired in step S9-1 is a value corresponding to the first special symbol lottery, the various random numbers acquired in step S9-3 are used as the special diagram 1 start information. 1 Store in the start information storage area. At this time, the various random numbers acquired in step S9-3 are stored in the highest priority storage unit among the free storage units. Specifically, when the value of the current special figure 1 hold number counter = “1”, the various random numbers acquired in step S9-3 are stored in the first storage unit. On the other hand, if the current value of the special figure 1 holding number counter = “2”, the various random numbers acquired in step S9-3 are stored in the second storage unit. If the value of the current special figure 1 hold number counter = “3”, the various random numbers acquired in step S9-3 are stored in the third storage unit. If the value of the current special figure 1 hold number counter = “4”, the various random numbers acquired in step S9-3 are stored in the fourth storage unit.
On the other hand, when the special symbol identification value acquired in step S9-1 is a value corresponding to the second special symbol lottery, the various random numbers acquired in step S9-3 are used as the special diagram 2 starting information. 2 Store in the start information storage area. At this time, the various random numbers acquired in step S9-3 are stored in the highest priority storage unit among the free storage units. Specifically, when the value of the current special figure 2 hold number counter = “1”, the various random numbers acquired in step S9-3 are stored in the first storage unit. On the other hand, if the value of the current special figure 2 hold number counter = “2”, the various random numbers acquired in step S9-3 are stored in the second storage unit. If the value of the current special figure 2 hold number counter = “3”, the various random numbers acquired in step S9-3 are stored in the third storage unit. When the value of the current special figure 2 hold number counter = “4”, the various random numbers acquired in step S9-3 are stored in the fourth storage unit.

  In step S9-7, the number-of-holds designation command setting process is executed, and the process proceeds to step S9-8. In the hold number designation command setting process, a hold number designation command for designating that the special figure hold number (the special figure 1 hold number or the special figure 2 hold number) has increased by “1” is stored in the subcommand output request buffer of the RAM 230. To do. At this time, if the special symbol identification value acquired in step S9-1 is a value corresponding to the first special symbol lottery, the number-of-holds designation command for designating that the number of special symbol 1 reservations has increased by "1" Is stored in the sub-command output request buffer of the RAM 230, and if the value corresponds to the second special symbol lottery, a hold number designation command for designating that the special figure 2 hold number has increased by "1" is stored in the RAM 230. Is stored in the subcommand output request buffer.

In step S9-8, a pre-determination process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-10 or S5-5). In the pre-determination process, the start information (the special figure 1 start information or the special figure) saved (stored) in the special figure start information storage area (the special figure 1 start information storage area or the special figure 2 start information storage area) in step S9-6. (2 start information) (hereinafter referred to as “preliminary determination start information”), various lottery results are determined in advance.
In this embodiment, pre-determination of various lottery results is executed for all start information (Special Figure 1 start information and Special Figure 2 start information).
Note that the start information acquired (stored) during the occurrence of the big hit gaming state may be configured such that prior determination of various lottery results is not executed. In addition, for the special figure 2 start information acquired (stored) during stoppage of the time reduction control, the preliminary determination of various lottery results is not executed, and the special figure 1 start information acquired (stored) during execution of the time reduction control. With regard to, it is possible to adopt a configuration in which the preliminary determination of various lottery results is not executed.

In the preliminary determination process, first, a preliminary special figure winning determination process is executed.
In the special special symbol winning determination process, a special symbol lottery result ("big hit" or "out of game") is determined (preliminary special symbol winning determination).
The ROM 220 stores a special symbol winning lottery table in which special bonus lottery values are registered. In addition, the special figure winning lottery table corresponds to each combination of a set value ("1" to "6") and a gaming state ("special figure low probability state" or "special figure high probability state"). The special figure winning lottery table is stored.
Specifically, as the special figure winning lottery table, “setting value 1 low-accuracy special figure winning lottery table”, “setting value 1 high-accuracy special drawing winning lottery table”, and “setting value 2 low-probability special lottery table”. "Figure winning lottery table", "Set value 2 high accuracy special figure winning lottery table", "Set value 3 low accuracy special figure winning lottery table" and "Set value 3 high accuracy special figure winning lottery table" “Set value 4 low-accuracy special map winning lottery table”, “Set value 4 high-accuracy special map winning lottery table”, “Set value 5 low-accuracy special map winning lottery table”, “Setting value A “5 high-accuracy special figure winning lottery table”, a “set value 6 low-accuracy special figure winning lottery table”, and a “set value 6 high-accuracy special figure winning lottery table” are stored.

In the “set value 1 low probability special figure winning lottery table”, the set value = “1” and “0” is set in the special figure high probability state flag area (occurrence of “special figure low probability state” Selected). In the “set value 1 low probability special figure winning lottery table”, among the big hit random numbers “0” to “65535”, “0” to “204” are registered as big hit values.
In the “set value 1 high-accuracy special figure winning lottery table”, the set value = “1” and “1” is set in the special figure high probability state flag area (occurrence of “special figure high probability state”) Selected). In the “set value 1 high-accuracy special figure winning lottery table”, “0” to “2039” among the big hit random numbers “0” to “65535” are registered as the big hit values.
In the “set value 2 low probability special figure winning lottery table”, the set value = “2” and “0” is set in the special figure high probability state flag area (occurrence of “special figure low probability state” Selected). In the “set value 2 low probability special figure winning lottery table”, “0” to “209” among the big hit random numbers “0” to “65535” are registered as the big hit values.
In the “set value 2 high-accuracy special figure winning lottery table”, the set value = “2” and “1” is set in the special figure high probability state flag area (occurrence of the “special figure high probability state”) Selected). In the “set value 2 high-accuracy special figure winning lottery table”, “0” to “2089” among the big hit random numbers “0” to “65535” are registered as the big hit values.
In the “set value 3 low probability special figure winning lottery table”, the set value = “3” and “0” is set in the special figure high probability state flag area (occurrence of “special figure low probability state” Selected). In the “set value 3 low probability special figure winning lottery table”, “0” to “214” of the big hit random numbers “0” to “65535” are registered as the big hit values.
In the “set value 3 high probability special figure winning lottery table”, the set value = “3” and “1” is set in the special figure high probability state flag area (occurrence of “special figure high probability state” Selected). In the “set value 3 high-accuracy special figure winning lottery table”, “0” to “2139” among the big hit random numbers “0” to “65535” are registered as the big hit values.

In the “set value 4 low probability special figure winning lottery table”, the set value = “4” and “0” is set in the special figure high probability state flag area (occurrence of “special figure low probability state” Selected). In the “set value 4 low probability special figure winning lottery table”, “0” to “219” among the big hit random numbers “0” to “65535” are registered as the big hit values.
In the “set value 4 high accuracy special figure winning lottery table”, the set value = “4” and “1” is set in the special figure high probability state flag area (occurrence of “special figure high probability state” Selected). In the “set value 4 high-accuracy special figure winning lottery table”, “0” to “2189” among the big hit random numbers “0” to “65535” are registered as the big hit values.
In the “set value 5 low probability special figure winning lottery table”, the set value = “5” and “0” is set in the special figure high probability state flag area (occurrence of “special figure low probability state” Selected). In the “set value 5 low probability special figure winning lottery table”, among the big hit random numbers “0” to “65535”, “0” to “224” are registered as big hit values.
In the “set value 5 high accuracy special figure winning lottery table”, the set value = “5” and “1” is set in the special figure high probability state flag area (occurrence of “special figure high probability state” Selected). In the “set value 5 high-precision special figure winning lottery table”, “0” to “2239” among the big hit random numbers “0” to “65535” are registered as the big hit values.
In the “set value 6 low probability special figure winning lottery table”, the set value = “6” and “0” is set in the special figure high probability state flag area (occurrence of “special figure low probability state” Selected). In the “set value 5 low probability special figure winning lottery table”, among the big hit random numbers “0” to “65535”, “0” to “229” are registered as big hit values.
In the “set value 6 high-accuracy special figure winning lottery table”, the set value = “6” and “1” is set in the special figure high probability state flag area (occurrence of “special figure high probability state”) Selected). In the “set value 6 high-accuracy special figure winning lottery table”, “0” to “2289” among the big hit random numbers “0” to “65535” are registered as the big hit values.

In the special special chart winning determination process, the value (setting value) set in the setting information storage area and the current gaming state ("high special figure probability state" or "special figure low probability state") are confirmed. The special figure winning lottery table corresponding to the confirmation result is read out.
Then, based on the jackpot random number included in the preliminary determination start information and the read special symbol winning lottery table, it is determined whether or not the result of the special symbol lottery is “big hit” (preliminary special symbol winning determination). .
Specifically, if the value of the jackpot random number included in the pre-determination start information matches the jackpot value registered in the read special symbol winning lottery table, the result of the special symbol lottery is set to “big hit” (Winning) is determined.
On the other hand, if the value of the jackpot random number included in the pre-judgment start information does not match the jackpot value registered in the read special figure winning lottery table (if it matches the outlier value), the special symbol The result of the lottery is determined to be “out” (decision).

In the preliminary determination process, a preliminary special figure stop symbol determination process is executed next. In the pre-special symbol stop symbol determination process, the special symbol stop symbol type is determined (pre-special symbol stop symbol determination).
In the pre-special symbol stop symbol determination process, if it is determined that “big hit” (winning) is determined by the pre-special symbol winning determination, the type of “big hit symbol” is determined (pre-special symbol stop symbol determination).
The ROM 220 stores a jackpot symbol lottery table in which the correspondence between the hit symbol random number and the type of “hit symbol” is registered. In addition, as the jackpot symbol lottery table, a first jackpot symbol lottery table corresponding to the first special symbol lottery and a second jackpot symbol lottery table corresponding to the second special symbol lottery are stored.
In the first jackpot symbol lottery table, “one jackpot symbol” and “two jackpot symbols” are registered as the type of “hit symbol”. On the other hand, in the second big hit symbol lottery table, “big hit three symbols” to “big hit six symbols” are registered as types of “big hit symbols”.
When the pre-determined start information is the special figure 1 start information, the first big hit symbol lottery table is read. Then, the type of the big hit symbol is determined based on the winning symbol random number included in the pre-determination start information and the read first big hit symbol lottery table.
On the other hand, when the preliminary determination start information is the special figure 2 start information, the second big hit symbol lottery table is read. Then, the type of the big hit symbol is determined based on the winning symbol random number included in the pre-determination start information and the read second big hit symbol lottery table.
On the other hand, in the special special symbol stop symbol determination process, if it is determined to be “out” (decision) by the preliminary special symbol winning determination, “exclusion symbol” is determined as the stop symbol type (pre-special symbol stop symbol determination) )

In the pre-determination process, a first prefetch designation command setting process is executed next.
In the first prefetch designation command setting process, the first prefetch designation command for designating the type of the stop symbol determined by the pre-special symbol stop symbol determination is stored in the subcommand output request buffer of the RAM 230.

In the pre-determination process, next, a pre-special drawing variation mode determination process is executed.
At this time, if it is determined as “big hit” (winning) by the pre-special drawing winning determination, a pre-special drawing variation mode determining process described later is executed. On the other hand, if it is determined as “out of” (decision) by the prior special figure winning determination, the pre-specialized figure variation state determination process at the time of loss described later is executed.

In the winning special figure variation mode determination process, first, the type (variation mode number) of the variation mode is determined (pre-variation mode determination at the time of winning).
The ROM 220 stores a winning-time variation mode determination table in which the correspondence between the reach mode random number and the variation mode type (variation mode number) is registered.
In addition, the winning mode variation mode determination table includes the type of jackpot symbol ("one jackpot symbol" to "six jackpot symbols"), the gaming state ("special symbol high probability state" or "special symbol low probability state"), hourly counter And the winning variation mode determination table corresponding to the combination of the value and the like.
In the present embodiment, the types of fluctuation modes (variation mode numbers) are defined as “no pseudo-continuous fluctuation”, “pseudo-continuous 2 fluctuation”, “pseudo-continuous 3 fluctuation”, and “pseudo-continuous 4 fluctuation”. Has been.
In addition, a plurality of variation modes (variation mode numbers) associated with different variation times are defined as the variation modes (variation mode numbers) belonging to the “pseudo-continuous variation”.
The jackpot expectation of each type is the category belonging to “pseudo-continuous 4 variation”, “pseudo-continuous 3 variation”, “pseudo-continuous 2 variation”, and “pseudo-continuous variation” in descending order of the jackpot expectation. It is specified that the degree of high hits → low expectation of big hits).
The “big hit expectation” refers to the possibility (degree) of occurrence of a big hit gaming state when the content (variation mode type, fluctuation pattern type, production mode, etc.) is selected.

In each winning variation mode determination table, “pseudo continuous 2 variation”, “pseudo continuous 3 variation”, and “pseudo continuous 4 variation” are registered as the variation mode type (variation mode number). ("Fluctuation without pseudo-ream" is not registered).
In the pre-variation mode determination at the time of winning, first, the type of jackpot symbol determined by the pre-special symbol stop symbol determination and the gaming state are confirmed, and a winning variation mode determination table corresponding to the confirmation result is read out.
Then, the type (variation mode number) of the variation mode is determined based on the reach mode random number included in the preliminary determination start information and the read variation mode determination table at the time of winning.

In the pre-special drawing variation mode determination process at the time of winning, next, the type (variation pattern number) of the variation pattern is determined (pre-variation pattern determination at the time of winning).
The ROM 220 stores a winning variation pattern determination table in which correspondence between a variation pattern random number and a variation pattern type (variation pattern number) is registered.
In addition, as the winning variation pattern determination table, the type of jackpot symbol ("one jackpot symbol" to "six jackpot symbols"), the game state ("special figure high probability state" or "special figure low probability state", hourly counter And the winning variation pattern determination table corresponding to the combination of the variation mode type and the type of variation mode.
In the present embodiment, “variation without reach”, “normal reach variation”, and “super reach variation” are defined as the types of variation patterns (variation pattern numbers).
A plurality of variation patterns (variation pattern numbers) associated with different variation times are defined as variation patterns (variation pattern numbers) belonging to “unreachable variation”.
In addition, a plurality of variation patterns (variation pattern numbers) associated with different variation times are defined as variation patterns (variation pattern numbers) belonging to “normal reach variation”.
In addition, as variation patterns (variation pattern numbers) belonging to “super reach variation”, a plurality of variation patterns (variation pattern numbers) associated with different variation times are defined. In the present embodiment, “super reach variation 1” to “super reach variation 5” are defined as variation patterns (variation pattern numbers) belonging to “super reach variation”.
The expectation level of each type is defined to be “super reach fluctuation”, “normal reach fluctuation”, and “non-reach fluctuation” (high expectation → low expectation) in descending order of expectation.
In addition, the expectation level of each variation pattern belonging to “super reach variation” is “super reach variation 5”, “super reach variation 4”, “super reach variation 3”, “super reach variation” in descending order of expectation. 2 ”,“ Super Reach Variation 1 ”(High Expectation → Low Expectation).

In each winning variation pattern determination table, “normal reach variation” and “super reach variation” are registered as variation pattern types (variation pattern numbers) (“reach-less variation” is not registered). ).
In the pre-variation pattern determination at the time of winning, first, the type of jackpot symbol determined by the prior special figure stop symbol determination, the gaming state, and the type of variation mode (variation mode number) determined by the pre-variation mode determination at the time of winning , And the winning variation pattern determination table corresponding to the confirmation result is read out.
Then, the variation pattern type (variation pattern number) is determined based on the variation pattern random number included in the preliminary determination start information and the read variation pattern determination table at the time of winning.

On the other hand, in the prior special figure variation mode determination process at the time of a loss, first, the type (“indefinite value” or “fixed value”) of the reach group random number included in the preliminary determination start information is determined (preliminary random type determination).
In the present embodiment, “undefined value” and “fixed value” are defined as the types of reach group random numbers.
“Undefined value” means that when starting information (Special Figure 1 starting information or Special Figure 2 starting information) is acquired (stored), the type of fluctuation mode (variation mode number) and the type of fluctuation pattern (variation pattern number) are determined. Not at the start of special symbol variation display based on the start information (when executing step S11-7), based on the number of suspensions at that time (the number of suspensions of special figure 1 or the number of special figure 2) The type of mode (variation mode number) and the type of variation pattern (variation pattern number) are determined.
“Fixed value” means acquisition of start information (special figure 1 start information or special figure 2 start information) regardless of the number of suspensions at the start of special symbol fluctuation display (when step S11-7 is executed). At the time of storage (when step S9-8 is executed), the type of variation mode (variation mode number) and the type of variation pattern (variation pattern number) are determined.
In the present embodiment, the value of the reach group random number is updated within the range of “0” to “10006”. Of “0” to “10006”, “0” to “8499” are “undefined values”, and “8500” to “10006” are “fixed values”.
Therefore, in the prior random number type determination, when the value of the reach group random number included in the preliminary determination start information is less than “8500”, it is determined as “undefined value”, and the reach group random number included in the preliminary determination start information is determined. When the value is “8500” or more, it is determined as “fixed value”.

In the special figure variation mode determination process at the time of defeat, when it is determined as “fixed value” by the pre-random number type determination, the prior reach group determination, the pre-variation mode determination at the time of defeat, and the pre-variation pattern determination at the time of defeat And execute.
In addition, in the special figure variation mode determination process at the time of loss, if it is determined as “undefined value” by the prior random type determination, the advance reach group determination, the advance variation mode determination at the time of loss, and the fluctuation pattern determination at the time of loss , Is not executed.

In the advance reach group determination, the type of reach group (reach group number) is determined.
The ROM 220 stores a reach group determination table in which correspondences between reach mode random numbers and reach group types (reach group numbers) are registered.
In addition, an indefinite value reach group determination table and a fixed value reach group determination table are stored as the reach group determination table.
In this embodiment, “reach group 1”, “reach group 2”, and “reach group 3” are defined as the types of reach groups.
In the indefinite value reach group determination table, only “reach group 1” is registered as the reach group type (“reach group 2” and “reach group 3” are not registered).
On the other hand, in the fixed value reach group determination table, only “reach group 2” and “reach group 3” are registered as the reach group type (“reach group 1” is not registered).
In the advance reach group determination, the fixed value reach group determination table is read. Then, the type of reach group is determined based on the reach group random number included in the pre-determination start information and the read fixed value reach group determination table.

In the pre-change mode determination at the time of loss, the type of change mode (change mode number) is determined.
The ROM 220 stores a loss mode variable mode determination table in which the correspondence between the reach mode random number and the variation mode type (variation mode number) is registered.
Furthermore, as the loss mode fluctuation mode determination table, “loss mode change mode determination table 1” corresponding to “reach group 1”, “failure change mode determination table 2” corresponding to “reach group 2”, and “reach” "Disappointment variation mode determination table 3" corresponding to "Group 3" is stored.
In addition, as the “Disappointing Fluctuation Mode Determination Table 1”, it corresponds to each combination of the number of holds (Special figure 1 hold number or Special figure 2 hold number) and the execution status (running or stopped) of the time-saving control. The “decision change mode determination table 1” is stored.

In the “decision fluctuation mode determination table 1”, only “variation without pseudo-continuous variation” is registered as the type of variation mode (variation mode number) (“quasi-continuous variation 2”, “pseudo-continuous variation 3”). "And" Pseudo-ream 4 variation "are not registered).
Further, the contents of the “decision variable mode determination table 1” corresponding to each number of holds are set so that the type of change mode (change mode number) associated with a short change time is selected as the number of holds increases. Yes.
In the “decided fluctuation mode determination table 2”, the types of fluctuation modes (fluctuation mode numbers) are registered as “pseudo continuous 2 fluctuation”, “pseudo continuous 3 fluctuation”, and “pseudo continuous 4 fluctuation”. ("Fluctuation without quasi-continuous" is not registered).
In the “decision fluctuation mode determination table 3”, the types of fluctuation modes (fluctuation mode numbers) are registered as “pseudo continuous 2 fluctuation”, “pseudo continuous 3 fluctuation”, and “pseudo continuous 4 fluctuation”. ("Fluctuation without quasi-ream" is not registered).

In the pre-variation mode determination at the time of loss, first, the type of reach group determined by the pre-reach group determination is confirmed, and a loss mode variable mode determination table corresponding to the confirmation result is read.
Then, the type (variation mode number) of the variation mode is determined based on the reach mode random number included in the pre-determination start information and the read variation mode determination table at the time of loss.

In the prior variation pattern determination at the time of loss, the type of variation pattern (variation pattern number) is determined.
The ROM 220 stores a loss pattern change pattern determination table in which a correspondence between a change pattern random number and a change pattern type (change pattern number) is registered.
Further, as the change pattern determination table at the time of loss, “change pattern determination table 1 at the time of loss” corresponding to “reach group 1”, “change pattern determination table 2 at time of loss” corresponding to “reach group 2”, and “reach” “Decision change variation pattern determination table 3” corresponding to “Group 3” is stored.
In addition, as the “decision change pattern determination table 1”, it corresponds to each combination of the number of holdings (the number of holdings of special figure 1 or the number of holdings of special figure 2) and the execution status (running or stopped) of the time reduction control The “decision change pattern determination table 1” is stored.

In the “decision change variation pattern determination table 1”, only “variation without reach” is registered as the variation pattern type (variation pattern number) (“normal reach variation” and “super reach variation” are registered). Not)
In addition, the contents of the “decision change pattern determination table 1” corresponding to each number of holds are set so that the type of change pattern (change pattern number) associated with a shorter change time is selected as the number of holds increases. Yes.
Only “normal reach fluctuation” and “super reach fluctuation” and “super reach fluctuation” are not registered as the type of fluctuation pattern (fluctuation pattern number) in the “decision fluctuation pattern determination table 2”. ).
Only “super reach variation” and “normal reach variation” are not registered as the variation pattern type (variation pattern number) in the “decision variation pattern determination table 3”. ).

In the pre-change pattern determination at the time of loss, first, the type of reach group determined by the pre-reach group determination is confirmed, and a change pattern determination table at the time of loss corresponding to the confirmation result is read.
Then, the variation pattern type (variation pattern number) is determined based on the variation pattern random number included in the preliminary determination start information and the read variation pattern determination table at the time of winning.

Next, in the pre-determination process, second and third prefetch designation command setting processes are executed.
In the second and third look-ahead designation command setting processes, if it is determined that “big hit” (winning) is determined by the pre-special drawing winning determination, the type of the changing mode (variation mode number) determined by the pre-variation mode determination at the time of winning ) And a third prefetch designation command for designating the type (variation pattern number) of the variation pattern determined by the prior variation pattern determination at the time of winning are stored in the subcommand output request buffer of the RAM 230. To do.
On the other hand, when it is determined as “out of” (decision) by the prior special figure winning determination and “fixed value” is determined by the prior random number type determination, the variation mode determined by the prior variation mode determination at the time of defeat is determined. A sub-command of the RAM 230 includes a second look-ahead designation command for designating the type (variation mode number), a second look-ahead designation command for designating the type of the variation pattern (variation pattern number) determined by the pre-variation pattern determination at the time of loss. Store in the output request buffer.
On the other hand, if it is determined as “out of” (decision) by the prior special figure winning determination, and “undefined value” is determined by the prior random number type determination, , The third prefetching designation command for designating “undefined value” and the subcommand output request buffer of the RAM 230 are stored.

As described above, when the value of the reach group random number included in the pre-determination start information is “fixed value”, the variation mode type (variation mode number) and the variation pattern type (variation pattern number) are determined, Second and third look-ahead designation commands for designating the determined variation mode type and variation pattern type are transmitted to the effect control circuit 300.
On the other hand, if the value of the reach group random number included in the pre-determination start information is “undefined value”, the variation mode type (variation mode number) and the variation pattern type (variation pattern number) are not determined. , Second and third prefetch designation commands for designating “indefinite value” are transmitted to the effect control circuit 300.

Next, the special game management process in step S4-11 will be described.
FIG. 15 is a flowchart showing the special game management process.
In the present embodiment, as a stage / stage (hereinafter referred to as “special game phase”) of a game (hereinafter referred to as “special game”) executed based on a special symbol lottery, `` Special figure changing state '', `` Special figure stop symbol display state '', `` Big prize opening before opening '', `` Big prize opening opening control state '', `` Large winning opening closed effective state '' and `` Large winning opening closed '' Seven "wait states" are defined.
A value (special game phase flag) corresponding to one of the seven special game phases is set in the special game phase flag area of the RAM 230.
The ROM 220 stores special game control modules corresponding to each special game phase as special game control modules (programs) for controlling (executing) special games.
In the special game management process, a special game control module corresponding to the value set in the special game phase flag area of the RAM 230 is selected, and a process based on the selected special game control module is executed.

Specifically, when the special game management process is executed in step S4-11, the process first proceeds to step S10-1, as shown in FIG.
In step S10-1, a special game phase acquisition process is executed, and the process proceeds to step S10-2. In the special game phase acquisition process, the value (special game phase) set in the special game phase flag area of the RAM 230 is acquired (loaded).
In step S10-2, a special game control module acquisition process is executed, and the process proceeds to step S10-3. In the special game control module acquisition process, the special game control module corresponding to the value (special game phase) acquired in step S10-1 is read.
In step S10-3, a special game control module execution process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-12). In the special game control module execution process, a process based on the special game control module read in step S10-2 is started.
Specifically, when the value acquired in step S10-1 is a value corresponding to the “special figure change waiting state”, a special figure change waiting process described later is started, and the “special figure change waiting state” is started. In the case of a value corresponding to, a special figure changing process to be described later is started, and in the case of a value corresponding to "special figure stop symbol display state", a special figure stopping process to be described later is started, When the value corresponds to “a state before opening the big prize opening”, a pre-opening process for a special prize opening described later is started. When the value of the winning prize opening control process is started and the value corresponds to the “Large winning opening closed effective state”, the winning opening closing effective process described later is started, and the “Large winning opening open wait state” is entered. When the value is a corresponding value, a special winning opening opening end wait process described later is performed. It is started.

Next, the special figure variation waiting process executed in step S10-3 will be described.
FIG. 16 is a flowchart showing the special figure variation waiting process.
When the special figure variation waiting process is executed in step S10-3, as shown in FIG. 16, the process first proceeds to step S11-1.
In step S11-1, it is determined whether or not the value of the special figure 2 hold number counter is “1” or more, and when it is determined that the value of the special figure 2 hold number counter is not “1” or more (No). Shifts to step S11-2, and when it is determined that the value of the special figure 2 hold number counter is “1” or more (Yes), shifts to step S11-3.
In step S11-2, it is determined whether or not the value of the special figure 1 hold number counter is “1” or more, and it is determined that the value of the special figure 1 hold number counter is “1” or more (Yes). In step S11-3, if it is determined that the value of the special figure 1 holding number counter is not equal to or greater than “1” (Yes), the series of processing is terminated and the next processing (step S4-12) is performed. ).

In step S11-3, a special figure hold number update process is executed, and the process proceeds to step S11-4. In the special figure hold number update process, the special figure hold number (the special figure 1 hold number or the special figure 2 hold number) is updated.
Specifically, in the special figure hold number update process, first, the start information (special figure 1 start) stored in the start information storage area (the special figure 1 start information storage area and the special figure 2 start information storage area) of the RAM 230. Information and special figure 2 start information) is selected as determination start information.
In this embodiment, the start determination for the special figure 2 start information stored in the special figure 2 start information storage area is given priority over the special figure 1 start information stored in the special figure 1 start information storage area. (Special figure winning judgment, special figure stop symbol judgment, special figure fluctuation pattern judgment, etc.) are executed.
Accordingly, when one or more special figure 2 start information is stored in the special figure 2 start information storage area, the first of the special figure 2 start information stored in the special figure 2 start information storage area. Obtained (stored) is selected as determination start information. That is, the special figure 2 start information stored in the first storage unit of the special figure 2 start information storage area is selected as the determination start information.
On the other hand, when the special figure 2 start information is not stored in the special figure 2 start information storage area, the special figure 1 start information stored in the special figure 1 start information storage area is first acquired (stored). ) Is selected as determination start information. That is, the special figure 1 start information stored in the first storage unit of the special figure 1 start information storage area is selected as the determination start information.
Next, the value of the special figure hold number counter (the special figure 1 hold number counter or the special figure 2 hold number counter) is updated.
Specifically, when the special figure 1 start information is set as the determination start information, a value obtained by subtracting “1” from the value set in the special figure 1 hold number counter is newly added to the special figure 1 hold number. Set to counter.
On the other hand, when the special figure 2 start information is determined start information, a value obtained by subtracting “1” from the value set in the special figure 2 hold number counter is newly set in the special figure 2 hold number counter. To do.
Next, the determination start information storage area is changed (shifted) from the start information storage area (see FIG. 1 start information storage area or special figure 2 start information storage area) to the changing start information storage area.
Specifically, when the special figure 2 start information is determined start information, the special figure 2 start information (determination start information) stored in the first storage unit of the special figure 2 start information storage area is Store (shift) in the starting information storage area during fluctuation. Further, when the special figure 2 start information is stored in the second storage part to the fourth storage part of the special figure 2 start information storage area, the special figure 2 start information stored in each storage part is The data is stored (shifted) in the storage unit that has a higher priority than the storage unit.
On the other hand, when the special figure 1 start information is determined start information, the special figure 1 start information (determination start information) stored in the first storage unit of the special figure 1 start information storage area is used as the start during fluctuation. Store (shift) in the information storage area. In addition, when the special figure 1 start information is stored in the second storage part to the fourth storage part of the special figure 1 start information storage area, the special figure 1 start information stored in each storage part is The data is stored (shifted) in the storage unit that has a higher priority than the storage unit.

In step S11-4, special figure winning determination processing is executed, and the process proceeds to step S11-5. In the special symbol winning determination process, the result of the special symbol lottery is determined (special symbol winning determination).
In the special figure winning determination process, the value set in the setting information storage area (setting value) and the current gaming state ("special figure high probability state" or "special figure low probability state") are confirmed. Then, the special drawing winning lottery table corresponding to the confirmation result is read.
Then, based on the jackpot random number included in the determination start information and the read special symbol winning lottery table, it is determined whether or not the result of the special symbol lottery is “big hit” (special symbol winning determination).
Specifically, when the value of the jackpot random number included in the determination start information matches the jackpot value registered in the read special symbol winning lottery table, the result of the special symbol lottery is set to “big hit” ( It is determined that (winning).
On the other hand, if the value of the jackpot random number included in the judgment start information does not match the jackpot value registered in the read special figure winning lottery table (if it matches the outlier value), the special symbol lottery The result is determined as “out of” (decision).

In step S11-5, a special figure stop symbol determination process is executed, and the process proceeds to step S11-6.
In the special figure stop symbol determination process, first, the type of stop symbol of the special symbol is determined (special symbol stop symbol determination).
In other words, if it is determined that “big hit” (winning) is determined by the special symbol winning determination, the type of “big winning symbol” is determined.
Specifically, when the determination start information is the special figure 1 start information, the first big hit symbol lottery table is read. Then, based on the winning symbol random number included in the determination start information and the read first big hit symbol lottery table, the type of the big hit symbol is determined.
On the other hand, when the judgment start information is the special figure 2 start information, the second big hit symbol lottery table is read out. Then, the type of the big hit symbol is determined based on the winning symbol random number included in the determination start information and the read second big hit symbol lottery table.
On the other hand, when it is determined as “disappearance” (decision) by the special symbol winning determination, “disappearing symbol” is determined as the stop symbol type.

In the special figure stop symbol determination process, next, a special symbol stop symbol (seg data / stop symbol number) is determined.
The ROM 220 stores a seg data table in which correspondences between hit symbol random numbers and stop symbols (seg data / stop symbol numbers) are registered.
In addition, as a seg data table, a special symbol lottery (first special symbol lottery or second special symbol lottery) corresponding to the case of winning a special symbol lottery (first special symbol lottery or second special symbol lottery) A lost selection seg data table corresponding to the case of being lost in symbol lottery is stored.
Furthermore, a winning seg data table corresponding to the first special symbol lottery and a winning seg data table corresponding to the second special symbol lottery are stored as the winning seg data table.
In order to determine the stop symbol of the special symbol, first, the result of the special symbol failure determination is confirmed.
Then, when it is determined as “big hit” (winning) by the special figure winning determination, the type of determination starting information (special figure 1 starting information or special figure 2 starting information) is further confirmed, and this confirmation result is obtained. Read the corresponding winning seg data table. Then, a stop symbol (seg data / stop symbol number) is determined based on the winning symbol random number included in the determination start information and the read winning seg data table.
On the other hand, if it is determined as “out of” (decision) by the special figure winning determination, the seg data table at the time of selection is read. Then, the stop symbol (seg data / stop symbol number) is determined on the basis of the winning symbol random number included in the determination start information and the read-off seg data table.
In the special symbol stop symbol determination process, the determined stop symbol (seg data / stop symbol number) is then stored in the stop symbol storage area of the RAM 230.

  In step S11-6, a symbol type designation command setting process is executed, and the process proceeds to step S11-7. In the symbol type designation command setting process, a symbol type designation command for designating the type of the stop symbol determined in step S11-5 is stored in the subcommand output request buffer.

In step S11-7, special figure fluctuation pattern determination processing is executed, and the process proceeds to step S11-8. In the special figure variation pattern determination process, the variation mode (variation mode type and variation pattern type) of the special symbol is determined.
Specifically, in the special figure fluctuation pattern determination process, a winning special figure fluctuation mode determination process is executed. At this time, if it is determined as “big hit” (winning) by the special figure winning determination, the winning special figure fluctuation mode determining process described later is executed. On the other hand, when it is determined as “disappearance” (decision) by the special figure winning determination, a special figure fluctuation state determination process at the time of winning is executed.

In the winning special figure variation mode determination process, first, the type of variation mode (variation mode number) is determined (variation mode determination at the time of winning).
In the winning variation mode determination, the type of jackpot symbol determined by the special symbol stop symbol determination and the gaming state ("special figure high probability state" or "special figure low probability state", value of the short time counter, etc.), After confirmation, the winning variation mode determination table corresponding to the confirmation result is read.
Then, based on the reach mode random number included in the determination start information and the read winning variation mode determination table, the variation mode type (variation mode number) is determined.
In the winning special figure variation mode determination process, next, the variation pattern type (variation pattern number) is determined (variation pattern determination at the time of winning).
In the winning variation pattern determination, the type of jackpot symbol determined by the special figure stop symbol determination, the gaming state ("special figure high probability state" or "special figure low probability state", the value of the short time counter, etc.), and the winning The type of variation mode (variation mode number) determined by the time variation mode determination is confirmed, and a winning variation pattern determination table corresponding to the confirmation result is read.
Then, based on the variation pattern random number included in the determination start information and the read variation pattern determination table at the time of winning, the type of variation pattern (variation pattern number) is determined.

On the other hand, in the special figure change mode determination process at the time of loss, first, the type (“indefinite value” or “fixed value”) of the reach group random number included in the determination start information is determined (random number type determination).
In the random number type determination, when the reach group random number value included in the determination start information is less than “8500”, it is determined as “undefined value”, and the reach group random number value included in the determination start information is “8500”. When it is above, it is determined as “fixed value”.
In the special figure change mode determination process at the time of loss, next, the type of reach group (reach group number) is determined (reach group determination).
In the reach group determination, when it is determined as “fixed value” by the random number type determination, the fixed value reach group determination table is read. Then, the type of the reach group is determined based on the reach group random number included in the determination start information and the read fixed value reach group determination table.
On the other hand, when it is determined as “indefinite value” by the random number type determination, the indefinite value reach group determination table is read. Then, the type of reach group is determined based on the reach group random number included in the determination start information and the read indefinite value reach group determination table.
In the special figure change mode determination process at the time of loss, next, the type of change mode (change mode number) is determined (change mode determination at the time of loss).
In the loss mode change mode determination, if it is determined as a “fixed value” by the random number type determination, the reach group type determined by the reach group determination is confirmed, and the loss mode change mode determination corresponding to this confirmation result Read the table. Then, the type (variation mode number) of the variation mode is determined based on the reach mode random number included in the determination start information and the read variation mode determination table at the time of loss.
On the other hand, when it is determined as “undefined value” by the random number type determination, the type of the reach group determined by the reach group determination, the number of reservations (the number of special figure 1 or the number of special figure 2), and time reduction control The execution state (during execution or stoppage) is confirmed, and the selection mode change mode determination table corresponding to the confirmation result is read. Then, the type (variation mode number) of the variation mode is determined based on the reach mode random number included in the determination start information and the read variation mode determination table at the time of loss.
In the special figure change mode determination process at the time of loss, next, the type (change pattern number) of the change pattern is determined (change pattern determination at the time of loss).
In the change pattern determination at the time of loss selection, if it is determined as “fixed value” by the random number type determination, the type of reach group determined by the reach group determination is confirmed, and the change pattern determination at the time of loss corresponding to this confirmation result Read the table. Then, based on the fluctuation pattern random number included in the determination start information and the read-out fluctuation pattern determination table, the type of fluctuation pattern (fluctuation pattern number) is determined.
On the other hand, when it is determined as “undefined value” by the random number type determination, the type of the reach group determined by the reach group determination, the number of reservations (the number of special figure 1 or the number of special figure 2), and time reduction control The execution state (during execution or stoppage) is confirmed, and the selection pattern variation pattern determination table corresponding to the confirmation result is read. Then, based on the fluctuation pattern random number included in the determination start information and the read-out fluctuation pattern determination table, the type of fluctuation pattern (fluctuation pattern number) is determined.

In step S11-8, a variation pattern command setting process is executed, and the process proceeds to step S11-9. In the variation pattern command setting process, a variation mode designation command for designating the variation mode type (variation mode number) determined in step S11-7 is stored in the subcommand output request buffer. Further, the variation pattern designation command for designating the variation pattern type (variation pattern number) determined in step S11-7 is stored in the subcommand output request buffer.
In step S11-9, a special figure variation time setting process is executed, and the process proceeds to step S11-10. In the special figure variation time setting process, the variation time (hereinafter referred to as “variation time 1”) corresponding to the variation mode type (variation mode number) determined in step S11-7 is acquired. Also, a variation time (hereinafter referred to as “variation time 2”) corresponding to the type (variation pattern number) of the variation pattern determined in step S11-7 is acquired. Then, the total time of the obtained fluctuation time 1 and fluctuation time 2 is calculated. Then, the calculated total time is set in the special game timer.

In step S11-10, special figure fluctuation display data setting processing is executed, and the process proceeds to step S11-11. In the special figure fluctuation display data setting process, data for controlling the fluctuation display of the special figure display device is set.
Specifically, in the special figure variation display data setting process, first, a predetermined display time is set in the special figure display timer.
Next, when the judgment start information is special figure 1 start information, predetermined segment data is set as the segment data corresponding to the special figure 1 display device. Thereby, among the predetermined number of segments constituting the special figure 1 display device, the segment corresponding to the set segment data is controlled to be lit.
On the other hand, when the determination start information is the special figure 2 start information, predetermined segment data is set as the segment data corresponding to the special figure 2 display device. Thereby, among the predetermined number of segments constituting the special figure 2 display device, the segment corresponding to the set segment data is controlled to be lit.

In step S11-11, a hold number designation command setting process is executed, and the process proceeds to step S11-12. In the number-of-holds designation command setting process, a number-of-holds designation command that designates that the number of special figure holds (number of special figure 1 hold or number of special figure 2 hold) has decreased by “1” is stored in the subcommand output request buffer of the RAM 230. To do. At this time, if the judgment start information is the special figure 1 start information, the pending number designation command for designating that the special figure 1 pending number has decreased by "1" is stored in the sub-command output request buffer of the RAM 230, If the judgment start information is the special figure 2 start information, a hold number designation command for designating that the special figure 2 hold number has decreased by "1" is stored in the subcommand output request buffer of the RAM 230.
In step S11-12, a special game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-12). In the special game phase update process, a value corresponding to the “special figure changing state” is set in the special game phase flag area of the RAM 230.

Next, the special figure changing process executed in step S10-3 will be described.
FIG. 17 is a flowchart showing the special figure changing process.
When the special figure changing process is executed in step S10-3, as shown in FIG. 17, first, the process proceeds to step S12-1.
In step S12-1, it is determined whether or not the value of the special game timer is “0”. If it is determined that the value of the special game timer is not “0” (No), the process proceeds to step S12-2. If it is determined that the value of the special game timer is “0” (Yes), the process proceeds to step S12-4.
In step S12-2, it is determined whether or not the value of the special figure display timer is "0". If it is determined that the value of the special figure display timer is "0" (Yes), step S12- 3, when it is determined that the value of the special figure display timer is not “0” (No), the series of processes is terminated and the process proceeds to the next process (step S4-12).
In step S12-3, a special figure fluctuation display data update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-12). In the special figure fluctuation display data update processing, data for controlling the fluctuation display of the special figure display device is updated.
Specifically, in the special figure variation display data update process, when the variable display of the first special symbol is being executed, the segment data corresponding to the special figure 1 display device is updated. On the other hand, when the variable display of the second special symbol is being executed, the segment data corresponding to the special symbol 2 display device is updated.

In step S12-4, a special figure stop display data setting process is executed, and the process proceeds to step S12-5. In the special figure stop display data setting process, data for controlling the stop display of the special figure display device is set.
Specifically, in the special symbol stop display data setting process, the stop symbol (seg data / stop symbol number) stored in the stop symbol storage area of the RAM 230 is acquired.
Next, when the variable display of the first special symbol is terminated, the acquired segment data (or the segment data corresponding to the acquired stop symbol number) is set as the segment data corresponding to the special symbol 1 display device. Thereby, among the predetermined number of segments constituting the special figure 1 display device, the segment corresponding to the set segment data is controlled to be lit (stop display).
On the other hand, when ending the variable display of the second special symbol, the acquired segment data (or the segment data corresponding to the acquired stop symbol number) is set as the segment data corresponding to the special symbol 2 display device. As a result, among the predetermined number of segments constituting the special figure 2 display device, the segment corresponding to the set segment data is subjected to lighting control (stop display).

In step S12-5, a special figure stop time setting process is executed, and the process proceeds to step S12-6. In the special figure stop time setting process, a predetermined stop time is set in the special game timer.
In step S12-6, a stop designation command setting process is executed, and the process proceeds to step S12-7. In the stop specification command setting process, the stop specification command is stored in the subcommand output request buffer. Further, a predetermined number (1 [times] in the present embodiment) is added to the value of the external information determination number counter.
In step S12-7, a special game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-12). In the special game phase update process, a value corresponding to the “special figure stop symbol display state” is set in the special game phase flag area of the RAM 230.

Next, the special figure stopping process executed in step S10-3 will be described.
FIG. 18 is a flowchart showing the special figure stopping process.
When the special figure stopping process is executed in step S10-3, as shown in FIG. 18, first, the process proceeds to step S13-1.
In step S13-1, it is determined whether or not the value of the special game timer is “0”. If it is determined that the value of the special game timer is “0” (Yes), the process proceeds to step S13-2. If it is determined that the value of the special game timer is not “0” (No), the series of processes is terminated and the process proceeds to the next process (step S4-12).
In step S13-2, it is determined whether or not the stop symbol type is “hit symbol”. If it is determined that the stop symbol type is not “hit symbol” (No), the process proceeds to step S13-3. If it is determined that the stop symbol type is “big hit symbol” (Yes), the process proceeds to step S13-6.
In step S13-3, it is determined whether or not the time reduction control is being executed. If it is determined that the time reduction control is being executed (Yes), the process proceeds to step S13-4 and the time reduction control is being executed. If not (No), the process proceeds to step S13-5.
Here, if “1” is set in the time reduction control flag area of the RAM 230, it is determined that the time reduction control is being executed, and if “0” is set, execution of the time reduction control is executed. Judge that it is not inside.

In step S13-4, a time reduction control management process is executed, and the process proceeds to step S13-5. In the time reduction control management process, it is determined whether or not the time reduction control is terminated.
Specifically, in the time reduction control management process, first, a value obtained by subtracting “1” from the value of the time reduction counter is newly set as the value of the time reduction counter.
Next, it is determined whether or not the value of the time reduction counter is “0”. If it is determined that the value of the time reduction counter is “0” (Yes), “0” is set in the time reduction control flag area of the RAM 230 (time reduction control is stopped). On the other hand, when it is determined that the value of the time reduction counter is not “0”, the state where “1” is set in the time reduction control flag area of the RAM 230 is maintained (the state where the time reduction control is being executed is maintained). .
In step S13-5, a special game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-12). In the special game phase update process, a value corresponding to the “special figure change waiting state” is set in the special game phase flag area of the RAM 230.
In step S13-6, a game state update process is executed, and the process proceeds to step S13-7. In the game state update process, the game state is updated.
Specifically, in the game state update process, “0” is set in the special figure high probability state flag area of the RAM 230. Also, “0” is set in the time reduction control flag area of the RAM 230.

In step S13-7, a special power control data setting process is executed, and the process proceeds to step S13-8. In the special electric combination control data setting process, control data for opening and closing the special electric combination 53a is set.
The ROM 220 stores special power control tables corresponding to each type of “big hit symbol”. Each special power control table includes a winning opening closing effective time, a closing opening closing time, the number of round games, the number of opening / closing switching corresponding to each round game, and control data (solenoid) corresponding to each opening / closing switching. Control data, control time data) and the like.
In the special power control data setting process, a special power control table corresponding to the type of “big hit symbol” determined in step S11-5 is read, and the read special power control table is used as the special power control table in the RAM 230. Set to area.
Next, “0” is set in the special electric utility continuous operation number counter.

In step S13-8, an opening time setting process is executed, and the process proceeds to step S13-9. In the opening time setting process, a predetermined opening time is set in the special game timer with reference to the special power control table set in the special power control table area of the RAM 230.
In step S13-9, an opening designation command setting process is executed, and the process proceeds to step S13-10. In the opening designation command setting process, the opening designation command for designating the type of “big hit symbol” determined in step S11-5 is stored in the subcommand output request buffer. Also, a predetermined number (1 [times] in the present embodiment) is added to the value of the external information big hit counter.
In step S13-10, a special game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-12). In the special game phase update process, a value corresponding to the “pre-opening state for big prize opening” is set in the special game phase flag area of the RAM 230.

Next, the big winning opening opening pre-processing executed in step S10-3 will be described.
FIG. 19 is a flowchart showing the pre-opening process for the special winning opening.
When the big prize opening pre-processing is executed in step S10-3, as shown in FIG. 19, first, the process proceeds to step S14-1.
In step S14-1, it is determined whether or not the value of the special game timer is “0”. If it is determined that the value of the special game timer is “0” (Yes), the process proceeds to step S14-2. If it is determined that the value of the special game timer is not “0” (No), the series of processes is terminated and the process proceeds to the next process (step S4-12).
In step S14-2, a special electric combination continuous operation number counter update process is executed, and the process proceeds to step S14-3. In the special electric power continuous operation frequency counter update process, a value obtained by adding “1” to the value set in the special electric power continuous operation frequency counter is newly set in the special electric power continuous operation frequency counter.
In step S14-3, a round start designation command setting process is executed, and the process proceeds to step S14-4. In the round start designation command setting process, the round start designation command is stored in the subcommand output request buffer.

In step S14-4, a special power combination opening / closing switching count setting process is executed, and the process proceeds to step S14-5. In the special power combination open / close switching number setting process, the special power combination control table set in the special power combination control table area of the RAM 230 is referred to read out the number of open / close switching corresponding to the value of the special power combination continuous operation number counter. . Then, the read opening / closing switching frequency is set in the special electric utility switching frequency counter.
Next, “0” is set as the value of the special electric winning prize counter.
In step S14-5, a special power combination opening / closing switching process is executed, and the process proceeds to step S14-6. The special power combination opening / closing switching process will be described later.
In step S14-6, a special game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-12). In the special game phase update process, a value corresponding to the “big winning opening release control state” is set in the special game phase flag area of the RAM 230.

Next, the special power combination opening / closing switching process of steps S14-5 and S16-3 will be described.
FIG. 20 is a flowchart showing the special power combination opening / closing switching process.
When the special power combination opening / closing switching process is executed in steps S14-5 and S16-3, the process first proceeds to step S15-1, as shown in FIG.
In step S15-1, it is determined whether or not the value of the special power utility switching frequency counter is “0”, and when it is determined that the value of the special power service switching frequency counter is not “0” (No). Moves to step S15-2, and when it is determined that the value of the special electric power switch on / off switching counter is “0” (Yes), the series of processing ends and the next processing (step S14-6) Alternatively, the process proceeds to S16-4).

In step S15-2, a special power combination control data setting process is executed, and the process proceeds to step S15-3. In the special electric combination control data setting process, control data for controlling the special electric combination 53a to the open state or the closed state is set.
Specifically, in the special power control data setting process, a special power control table set in the special power control table area of the RAM 230 is referred to, and the solenoid corresponding to the value of the special power on / off switching counter Read control data. Then, the read solenoid control data (control data designating energization or deenergization) is set in a predetermined area of the RAM 230. As a result, the control of the special winning opening solenoid 65 based on the set solenoid data is started, and the special electric accessory 53a is controlled to be in an open state or a closed state.

In step S15-3, a special power control time setting process is executed, and the process proceeds to step S15-4. In the special power control time setting process, a control time for continuing control based on the solenoid control data set in step S15-2 is set.
Specifically, in the special power combination control time setting process, the special power role control table set in the special power role control table area of the RAM 230 is referred to, and the control corresponding to the value of the special power role opening / closing switching frequency counter is referred to. Read time. Then, the read control time is set in the special game timer.
In step S15-4, a special power combination opening / closing switching number counter update process is executed, a series of processes is terminated, and the process proceeds to the next process (step S14-6 or S16-4). In the special electric utility switching frequency counter updating process, a value obtained by subtracting “1” from the value set in the special electric power switching frequency counter is newly set in the special electric power switching frequency counter.

Next, the special winning opening opening control process executed in step S10-3 will be described.
FIG. 21 is a flowchart showing the special winning opening opening control process.
When the big prize opening opening control process is executed in step S10-3, as shown in FIG. 21, first, the process proceeds to step S16-1.
In step S16-1, it is determined whether or not the value of the special game timer is “0”. If it is determined that the value of the special game timer is “0” (Yes), the process proceeds to step S16-2. If it is determined that the value of the special game timer is not “0” (No), the process proceeds to step S16-4.
In step S16-2, it is determined whether or not the value of the special power combination switching frequency counter is “0”, and when it is determined that the value of the special power switching frequency counter is not “0” (No). The process proceeds to step S16-3, and if it is determined that the value of the special electric power opening / closing switching number counter is “0” (Yes), the process proceeds to step S16-5.
In step S16-3, a special power combination opening / closing switching process (see FIG. 20) is executed, and the process proceeds to step S16-4.
In step S16-4, it is determined whether or not the value of the special power prize winning number counter has reached a predetermined upper limit value (10 [ball] in the present embodiment). If it is determined that the upper limit value has been reached (Yes), the process proceeds to step S16-5, and if it is determined that the value of the special electric winning prize counter has not reached the predetermined upper limit value (No). Terminates the series of processes and proceeds to the next process (step S4-12).

In step S16-5, a special winning opening opening control end process is executed, and the process proceeds to step S16-6. In the special winning opening opening control end process, solenoid control data for designating the energization stop is set in a predetermined area of the RAM 230. As a result, the special electric accessory 53a is controlled to be closed.
In step S16-6, a special winning opening closing effective time setting process is executed, and the process proceeds to step S16-7. In the special winning opening closing time setting process, the special winning combination closing effective time (interval time) is obtained by referring to the special electric control table set in the special electric control table area of the RAM 230, and the special game timer. Set to.
In step S16-7, a round end designation command setting process is executed, and the process proceeds to step S16-8. In the round end designation command setting process, the round end designation command is stored in the subcommand output request buffer.
In step S16-8, a special game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-12). In the special game phase update process, a value corresponding to the “big winning opening closed effective state” is set in the special game phase flag area of the RAM 230.

Next, the special winning opening closing effective process executed in step S10-3 will be described.
FIG. 22 is a flowchart showing the special winning opening closing effective process.
When the big winning opening closing effective process is executed in step S10-3, as shown in FIG. 22, first, the process proceeds to step S17-1.
In step S17-1, it is determined whether or not the value of the special game timer is “0”. If it is determined that the value of the special game timer is “0” (Yes), the process proceeds to step S17-2. If it is determined that the value of the special game timer is not “0” (No), the series of processes is terminated and the process proceeds to the next process (step S4-12).
In step S17-2, it is determined whether or not the value of the special power combination continuous operation number counter has reached a specified value, and when it is determined that the value of the special power combination continuous operation number counter has not reached the specified value (No ), The process proceeds to step S17-3, and if it is determined that the value of the special electric power continuous operation number counter has reached the specified value (Yes), the process proceeds to step S17-5.
Here, referring to the special power control table set in the special power control table area of the RAM 230, the number of round games specified in the special power control table is acquired as a specified value to make a determination. .
In step S17-3, a special winning opening closing time setting process is executed, and the process proceeds to step S17-4. In the big winning opening closing time setting process, a special big winning opening closing time is set in the special game timer with reference to the special electric winning control table set in the special electric winning control table area of the RAM 230.
In step S17-4, a special game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-12). In the special game phase update process, a value corresponding to the “pre-opening state for big prize opening” is set in the special game phase flag area of the RAM 230.

In step S17-5, an ending time setting process is executed, and the process proceeds to step S17-6. In the ending time setting process, a special ending time is set in the special game timer with reference to a special power control table set in the special power control table area of the RAM 230.
In step S17-6, an ending designation command setting process is executed, and the process proceeds to step S17-7. In the ending designation command setting process, the ending designation command is stored in the subcommand output request buffer.
In step S17-7, a special game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-12). In the special game phase update process, a value corresponding to the “big winning opening free wait state” is set in the special game phase flag area of the RAM 230.

Next, the special winning opening free weighting process executed in step S10-3 will be described.
FIG. 23 is a flowchart showing the special winning opening free weighting process.
When the big prize opening end wait process is executed in step S10-3, as shown in FIG. 23, first, the process proceeds to step S18-1.
In step S18-1, it is determined whether or not the value of the special game timer is “0”. If it is determined that the value of the special game timer is “0” (Yes), the process proceeds to step S18-2. If it is determined that the value of the special game timer is not “0” (No), the series of processes is terminated and the process proceeds to the next process (step S4-12).

In step S18-2, a game state setting process is executed, and the process proceeds to step S18-3. In the game state setting process, the game state is set.
Specifically, in the game state setting process, the value of the special figure high probability state flag in the RAM 230 is set according to the type of the stop symbol (big hit symbol).
At this time, when the type of the stop symbol is “one jackpot symbol” or “three jackpot symbol” to “5 jackpot symbol”, “1” is set in the special symbol high probability state flag area of the RAM 230. On the other hand, when the stop symbol type is “2 jackpot symbols” or “6 jackpot symbols”, “0” is set in the special symbol high probability state flag area of the RAM 230.
Next, a predetermined number of time reductions is set in the time reduction counter. At this time, if the type of the stop symbol is “2 jackpot symbols” or “6 jackpot symbols”, 100 [times] is set as the predetermined number of times. On the other hand, when the type of the stop symbol is “one jackpot symbol” or “three jackpot symbol” to “5 jackpot symbol”, 10000 [times] is set as the predetermined number of times. Also, “1” is set in the time reduction control flag area of the RAM 230.
Next, a value corresponding to the type of jackpot symbol is set in the previous jackpot symbol flag area of the RAM 230.
In step S18-3, a special game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-12). In the special game phase update process, a value corresponding to the “special figure change waiting state” is set in the special game phase flag area of the RAM 230.

Next, the normal game management process in step S4-12 will be described.
FIG. 24 is a flowchart showing the normal game management process.
Here, in the present embodiment, as a stage / stage (hereinafter referred to as “normal game phase”) of a game (hereinafter referred to as “normal game phase”) executed based on the normal symbol lottery, `` Status '', `` Normal diagram changing status '', `` Normal diagram stop symbol display status '', `` Multi-plan electric accessory release state '', `` Multi-plan electric accessory release control status '', `` Multi-plan electric feature closure enabled Seven states are defined: “state” and “usually waiting state for opening the electric accessory release”.
Then, a value (ordinary game phase flag) corresponding to one of the seven normal game phases is set in the normal game phase flag area of the RAM 230.
The ROM 220 stores a normal game control module corresponding to each normal game phase as a normal game control module (program) for controlling (executing) the normal game.
In the normal game management process, the normal game control module corresponding to the value set in the normal game phase flag area of the RAM 230 is selected, and the process based on the selected normal game control module is executed.

Specifically, when the normal game management process is executed in step S4-12, the process first proceeds to step S19-1, as shown in FIG.
In step S19-1, a normal game phase acquisition process is executed, and the process proceeds to step S19-2. In the normal game phase acquisition process, the value (normal game phase) set in the normal game phase flag area of the RAM 230 is acquired (loaded).
In step S19-2, a normal game control module acquisition process is executed, and the process proceeds to step S19-3. In the normal game control module acquisition process, the normal game control module corresponding to the value acquired in step S19-1 (normal game phase) is read.
In step S19-3, a normal game control module execution process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-13). In the normal game control module execution process, a process based on the normal game control module read in step S19-2 is started.
Specifically, when the value acquired in step S19-1 is a value corresponding to the “waiting state for normal map change”, a process for waiting for a normal map change to be described later is started, and the “current state for normal map change” is started. In the case of a value corresponding to, the process of changing the normal map described later is started, and in the case of the value corresponding to the “general map stop symbol display state”, the process of stopping the normal map described later is started, When it is a value corresponding to “a state before opening of an ordinary electric accessory”, a normal electric accessory opening pre-processing described later is started, and when it is a value corresponding to “an ordinary electric accessory opening control state”. When the normal electric actor release control process to be described later is started and the value corresponds to the “normal electric actor closing effective state”, the normal electric actor closing effective process to be described later is started, If the value corresponds to the `` object release end wait state '', Electric won game open end wait process is started.

Next, the process of waiting for a change in the normal map executed in step S19-3 will be described.
FIG. 25 is a flowchart showing the normal variation waiting process.
When the normal variation waiting process is executed in step S19-3, as shown in FIG. 25, first, the process proceeds to step S20-1.
In step S20-1, it is determined whether or not the value of the pending map counter is “1” or more, and when it is determined that the value of the pending map counter is “1” or more (Yes). , The process proceeds to step S20-2, and if it is determined that the value of the general-purpose hold number counter is not equal to or greater than “1” (No), the series of processes is terminated and the process proceeds to the next process (step S4-13) To do.
In step S20-2, a general-purpose hold number update process is executed, and the process proceeds to step S20-3. In the general figure hold number update process, the general figure hold number is updated.
Specifically, in the normal figure reservation number update process, one start information among the general figure start information stored in the normal start information storage area of the RAM 230 is selected as determination start information.
In the present embodiment, the universal chart start information acquired (stored) first among the general chart start information stored in the universal chart start information storage area is selected as the determination start information.

In step S20-3, a normal winning determination process is executed, and the process proceeds to step S20-4. In the normal figure winning determination process, the result of the normal symbol lottery is determined (normal figure winning determination).
The ROM 220 stores a common symbol winning lottery table in which the winning value of the normal symbol lottery is registered. In addition, as a common figure winning lottery table, a common figure winning lottery table corresponding to the execution of the time reduction control and a common figure winning lottery table corresponding to the stoppage of the time reduction control are stored.
In the common-place winning lottery table corresponding to the stoppage of the short-time control, the winning value is registered so that the winning probability is the first probability (1/99 in this embodiment). On the other hand, the win value is registered so that the winning probability is a second probability (1/1 in the present embodiment) higher than the first probability in the common figure winning lottery table corresponding to the execution of the short-time control. ing.
Then, in the normal figure winning determination process, the normal figure winning lottery is determined based on the winning random number included in the determination start information and the normal figure winning lottery table corresponding to the current execution state of time-shortening control (running or stopped). Make a decision.
Specifically, when the value of the winning random number included in the determination start information matches the winning value, the result of the normal symbol lottery is determined as “winning” (winning).
On the other hand, if the value of the winning random number included in the determination start information does not match the winning value, the result of the normal symbol lottery is determined to be “out” (losing).

In step S20-4, a common figure stop symbol determination process is executed, and the process proceeds to step S20-5. In the general symbol stop symbol determination process, the stop symbol type (stop symbol number) of the normal symbol is determined (normal symbol stop symbol determination).
Specifically, in the general symbol stop symbol determination process, if it is determined to be “winning” (winning) by the common symbol winning determination, “stop per symbol” is set as the type of stop symbol (stop symbol number). judge.
On the other hand, if it is determined as “out of” (decision) by the normal symbol winning determination, “out of symbol” is determined as the type of stop symbol (stop symbol number).
Next, the determined stop symbol type (stop symbol number) is stored in the stop symbol storage area of the RAM 230.
In step S20-5, a normal fluctuation pattern determination process is executed, and the process proceeds to step S20-6. In the normal pattern variation pattern determination process, the type (variation pattern number) of the variation pattern of the normal symbol is determined (normal pattern variation pattern determination).
Specifically, in the normal map variation pattern determination process, when the time reduction control is stopped, the first type (2.0 in this embodiment) is set as the type of the general map variation pattern (variation pattern number). The type corresponding to the variation time of [s] is determined.
On the other hand, when the time-shortening control is being executed, the second type (in this embodiment, the type corresponding to the fluctuation time of 0.5 [s]) is used as the type of the normal fluctuation pattern (variation pattern number). Determine.

In step S20-6, a normal time change time setting process is executed, and the process proceeds to step S20-7. In the usual figure fluctuation time setting process, the fluctuation time corresponding to the type of the usual figure fluctuation pattern (fluctuation pattern number) determined in step S20-6 is acquired. And the acquired fluctuation | variation time is set to a normal game timer.
In step S20-7, a map change display data setting process is executed, and the process proceeds to step S20-8. In the general map display data setting process, data for controlling the variable display of the general map display device is set.
Specifically, in the normal map display data setting process, first, a predetermined display time is set in the general map display timer.
Next, predetermined segment data is set as segment data corresponding to the common map display device. As a result, the segment corresponding to the set segment data is controlled to be lit out of a predetermined number of segments constituting the general-purpose display device.
In step S20-8, a normal game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-13). In the normal game phase update processing, a value corresponding to the “normal state changing state” is set in the normal game phase flag area of the RAM 230.

Next, the process during normal map change executed in step S19-3 will be described.
FIG. 26 is a flowchart showing the process during normal map change.
When the normal map change process is executed in step S19-3, the process first proceeds to step S21-1, as shown in FIG.
In step S21-1, it is determined whether or not the value of the normal game timer is “0”. If it is determined that the value of the normal game timer is not “0” (No), the process proceeds to step S21-2. When it is determined that the value of the normal game timer is “0” (Yes), the process proceeds to step S21-4.
In step S21-2, it is determined whether or not the value of the common map display timer is “0”. If it is determined that the value of the general map display timer is “0” (Yes), step S21− When the process proceeds to 3 and it is determined that the value of the normal display timer is not “0” (No), the series of processes is terminated and the process proceeds to the next process (step S4-13).
In step S21-3, a normal map display data update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-13). In the general map display data update process, data for controlling the variable display of the general map display device is updated.
Specifically, in the general map change display data update process, the segment data corresponding to the general map display device is updated.

In step S21-4, a normal stop display data setting process is executed, and the process proceeds to step S21-5. In the general map stop display data setting process, data for controlling the stop display of the general map display device is set.
Specifically, in the general symbol stop display data setting process, a stop symbol (seg data) stored in the stop symbol storage area of the RAM 230 is acquired.
Next, the acquired segment data (segment data related to the stop symbol) is set as segment data corresponding to the general-purpose display device. As a result, the segment corresponding to the set segment data is controlled to be turned on (stopped display) among a predetermined number of segments constituting the general-purpose display device.
In step S21-5, a normal stop time setting process is executed, and the process proceeds to step S21-6. In the usual stop time setting process, a predetermined stop time is set in the normal game timer.
In step S21-6, a normal game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-13). In the normal game phase update process, a value corresponding to the “normal game stop symbol display state” is set in the normal game phase flag area of the RAM 230.

Next, the routine stoppage process executed in step S19-3 will be described.
FIG. 27 is a flowchart showing processing during a normal stoppage.
When the normal map stop process is executed in step S19-3, as shown in FIG. 27, the process first proceeds to step S22-1.
In step S22-1, it is determined whether or not the value of the normal game timer is “0”. If it is determined that the value of the normal game timer is “0” (Yes), the process proceeds to step S22-2. If it is determined that the value of the normal game timer is not “0” (No), the series of processes is terminated and the process proceeds to the next process (step S4-13).
In step S22-2, it is determined whether or not the stop symbol is “per symbol”. If it is determined that the stop symbol is not “per symbol” (No), the process proceeds to step S22-3. If it is determined that the stop symbol is “per symbol” (Yes), the process proceeds to step S22-4.
In step S22-3, a normal game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-13). In the normal game phase update process, a value corresponding to the “normal state waiting state” is set in the normal game phase flag area of the RAM 230.
In step S22-4, normal electric control data setting processing is executed, and the process proceeds to step S22-5. In the ordinary electric combination control data setting process, control data for opening and closing the ordinary electric combination 52a is set.
The ROM 220 stores a normal power control table corresponding to the execution status (running or stopped) of the time-saving control. Each ordinary power control table includes a time before opening a normal power, a normal power service closing effective time, an opening end wait time, the number of opening / closing switching, and control data corresponding to each opening / closing switching (solenoid control data, control time). Data).
In the normal power control data setting process, the normal power control table corresponding to the execution status (running or stopped) of the short-time control is read, and the read normal power control table is stored in the normal power control table area of the RAM 230. Set.
Next, the number of times of opening / closing switching is read with reference to the normal power control table set in the normal power control table area of the RAM 230. Then, the read opening / closing switching frequency is set in the normal electric utility switching frequency counter. Also, “0” is set as the value of the ordinary electronic winning prize counter.

In step S22-5, a normal power combination opening time setting process is executed, and the process proceeds to step S22-6. In the normal power combination opening time setting process, a predetermined normal power combination release time is set in the normal game timer with reference to the normal power control table set in the normal power control table area of the RAM 230.
In step S22-6, a normal game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-13). In the normal game phase update process, a value corresponding to the “state before opening the normal electric accessory” is set in the normal game phase flag area of the RAM 230.

Next, the normal electric accessory opening pre-processing executed in step S19-3 will be described.
FIG. 28 is a flowchart showing the process for releasing the ordinary electric accessory.
When the normal electric accessory release pre-processing is executed in step S19-3, as shown in FIG. 28, first, the process proceeds to step S23-1.
In step S23-1, it is determined whether or not the value of the normal game timer is “0”. If it is determined that the value of the normal game timer is “0” (Yes), the process proceeds to step S23-2. If it is determined that the value of the normal game timer is not “0” (No), the series of processes is terminated and the process proceeds to the next process (step S4-13).
In step S23-2, a normal power combination opening / closing switching process is executed, and the process proceeds to step S23-3. The normal power combination opening / closing switching process will be described later.
In step S23-3, a normal game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-13). In the normal game phase update process, a value corresponding to the “ordinary electric accessory release control state” is set in the normal game phase flag area of the RAM 230.

Next, the normal electric combination opening / closing switching process in steps S23-2 and S25-3 will be described.
FIG. 29 is a flowchart showing the normal power combination opening / closing switching process.
When the ordinary power combination opening / closing switching process is executed in steps S23-2 and S25-3, the process first proceeds to step S24-1, as shown in FIG.
In step S24-1, it is determined whether or not the value of the normal power combination opening / closing switching number counter is “0”, and when it is determined that the value of the normal power combination opening / closing switching number counter is not “0” (No). Shifts to step S24-2, and when it is determined that the value of the normal electric utility opening / closing switching number counter is “0” (Yes), the series of processing is terminated and the next processing (step S23-3) is performed. Alternatively, the process proceeds to S25-4).
In step S24-2, a normal electronic combination control data setting process is executed, and the process proceeds to step S24-3. In the ordinary electric combination control data setting process, control data for controlling the ordinary electric combination 52a to an open state or a closed state is set.
Specifically, in the normal power combination control data setting process, the solenoid corresponding to the value of the normal power combination open / close switching counter is referred to by referring to the normal power combination control table set in the normal power combination control table area of the RAM 230. Read control data. Then, the read solenoid control data (control data designating energization or deenergization) is set in a predetermined area of the RAM 230. As a result, the control of the ordinary electric accessory solenoid 64 based on the set solenoid data is started, and the ordinary electric accessory 52a is controlled to be in an open state or a closed state.

In step S24-3, the normal electric control time setting process is executed, and the process proceeds to step S24-4. In the normal electric control time setting process, a control time for continuing the control based on the solenoid control data set in step S24-2 is set.
Specifically, in the normal power combination control time setting process, the control corresponding to the value of the normal power combination open / close switching counter is referred to by referring to the normal power control table set in the normal power control table area of the RAM 230. Read time. Then, the read control time is set in the normal game timer.
In step S24-4, the normal power combination opening / closing switching number counter update process is executed, the series of processes is terminated, and the process proceeds to the next process (step S23-3 or S25-4). In the normal power combination opening / closing switching number counter update process, a value obtained by subtracting “1” from the value set in the normal power combination opening / closing switching number counter is newly set in the normal power combination opening / closing switching number counter.

Next, the ordinary electric accessory release control process executed in step S19-3 will be described.
FIG. 30 is a flowchart showing the ordinary electric accessory release control process.
When the normal electric accessory release control process is executed in step S19-3, as shown in FIG. 30, first, the process proceeds to step S25-1.
In step S25-1, it is determined whether or not the value of the normal game timer is “0”. If it is determined that the value of the normal game timer is “0” (Yes), the process proceeds to step S25-2. If it is determined that the value of the normal game timer is not “0” (No), the process proceeds to step S25-4.
In step S25-2, it is determined whether or not the value of the normal power combination opening / closing switching number counter is “0”, and when it is determined that the value of the normal power combination opening / closing switching number counter is not “0” (No). The process proceeds to step S25-3, and if it is determined that the value of the ordinary power combination switching number counter is “0” (Yes), the process proceeds to step S25-5.
In step S25-3, a normal power combination opening / closing switching process (see FIG. 29) is executed, and the process proceeds to step S25-4.
In step S25-4, it is determined whether or not the value of the ordinary electronic winning prize counter has reached a predetermined upper limit (3 [ball] in the present embodiment), and the value of the ordinary electric winning prize counter is predetermined. If it is determined that the upper limit value has been reached (Yes), the process proceeds to step S25-5, and if it is determined that the value of the ordinary electronic winning prize counter has not reached the predetermined upper limit value (No). Terminates the series of processes and proceeds to the next process (step S4-13).

In step S25-5, a normal electric utility release control end process is executed, and the process proceeds to step S25-6. In the normal power combination release control end process, solenoid control data for designating the energization stop is set in a predetermined area of the RAM 230. As a result, the ordinary electric accessory 52a is controlled to be closed.
In step S25-6, normal electric utility closing effective time setting processing is executed, and the process proceeds to step S25-7. In the normal power combination closing valid time setting process, a normal power combination closing effective time is set in the normal game timer with reference to the normal power combination control table set in the normal power combination control table area of the RAM 230.
In step S25-7, a normal game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-13). In the normal game phase update process, a value corresponding to the “normal electric accessory closing valid state” is set in the normal game phase flag area of the RAM 230.

Next, the normal electric accessory closing effective process executed in step S19-3 will be described.
FIG. 31 is a flowchart showing a normal electric accessory closing effective process.
When the normal electric accessory closing effective process is executed in step S19-3, the process first proceeds to step S26-1 as shown in FIG.
In step S26-1, it is determined whether or not the value of the normal game timer is “0”. If it is determined that the value of the normal game timer is “0” (Yes), the process proceeds to step S26-2. If it is determined that the value of the normal game timer is not “0” (No), the series of processes is terminated and the process proceeds to the next process (step S4-13).
In step S26-2, an opening end wait time setting process is executed, and the process proceeds to step S26-3. In the opening end wait time setting process, a predetermined opening end wait time is set in the normal game timer with reference to the normal power combination control table set in the normal power combination control table area of the RAM 230.
In step S26-3, a normal game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-13). In the normal game phase update process, a value corresponding to the “ordinary electric accessory release end wait state” is set in the normal game phase flag area of the RAM 230.

Next, the ordinary electric accessory opening end weight process executed in step S19-3 will be described.
FIG. 32 is a flowchart showing the ordinary electric accessory release end weight process.
When the ordinary electric accessory release end weight process is executed in step S19-3, as shown in FIG. 32, first, the process proceeds to step S27-1.
In step S27-1, it is determined whether or not the value of the normal game timer is “0”. If it is determined that the value of the normal game timer is “0” (Yes), the process proceeds to step S27-2. If it is determined that the value of the normal game timer is not “0” (No), the series of processes is terminated and the process proceeds to the next process (step S4-13).
In step S27-2, a normal game phase update process is executed, a series of processes are terminated, and the process proceeds to the next process (step S4-13). In the normal game phase update process, a value corresponding to the “normal state waiting state” is set in the normal game phase flag area of the RAM 230.

Next, the performance display device control process in step S4-19 will be described.
FIG. 33 is a flowchart showing the performance display device control process.
The performance display device control process is a process based on a program for controlling the display of the performance display device 61. That is, the performance display device control process is a process based on a program stored in the non-use area m2 (program area) of the ROM 220. The performance display device control process is called during the execution of the timer interrupt process.
When the performance display device control process is called in step S4-19, the process proceeds to step S28-1, as shown in FIG.
In step S28-1, stack pointer saving processing is executed, and the process proceeds to step S28-2. In the stack pointer saving process, the value of the stack pointer used in the processing based on the program stored in the use area m1 is saved in the RAM saving area.
In step S28-2, a register saving process is executed, and the process proceeds to step S28-3. In the register saving process, the register value used in the processing based on the program stored in the use area m1 is saved in the RAM saving area.
In step S28-3, a ball number addition process is executed, and the process proceeds to step S28-4.
In the ball number addition process, the value stored in the out ball number addition value storage area of the RAM 230 is added to the value of the out ball number counter.
Next, the value stored in the payout amount addition value storage area of the RAM 230 is added to the value of the payout number counter.
In step S28-4, a base ratio calculation process is executed, and the process proceeds to step S28-5. The base ratio calculation process will be described later.

In step S28-5, a performance display device display process is executed, and the process proceeds to step S28-6. In the performance display device display process, the performance display device 61 sets control data for displaying the base ratio.
Specifically, in the performance display device display process, in the performance display device data signal control data setting area, the base ratio calculated in step S38-4 (the current base ratio in the current section) or step S38-2. The performance display device data signal control data corresponding to the base ratio (final base ratio of the previous section) stored in (1) is set.
Thus, according to the performance display device data signal control data set in the performance display device data signal control data setting area, in the performance display device 61, the current base ratio of the current section or the final section of the previous section The base ratio is displayed.
At this time, in the performance display device 61, the current base ratio of the current section and the final base ratio of the previous section are alternately displayed every predetermined time so that the current base ratio of the current section is displayed. The performance display device data signal control data corresponding to the base ratio and the performance display device data signal control data corresponding to the final base ratio of the previous section are alternately set every predetermined time.

In step S28-6, a register restoration process is executed, and the process proceeds to step S28-7. In the register restoration process, the value of the register saved in step S28-2 (the value of the register used in the process based on the program stored in the use area m1) is restored.
In step S28-7, stack pointer return processing is executed, a series of processing ends, and the processing proceeds to the next processing (step S4-20). In the stack pointer restoration process, the value of the stack pointer saved in step S28-1 (the value of the stack pointer used in the process based on the program stored in the use area m1) is restored.

Next, the base ratio calculation process in step S28-4 will be described.
FIG. 34 is a flowchart showing the base ratio calculation process.
The base ratio calculation process is a process based on a program for controlling the display of the performance display device 61. That is, the base ratio calculation process is a process based on a program stored in the non-use area m2 (program area) of the ROM 220. The base ratio calculation process is called during execution of the performance display device control process.
When the base ratio calculation process is called in step S28-4, as shown in FIG. 34, the process proceeds to step S38-1.
In step S38-1, it is determined whether or not the value of the out ball counter has reached the reference value. If it is determined that the value of the out ball counter has reached the reference value (Yes), step S38 is performed. -2 and if it is determined that the value of the out ball counter has not reached the reference value (No), the process proceeds to step S38-4.
In this embodiment, the reference value = 60000 × n (n = integer). “N” is a value indicating the current section, and “1” is set as an initial value.
In step S38-2, a base ratio storage process is executed, and the process proceeds to step S38-3. In the base ratio storage process, the base ratio calculated in the previous base ratio calculation process (step S38-4) is stored (stored) in a predetermined area of the RAM 230 as the final base ratio of the previous section. Also, the value of the payout counter is reset (“0” is set as the payout counter value).
In step S38-3, a reference value update process is executed, and the process proceeds to step S38-4. In the reference value update process, “1” is added to the value (n) indicating the current section. Thereby, the reference value is updated.
In step S38-4, a base ratio calculation process is executed, a series of processes are terminated, and the process proceeds to the next process (step S28-5). In the base ratio calculation process, the base ratio is calculated based on the value of the out-ball number counter and the value of the payout number counter.

(Various effects executed in the pachinko machine 1)
Next, various effects performed in the pachinko machine 1 will be described.

(Holding production)
First, a hold effect (hold display) executed in the pachinko machine 1 will be described.
In the pachinko machine 1, each start information (the special figure 1 start information or the special figure 2 start information) stored in the start information storage area (the special figure 1 start information storage area and the special figure 2 start information storage area) is targeted. The hold effect is executed.
The holding effect is that a special symbol notification display (starting determination) based on the start information (hereinafter referred to as “holding effect target start information”) that is the subject of the holding effect is held, or the holding effect. It is an effect that suggests (notifies) that a special symbol notification display based on the target start information is being executed.
In the hold effect, the hold symbol h corresponding to the hold effect target start information is displayed in the hold symbol display areas b1 to b3.

Specifically, in the reserved symbol display area b2, as the display position (display unit) where the reserved symbol h is displayed, four storage units (first storage unit to fourth storage unit) of the special figure 1 start information storage region The display position corresponding to each of) is defined.
In the reserved symbol display area b3, each of the four storage units (first storage unit to fourth storage unit) of the special figure 2 start information storage region is used as a display position (display unit) where the reserved symbol h is displayed. The display position corresponding to is defined.
And in the hold effect which uses the special figure 1 start information as the target hold effect target start information, the hold symbol h corresponding to the hold effect target start information is displayed in the hold symbol display areas b1 and b2.

That is, during the period in which the hold production target start information is stored in the special figure 1 start information storage area (the first storage unit to the fourth storage unit) (after acquisition of the hold production target start information, During the period before the start determination based on), the hold symbol h corresponding to the hold effect target start information is displayed in the hold symbol display area b2.
At this time, the hold symbol h corresponding to the hold effect target start information is displayed at the display position corresponding to the storage unit (first storage unit to fourth storage unit) in which the hold effect target start information is stored.
On the other hand, during the period in which the hold production target start information is stored in the changing start information storage area (after the start determination based on the hold production target start information is executed, the special symbol notification display based on the hold production target start information ends. In the period up to), the hold symbol h corresponding to the hold effect target start information is displayed in the hold symbol display area b1.
On the other hand, in the hold effect using the special figure 2 start information as the hold effect target start information, the hold symbol h corresponding to the hold effect target start information is displayed in the hold symbol display areas b1 and b3.
That is, during the period in which the hold production target start information is stored in the special figure 2 start information storage area (the first storage unit to the fourth storage unit) (after acquisition of the hold production target start information, During the period before the start determination based on), the hold symbol h corresponding to the hold effect target start information is displayed in the hold symbol display area b3.
At this time, the hold symbol h corresponding to the hold effect target start information is displayed at the display position corresponding to the storage unit (first storage unit to fourth storage unit) in which the hold effect target start information is stored.
On the other hand, during the period in which the hold production target start information is stored in the changing start information storage area (after the start determination based on the hold production target start information is executed, the special symbol notification display based on the hold production target start information ends. In the period up to), the hold symbol h corresponding to the hold effect target start information is displayed in the hold symbol display area b1.

For example, the various random numbers acquired in step S9-3 are stored as special figure 1 start information in the third storage unit of the special figure 1 start information storage area, and a holding effect for the special figure 1 start information is provided. When executed, the hold symbol h corresponding to the hold effect target start information is displayed at the display position corresponding to the third storage unit of the hold symbol display area b2 in response to the start of the hold effect.
Thereafter, the display area of the hold symbol h corresponding to the hold effect target start information in response to the storage area storing the hold effect target start information being changed (shifted) from the third storage unit to the second storage unit. However, the display position corresponding to the third storage unit is changed (shifted) to the display position corresponding to the second storage unit.
In addition, when the storage area for storing the hold effect target start information is changed (shifted) from the second storage unit to the first storage unit, the display area of the hold symbol h corresponding to the hold effect target start information However, the display position corresponding to the second storage unit is changed (shifted) to the display position corresponding to the first storage unit.
Furthermore, the storage area for storing the hold production target start information is changed (shifted) from the special figure 1 start information storage area (first storage unit) to the changing start information storage area. The display area of the reserved symbol h corresponding to the start information is changed (shifted) from the reserved symbol display area b2 (display position corresponding to the first storage unit) to the reserved symbol display area b1.
Then, in response to the end of the special symbol notification display based on the hold effect target start information, the display of the hold symbol h corresponding to the hold effect target start information in the hold symbol display area b1 is ended, whereby the hold effect ends. To do.

In the present embodiment, a normal hold effect and a hold notice effect are defined as the types of hold effects.
“Normal hold effect” is a type of hold effect that does not suggest the result of the preliminary determination (step S9-8) based on the hold effect target start information.
In the present embodiment, normal hold and special hold are defined as the type (mode) of the hold symbol h.
In the normal hold effect, the normal hold is displayed as the hold symbol h corresponding to the hold effect target start information.
In the normal hold effect, the hold effect target start information (Special Figure 1 start information or Special Figure 2 start information) is stored in the start information storage area (Special Figure 1 start information storage area or Special Figure 2 start information storage area). Is started in response to the end of the notification display of the special symbol based on the hold production target start information.

(Pending notice effect)
The “pending notice effect” is a kind of prefetch notice effect. That is, the hold notice effect is a type of hold effect that suggests the result of the prior determination (step S9-8) based on the predetermined start information by the form of the hold symbol h corresponding to the start information.
In the following description, the start information targeted for the hold notice effect is referred to as “hold notice target start information”. Further, the holding symbol h corresponding to the holding notice target start information is referred to as a notice target holding symbol hy.
In the present embodiment, the hold notice effect is an effect that suggests a result of pre-special symbol stop symbol determination based on the hold notice target start information (specifically, a possibility of being a “hit symbol”).
It should be noted that the hold notice effect may be configured to suggest a result of the prior special figure fluctuation pattern determination based on the hold notice target start information (specifically, the possibility of “super reach change”).
In the hold notice effect, special hold is displayed as the notice target hold symbol hy.
In the present embodiment, “blue hold”, “green hold”, “purple hold”, and “red hold” are defined as special hold modes (types).
Then, in the hold notice effect, the aspect of the notice target hold symbol hy changes, and the result of the prior determination based on the hold notice target start information (specifically, depending on the form of the notice target hold symbol hy that is finally displayed) It is suggested that a big hit gaming state may occur.
Here, the expectation of each aspect of the special hold is “red hold”, “purple hold”, “green hold”, “blue hold” in descending order of the big jackpot expectation (high hit expectation degree → high jackpot expectation degree) Low).

When the hold notice effect is executed, one or a plurality of hold change triggers and hold change contents corresponding to each hold change trigger are set. Then, in the hold notice effect, the mode of the notice target hold symbol hy changes according to the hold change content corresponding to the hold change trigger according to the arrival of the hold change trigger each time.
The “holding change opportunity” is an opportunity for changing the aspect of the notice target holding symbol hy. Further, the “holding change content” is a content in which the aspect of the notice target holding symbol hy changes.
In the present embodiment, as a change change opportunity, a start time of a variation effect corresponding to each preceding hold information, a start time of a change effect corresponding to the hold notice target start information, and the like are defined. When the hold notice effect is executed, one or more hold change triggers are set from these hold change triggers.
In this embodiment, the hold notice effect is executed only for the special figure 1 start information among the special figure 1 start information and the special figure 2 start information.

(Variation production)
Next, each aspect of the variation effect executed in the pachinko machine 1 will be described.
In the following description, the first effect symbol z1 displayed in the first effect symbol display area a1 is “left symbol”, and the first effect symbol z1 displayed in the first effect symbol display area a2 is “middle symbol”. The first effect symbol z1 displayed in the first effect symbol display area a3 is referred to as a “right symbol”.
In the present embodiment, the second effect symbol z2 is variably displayed in the second effect symbol display area a4 at all times during the execution of the variation effect (first variation effect and second variation effect).

First, each aspect of the first variation effect will be described.
In the present embodiment, as the first variation effect mode (variation effect number), “pseudo-continuous variation effect” corresponding to “pseudo-continuous variation variation” and “pseudo-continuous variation 2” corresponding to “pseudo-continuous variation 2”. An “effect”, a “pseudo continuous 3 variation effect” corresponding to “pseudo continuous 3 variation”, and a “pseudo continuous 4 variation effect” corresponding to “pseudo continuous 4 variation” are defined.
Also, modes corresponding to various types (variation pattern numbers) of “pseudo-continuous variation” are defined as modes (variable rendering number) of “pseudo-continuous variation effect”.

The “pseudo-continuous variation effect” includes a normal variation effect.
“Normal variation effect” refers to a display effect in which the first effect symbol z1 is normally variably displayed in the three first effect symbol display areas a1 to a3. Specifically, in the normal variation effect, the left symbol, the middle symbol, and the right symbol are normally varied and displayed.
“Normal variation display” refers to a display in which the types of the first effect symbols z1 displayed at the lottery result display positions in the first effect symbol display areas a1 to a3 are sequentially switched.
The “lottery result display position” refers to a position where the first effect symbol z1 is stopped and displayed in a stop effect to be described later.
In the “pseudo-continuous variation effect”, the “normal variation effect” is started in response to the start. Then, in the “pseudo continuous variation effect”, the normal variation display (“normal variation effect”) of the left symbol, the middle symbol, and the right symbol is continued until the end of the “pseudo continuous variation effect”.
In the “pseudo-variable rendering effect”, the pseudo-changing effect described later is not executed.

The “pseudo continuous variation effect” (“pseudo continuous 2 variation effect”, “pseudo continuous 3 variation effect”, and “pseudo continuous 4 variation effect”) is the first effect symbol during the execution of one special symbol variation display. The variation display of z1 is an effect that is executed a plurality of times in a pseudo manner. Specifically, the pseudo continuous variation effect includes a plurality of pseudo variation effects.
The “pseudo-continuous two-change effect” is configured to include two pseudo-change effects. The “pseudo-continuous three-change effect” is configured to include three pseudo-change effects. The “pseudo four-variation effect” is configured to include four pseudo-change effects.
In the following description, among the pseudo variation effects included in the pseudo continuous variation effect, the last pseudo variation effect is referred to as a “last pseudo variation effect”. In addition, among the pseudo variation effects included in the pseudo continuous variation effect, each time pseudo variation effect excluding the last round pseudo variation effect is referred to as “halfway pseudo variation effect”.

Each of the pseudo fluctuation effects (half-time pseudo fluctuation effect and final pseudo fluctuation effect) includes a normal fluctuation effect, a normal reach fluctuation effect, and a pseudo-continuous effect.
In the “normal reach variation effect”, the first effect symbol z1 is temporarily stopped in two or more areas among the three first effect symbol display areas a1 to a3, and is temporarily stopped in two or more areas. The combination of the first effect symbols z1 is a display effect that is a combination included in the “big hit symbol”.
In the following description, in the normal reach variation effect (or the reduced reach variation effect described later), the first effect symbol z1 that is temporarily stopped and displayed in the combination included in the “big hit symbol” is referred to as “the first state that forms the reach state”. It is referred to as “design z1”.
Specifically, in the normal reach variation effect, the reach state is formed by the left symbol and the right symbol. That is, in the normal reach variation effect, the left symbol and the right symbol are temporarily stopped and displayed, and the left symbol and the right symbol that are temporarily stopped are of the same type. In the normal reach variation effect, the normal variation display is continued for the middle symbol.
“Temporary stop display” is a state in which one kind of first effect symbol z1 is moved (swinged, rotated, etc.) in a predetermined manner at the lottery result display positions in the first effect symbol display areas a1 to a3. A display that continues for a predetermined time.

The “pseudo-continuous effect” is an effect that inquires whether or not the next pseudo-variable effect is executed.
The “pseudo-continuous effect” is a type of pseudo-continuous effect that indicates (implies) whether or not the next pseudo-variable effect is to be executed depending on whether or not the pseudo-continuous continuation symbol is temporarily displayed.
The “pseudo continuous continuation symbol” is configured to include information (in this embodiment, “NEXT” characters) that encourages execution of the next pseudo variation effect.
In the present embodiment, “pseudo continuous effect” and “pseudo continuous end effect” are defined as “pseudo continuous effect”.
The “pseudo continuous effect” is an effect that suggests that the next pseudo-variable effect is executed after asking whether or not the next pseudo-variable effect is executed.
Specifically, in the “pseudo continuous continuation effect”, a pseudo continuous continuation symbol (middle symbol) appears as a middle symbol, and the pseudo continuous continuation symbol moves toward the lottery result display position. At this time, the movement speed (fluctuation speed) of the pseudo continuous continuation symbol is slower than the movement speed of the first effect symbol z1 in the normal fluctuation display. In the “pseudo continuous continuation effect”, the pseudo continuous continuation symbol is temporarily stopped and displayed. This suggests that the next pseudo-variation effect will be executed.
The “pseudo-continuous end effect” is an effect suggesting that the next pseudo-variable effect is not executed after asking whether or not the next pseudo-variable effect is executed.
Specifically, in the “pseudo-continuation end effect”, a pseudo-continuation continuation symbol (middle symbol) appears as a middle symbol, similar to the pseudo-continuation continuation effect, and the pseudo-continuation continuation symbol moves toward the lottery result display position. Moving. At this time, the moving speed of the pseudo continuous continuation symbol is slower than the moving speed of the first effect symbol z1 in the normal variation display. In the “pseudo continuous end effect”, the pseudo continuous continuation symbol passes through the lottery result display position without being temporarily displayed. This suggests that the next pseudo fluctuation effect is not executed.

In each half-time pseudo variation effect, the reach variation effect is executed after the normal variation effect is executed. That is, after the left symbol, the middle symbol, and the right symbol are normally displayed in a variable manner, the left symbol and the right symbol are temporarily stopped and displayed, and a reach state is formed by the right symbol and the left symbol. Then, during the execution of the reach variation effect (during the formation of the reach state), the pseudo continuous effect is executed.
Each halfway pseudo-variable effect is ended in response to the end of the pseudo-continuous effect. Then, in response to the end of the halfway pseudo variation effect, the next pseudo variation effect is started.
In each final pseudo variation effect, the reach variation effect is executed after the normal variation effect is executed. That is, after the left symbol, the middle symbol, and the right symbol are normally displayed in a variable manner, the left symbol and the right symbol are temporarily stopped and displayed, and a reach state is formed by the right symbol and the left symbol. Then, the pseudo-continuous end effect is executed while the reach fluctuation effect is being executed (while the reach state is being formed).
The final pseudo-variation effect of each time is ended according to the end of the pseudo-continuous end effect. Then, the second variation effect (normal reach variation effect or super reach variation effect) is started in response to the end of the final pseudo variation effect.

Next, each aspect of the second variation effect will be described.
In the present embodiment, as the second variation effect mode (variation effect number), “reachless variation effect” corresponding to “reachless variation”, “normal reach variation effect” corresponding to “normal reach variation”, and “super “Super reach fluctuation production 1” corresponding to “reach fluctuation production 1”, “super reach fluctuation production 2” corresponding to “super reach fluctuation 2”, and “super reach fluctuation production 3” corresponding to “super reach fluctuation 3”. And “super reach variation effect 4” corresponding to “super reach variation 4” and “super reach variation effect 5” corresponding to “super reach variation 5” are defined.
Also, modes corresponding to various types of “variation without reach” (variation pattern numbers) are defined as modes (variation production numbers) of “variation production without reach”.
Also, modes corresponding to various types of “normal reach variation” (variation pattern numbers) are defined as modes (variation effect numbers) of “normal reach variation effects”.

The “unreachable variation effect” is configured to include a normal variation effect as a display effect.
Specifically, in the “reaching variation effect without reach”, the “normal variation effect” is executed in response to the start. That is, the normal variation display of the left symbol, the middle symbol, and the right symbol is started.
In the “unreachable variation effect”, the normal variation display (“normal variation effect”) of the left symbol, the middle symbol, and the right symbol is continued until the end of the “reachless variation effect”. Then, the stop effect is started in response to the end of the “non-reach fluctuation effect”.
Note that the reach variation effect and the development reach effect, which will be described later, are not executed in the reach-less variation effect.

The “normal reach fluctuation effect” includes a normal reach fluctuation effect.
Specifically, in the “normal reach fluctuation effect”, the normal reach fluctuation effect is executed in response to the start. That is, the left symbol and the right symbol form a reach state. The normal reach variation effect is ended when a predetermined time has elapsed from the start thereof.
The “normal reach variation effect” is terminated in response to the end of the normal reach variation effect. Then, the stop effect is started in response to the end of the “normal reach fluctuation effect”.
In the normal reach variation effect, the development reach effect described later is not executed.

“Super reach variation effect” (“super reach change effect 1” to “super reach change effect 5”) includes a normal reach change effect, a reduced reach change effect, and an extended reach effect as display effects. Has been.
The “reduction reach variation effect” refers to a display effect in which the first effect symbol z1 forming the reach state is reduced and displayed (temporary stop display). In particular, in the reduced reach variation effect, only the first effect symbol z1 that forms the reach state is displayed, and the display of the first effect symbol z1 that does not form the reach state is omitted. Specifically, in the reduced reach variation display, the right symbol and the left symbol forming the reach state are temporarily stopped in a reduced state, and the middle symbol is not displayed.

The “development reach effect” is an effect encouraging that the “hit symbol” is stopped and displayed in the effect symbol display areas a1 to a4. The development reach production is executed during the reach variation production.
In the present embodiment, “Development Reach Production 1” to “Development Reach Production 5” having different contents are defined as types of development reach production.
Then, in “super reach fluctuation production 1”, “development reach production 1” is executed as the development reach production. “Development reach effect 1” includes the display of “Development reach effect image 1” on the display screen 31a. “Development reach effect image 1” is an effect image by “character A”.
On the other hand, in the “super reach fluctuation production 2”, “development reach production 2” is executed as the development reach production. “Development reach effect 2” includes the display of “development reach effect image 2” on the display screen 31a. “Development reach effect image 2” is an effect image by “character B”.
On the other hand, in the “super reach variation effect 3”, the “advance reach effect 3” is executed as the advance reach effect. “Development reach effect 3” includes display of “Development reach effect image 3” on the display screen 31a. “Development reach effect image 3” is an effect image by “character C”.
On the other hand, in the “super reach fluctuation effect 4”, the “advance reach effect 4” is executed as the advance reach effect. “Development reach effect 4” includes a display of “development reach effect image 4” on the display screen 31a. “Development reach effect image 4” is an effect image by “character D”.
On the other hand, in the “super reach fluctuation effect 5”, the “advance reach effect 5” is executed as the advance reach effect. “Development reach effect 5” includes a display of “development reach effect image 5” on the display screen 31a. “Development reach effect image 5” is an effect image by “character E”.
As a result, the jackpot expectations for each type of development reach production are in the order of the highest jackpot expectation, "Development Reach Production 5,""Development Reach Production 4,""Development Reach Production 3," 2 ”,“ Development Reach Production 1 ”(High expectations for jackpot → Low expectations for jackpot).

In “super reach variation effect” (“super reach variation effect 1” to “super reach variation effect 5”), the reduced reach variation effect is executed after the normal reach variation effect is executed.
That is, from the state in which the left symbol and the right symbol form the reach state, the left symbol and the right symbol that form the reach state are reduced, and the reduced left symbol is moved to the upper left end portion of the display screen 31a and reduced. The displayed right symbol is moved to the upper right end of the display screen 31a, and the display of the middle symbol disappears. At this time, the reach state is formed by the left symbol and the right symbol that are stopped and displayed in the stop effect related to the predetermined stop effect number.
In the “super reach variation effect”, “development reach effect” (“development reach effect 1” to “development reach effect 5”) is executed during the period in which the reduction reach variation effect is being executed.
That is, the “development reach effect” is started in response to the elapse of a predetermined time from the start of the reduced reach fluctuation effect. The “development reach production” is ended when a predetermined time has elapsed from the start.
The “super reach variation effect” is ended in response to the end of the “development reach effect”. Then, the stop effect is started in response to the end of the “super reach fluctuation effect”.

(Main notice effect)
Next, the main notice effect performed in the pachinko machine 1 will be described.
In the pachinko machine 1, the main notice effect is executed while the change effect is being executed.
The “main notice effect” is an effect executed during the change effect, and suggests the result of start determination (special figure win determination, special figure stop symbol determination, special figure change pattern determination, etc.) related to the change effect. It has become a directing.
In the present embodiment, the main notice effect is executed during the first variation effect. Then, the main notice effect suggests the result of the special figure fluctuation pattern determination (specifically, the possibility that the type of the fluctuation pattern is “super reach fluctuation” (hereinafter referred to as “reach expectation”)).
In the present embodiment, telop notice, cut-in notice, button notice, character appearance notice, and the like are defined as the types of main notice effects.
Then, in the main notice effect corresponding to each type, the reach expectation level is suggested by the content of the effect.

(Processing executed by the effect control circuit 300)
Next, processing executed by the CPU of the effect control circuit 300 will be described.
First, the CPU initialization process executed by the CPU of the effect control circuit 300 will be described.
The effect control circuit 300 is provided with a reset circuit (not shown). The reset circuit generates a reset signal when the pachinko machine 1 is powered on.
The CPU of the effect control circuit 300 starts a CPU initialization process (not shown) in response to the generation of a reset signal by the reset circuit.
When the CPU initialization process is started, first, various registers, various timers (frame timer, phase timer, etc.), clock pulse oscillator, various RAMs, etc. are initialized. Next, effect random number update processing for updating various effect random numbers is executed. Thereafter, the effect random number update process is repeatedly executed until various interrupt processes described later are executed.

Next, command reception interrupt processing executed by the CPU of the effect control circuit 300 will be described.
The CPU of the effect control circuit 300 executes a command reception interrupt process (not shown) in response to receiving a control command from the main control circuit 200.
In the command reception interrupt process, the control command received from the main control circuit 200 is stored (stored) in the reception buffer area of the RAM of the effect control circuit 300.

Next, sub-timer interrupt processing executed by the CPU of the effect control circuit 300 will be described.
FIG. 35 is a flowchart showing the sub-timer interrupt process.
The effect control circuit 300 includes a clock pulse generation circuit. The clock pulse generation circuit generates a clock pulse signal every predetermined period.
The CPU of the effect control circuit 300 starts the sub-timer interrupt process shown in FIG. 35 at predetermined intervals based on the generation of the clock pulse by the clock pulse generation circuit. When the sub timer interrupt process is started, first, the process proceeds to step S31-1.
In step S31-1, a register saving process is executed, and the process proceeds to step S31-2. In the register saving process, the register value is saved in the saving area of the RAM.
In step S31-2, timer update processing is executed, and the process proceeds to step S31-3. In the timer update process, various timers provided in the effect control circuit 300 are updated.
In step S31-3, command analysis processing is executed, and the process proceeds to step S31-4. In the command analysis process, the control command stored in the reception buffer of the RAM of the effect control circuit 300 is analyzed, and the process according to the received control command is executed. The command analysis process will be described later.

In step S31-4, a time schedule management process is executed, and the process proceeds to step S31-5. In the time schedule management process, the progress of each performance is managed.
Here, the ROM of the effect control circuit 300 corresponds to each effect (each aspect of the change effect, each aspect of the stop effect, each aspect of the notice effect, each aspect of the pre-reading notice effect, each aspect of the hold effect, etc.). An effect control table is stored.
The “effect control table” is information that defines the progress of the effects (display effects, sound effects, lamp effects, movable object effects, etc.).
In each effect control table, a plurality of process data are registered in time series. Each process data includes one or a plurality of command information. Each command information is a process of designating the start of a predetermined effect (display effect, sound effect, lamp effect or movable object effect). In particular, each command information includes information for specifying the contents of the effect to be started (display effect number, sound effect number, lamp effect number, or movable object effect number).

In the time schedule management processing, an effect control table corresponding to each effect set in a predetermined area of the RAM of the effect control circuit 300, an effect management timer corresponding to the effect (the effect management timer for measuring the elapsed time of the effect) ) To manage the progress of the production.
Specifically, for each effect, the process based on the process data corresponding to the current value of the effect management timer among the process data registered in the effect control table is executed. Thus, the command information included in the process data is stored (stored) in a predetermined area of the RAM of the effect control circuit 300.
At this time, if the command information specifies the start of the display effect, the display effect request information specifying the display effect number included in the command information is the display effect request information storage area in the RAM of the effect control circuit 300. Saved in.
On the other hand, when the command information specifies the start of the sound effect, the sound effect request information specifying the sound effect number included in the command information is stored in the sound effect request information storage area of the RAM of the effect control circuit 300. Saved.
On the other hand, when the command information specifies the start of the lamp effect, the lamp effect request information specifying the lamp effect number included in the command information is stored in the lamp effect request information storage area of the RAM of the effect control circuit 300. Saved.
As described above, the processing based on each process data is sequentially executed for all the process data registered in the effect control table set in the predetermined area of the RAM of the effect control circuit 300.

In step S31-5, display control processing is executed, and the flow proceeds to step S31-6. In the display control process, display of the effect image (display effect) by the image display devices 31 and 32 is controlled.
Specifically, in the display control process, first, it is determined whether or not display effect request information is stored in the display effect request information storage area. If it is determined that the display effect request information is stored in the display effect request information storage area, the display effect scenario table corresponding to the display effect number specified by the LA display effect request information is selected and set. To do.
In the display control process, it is next determined whether or not a display effect scenario table is selected / set. And when it determines with the display effect scenario table having been selected and set, the display of the effect image by the image display apparatuses 31 and 32 is controlled according to the said display effect scenario table.

In step S31-6, a sound control process is executed, and the process proceeds to step S31-7. In the sound control process, the sound output (sound production) by the sound generator 22 is controlled.
Specifically, in the sound control process, first, it is determined whether or not the sound effect request information is stored in the sound effect request information storage area. When it is determined that the sound effect request information is stored in the sound effect request information storage area, the sound effect scenario table corresponding to the sound effect number specified by the sound effect request information is selected / set. .
In the sound control process, it is next determined whether or not a sound effect scenario table is selected / set. When it is determined that the sound effect scenario table is selected / set, the sound output by the sound generator 22 is controlled according to the sound effect scenario table.

In step S31-7, a lamp control process is executed, and the process proceeds to step S31-8. In the lamp control process, the operations (lamp effects) of the various lamps 20 and 21 are controlled.
Specifically, in the lamp control process, first, it is determined whether or not lamp effect request information is stored in the lamp effect request information storage area. When it is determined that the lamp effect request information is stored in the lamp effect request information storage area, the lamp effect scenario table corresponding to the lamp effect number specified by the lamp effect request information is selected / set. .
In the lamp control process, it is next determined whether or not a lamp effect scenario table is selected / set. If it is determined that the lamp effect scenario table is selected and set, lamp output data is generated according to the lamp effect scenario table, and the generated lamp output data is stored in the lamp data buffer area.
As a result, the lamp output data stored in the lamp data buffer area is output to each of the lighting bases 15 and 16 (LED driver) by a process (not shown).

  In step S31-8, a register restoration process is executed, and the sub timer interrupt process is terminated. In the register restoration process, the register value saved in step S31-1 is restored.

Next, the command analysis process in step S31-3 will be described.
FIG. 36 is a flowchart showing command analysis processing.
When the command analysis process is executed in step S31-3, the process proceeds to step S32-1, as shown in FIG.
In step S32-1, a set value command reception process is executed, and the process proceeds to step S32-2.
In the set value command reception process, it is determined whether or not a subcommand specifying a set value has been received. If it is determined that the subcommand specifying the setting value is received, the setting value specified by the subcommand is stored (stored) in a predetermined area of the RAM of the effect control circuit 300.
In step S32-2, a game state command reception process is executed, and the process proceeds to step S32-3.
In the gaming state command reception process, it is determined whether or not a gaming state designation command has been received. And when it determines with having received the game state designation | designated command, the setting of various effect flags is performed.
In step S32-3, a hold command reception process is executed, and the process proceeds to step S32-4. The hold command reception process will be described later.
In step S32-4, prefetch command reception processing is executed, and the flow proceeds to step S32-5. The prefetch command reception process will be described later.
In step S32-5, a variable command reception process is executed, and the process proceeds to step S32-6. The variable command reception process will be described later.
In step S32-6, stop command reception processing is executed, a series of processing ends, and the processing proceeds to the next processing (step S31-4). The stop command reception process will be described later.

Next, the hold command reception process in step S32-3 will be described.
FIG. 37 is a flowchart showing a hold command reception process.
When the hold command reception process is executed in step S32-3, the process proceeds to step S36-1, as shown in FIG.
In step S36-1, it is determined whether or not a hold number designation command has been received. If it is determined that a hold number designation command has been received (Yes), the process proceeds to step S36-2, and the hold number designation command is changed. If it is determined that it has not been received (No), the series of processes is terminated and the process proceeds to the next process (step S32-4).
In step S36-2, it is determined whether or not the hold number designation command specifies an increase in the hold number (that the hold number has increased by “1”), and the hold number designation command specifies an increase in the hold number. If it is determined (Yes), the process proceeds to step S36-3, and the hold number designation command does not specify an increase in the hold number (ie, it is specified that the hold number has decreased by “1”). When it determines (No), it transfers to step S36-4.

In step S36-3, the number-of-holds addition process is executed, the series of processes is terminated, and the process proceeds to the next process (step S32-4).
In the hold number addition process, first, it is determined whether or not the hold number designation command specifies an increase in the special figure 1 hold number.
If it is determined that the hold number designation command specifies an increase in the special figure 1 hold number, a value obtained by adding “1” to the value set in the special figure 1 hold number counter is newly set. Special figure 1 Set to the number of hold counter. In addition, a normal hold effect corresponding to the newly acquired (stored) special figure 1 start information is set.
For this purpose, an effect control table corresponding to the normal hold effect is read, and the read effect control table is set in a predetermined area of the RAM of the effect control circuit 300. At this time, as a display area for displaying the reserved symbol h, a storage unit (first storage unit) in which newly acquired special figure 1 start information is stored among the four display positions included in the reserved symbol display region b2. Display position corresponding to (.about.fourth storage section) is set. Here, the memory | storage part (1st memory | storage part-4th memory | storage part) where the newly acquired special figure 1 starting information is memorize | stored is determined based on the value of a special figure 1 hold | maintenance number counter.
On the other hand, if it is determined that the hold number designation command specifies an increase in the special figure 2 hold number, a value obtained by adding “1” to the value set in the special figure 2 hold number counter is newly set. Special figure 2 Set to the number of hold counter. Further, a normal hold effect corresponding to the newly acquired (stored) special figure 2 start information is set.
For this purpose, an effect control table corresponding to the normal hold effect is read, and the read effect control table is set in a predetermined area of the RAM of the effect control circuit 300. At this time, as a display area for displaying the reserved symbol h, a storage unit (first storage unit) in which newly acquired special figure 2 start information is stored among the four display positions included in the reserved symbol display region b3. Display position corresponding to (.about.fourth storage section) is set. Here, the memory | storage part (1st memory | storage part-4th memory | storage part) in which the newly acquired special figure 2 starting information is memorize | stored is determined based on the value of a special figure 2 reservation number counter.

In step S36-4, the number-of-holds subtraction process is executed, the series of processes is terminated, and the process proceeds to the next process (step S32-4).
In the hold number subtraction process, first, it is determined whether or not the hold number designation command specifies subtraction of the special figure 1 hold number.
If it is determined that the special figure 1 hold number subtraction is specified by the hold number designation command, a value obtained by subtracting “1” from the value set in the special figure 1 hold number counter is newly set. Special figure 1 is set in the number-of-holds counter. Further, the display position of each reserved symbol h displayed in the reserved symbol display area b2 is changed (shifted).
Specifically, the holding effect corresponding to the holding symbol h displayed in the holding symbol display area b1 is ended. Thereby, the display of the reserved symbol h corresponding to the ended reserved effect is ended.
Further, when the reserved symbol h is displayed at the display position corresponding to the first storage unit in the reserved symbol display area b2, the display position of the reserved symbol h is set to the reserved symbol display area b2 (in the first storage unit). The corresponding display position is changed (shifted) to the reserved symbol display area b1.
In addition, when the hold symbol h is displayed at the display position corresponding to the second storage unit in the hold symbol display area b2, the display position of the hold symbol h is changed from the display position corresponding to the second storage unit to the second display unit b2. Change (shift) to the display position corresponding to one storage unit.
Further, when the reserved symbol h is displayed at the display position corresponding to the third storage unit in the reserved symbol display area b2, the display position of the reserved symbol h is changed from the display position corresponding to the third storage unit to the second display unit b2. 2 Change (shift) to the display position corresponding to the storage unit.
In addition, when the holding symbol h is displayed at the display position corresponding to the fourth storage unit in the holding symbol display area b2, the display position of the holding symbol h is changed from the display position corresponding to the fourth storage unit to the second display unit b2. 3. Change (shift) to the display position corresponding to the storage unit.

On the other hand, if it is determined that the hold number designation command specifies subtraction of the special figure 2 hold number, a value obtained by subtracting “1” from the value set in the special figure 2 hold number counter is newly set. Special figure 2 Set to the number-of-holds counter. In addition, the display position of each reserved symbol h displayed in the reserved symbol display area b3 is changed (shifted).
Specifically, the holding effect corresponding to the holding symbol h displayed in the holding symbol display area b1 is ended. Thereby, the display of the reserved symbol h corresponding to the ended reserved effect is ended.
In addition, when the reserved symbol h is displayed at the display position corresponding to the first storage unit in the reserved symbol display area b3, the display position of the reserved symbol h is set to the reserved symbol display area b3 (in the first storage unit). The corresponding display position is changed (shifted) to the reserved symbol display area b1.
In addition, when the reserved symbol h is displayed at the display position corresponding to the second storage unit in the reserved symbol display area b3, the display position of the reserved symbol h is changed from the display position corresponding to the second storage unit to the second display unit b3. Change (shift) to the display position corresponding to one storage unit.
In addition, when the reserved symbol h is displayed at the display position corresponding to the third storage unit in the reserved symbol display area b3, the display position of the reserved symbol h is changed from the display position corresponding to the third storage unit to the second display unit b3. 2 Change (shift) to the display position corresponding to the storage unit.
In addition, when the holding symbol h is displayed at the display position corresponding to the fourth storage unit in the holding symbol display area b3, the display position of the holding symbol h is changed from the display position corresponding to the fourth storage unit to the second display unit b3. 3. Change (shift) to the display position corresponding to the storage unit.

Next, the prefetch command reception process in step S32-4 will be described.
FIG. 38 is a flowchart showing prefetch command reception processing.
When the prefetch command reception process is executed in step S32-4, the process proceeds to step S33-1, as shown in FIG.
In step S33-1, it is determined whether or not a prefetch designation command (first prefetch designation command, second prefetch designation command and third prefetch designation command) has been received, and if it is determined that a prefetch designation command has been received (Yes) ), The process proceeds to step S33-2, and if it is determined that the prefetch designation command has not been received (No), the series of processes is terminated and the process proceeds to the next process (step S32-5).

In step S33-2, a prefetch information analysis process is executed, and the process proceeds to step S33-3. In the prefetch information analysis process, information designated by the prefetch designation command is stored in a predetermined area of the RAM of the effect control circuit 300 as the hold information.
In the RAM of the effect control circuit 300, a hold information storage area capable of storing hold information is set. In addition, as a reserved information storage area, a first reserved information storage area corresponding to the first special symbol lottery (Special Figure 1 start information storage area of the RAM 230) and a second special symbol lottery (Special Figure 2 start information storage area of the RAM 230). ) Corresponding to the second hold information storage area.
The first hold information storage area includes a first storage unit to a fourth storage unit as a storage unit capable of storing the hold information. In the first hold information storage area, hold information corresponding to the special figure 1 start information stored in the special figure 1 start information storage area is stored. That is, the hold information stored in the first storage unit of the first hold information storage area corresponds to the special figure 1 start information stored in the first storage unit of the special figure 1 start information storage area. Further, the hold information stored in the second storage unit of the first hold information storage area corresponds to the special figure 1 start information stored in the second storage unit of the special figure 1 start information storage area. Further, the hold information stored in the third storage unit of the first hold information storage area corresponds to the special figure 1 start information stored in the third storage unit of the special figure 1 start information storage area. Further, the hold information stored in the fourth storage unit of the first hold information storage area corresponds to the special figure 1 start information stored in the fourth storage unit of the special figure 1 start information storage area.
The second hold information storage area includes a first storage unit to a fourth storage unit as a storage unit capable of storing the hold information. In the second hold information storage area, hold information corresponding to the special figure 2 start information stored in the special figure 2 start information storage area is stored. That is, the hold information stored in the first storage unit of the second hold information storage area corresponds to the special figure 2 start information stored in the first storage unit of the special figure 2 start information storage area. Further, the hold information stored in the second storage unit of the second hold information storage area corresponds to the special figure 2 start information stored in the second storage unit of the special figure 2 start information storage area. Further, the hold information stored in the third storage unit of the second hold information storage area corresponds to the special figure 2 start information stored in the third storage unit of the special figure 2 start information storage area. Further, the hold information stored in the fourth storage unit of the second hold information storage area corresponds to the special figure 2 start information stored in the fourth storage unit of the special figure 2 start information storage area.
Each hold information includes symbol information indicating the type of stop symbol, first variation information indicating the content of the variation mode (“variation mode number” or “undefined value”), and the content of the variation pattern (“variation pattern number” or Second variation information indicating “indefinite value”).

In the prefetch information analysis process, first, it is determined whether or not the received first prefetch designation command corresponds to the first special symbol lottery.
When it is determined that the received first prefetching designation command corresponds to the first special symbol lottery, the type of stop symbol designated by the first prefetching designation command (“missing symbol” or “hit p symbol” )), The contents of the fluctuation mode designated by the second prefetch designation command ("fluctuation mode m" or "undefined value"), and the contents of the fluctuation pattern designated by the third prefetch designation command ("fluctuation pattern n" or " Indefinite value "), the symbol information corresponding to the analyzed stop symbol type, the first variation information corresponding to the analyzed variation mode content, and the second corresponding to the analyzed variation pattern content Hold information including fluctuation information is generated. Then, the generated hold information is stored (saved) in the first hold information storage area.
On the other hand, when it is determined that the received first prefetching designation command corresponds to the second special symbol lottery, the type of stop symbol designated by the first prefetching designation command (“missing symbol” or “hit p symbol” )), The contents of the fluctuation mode designated by the second prefetch designation command ("fluctuation mode m" or "undefined value"), and the contents of the fluctuation pattern designated by the third prefetch designation command ("fluctuation pattern n" Indefinite value "), the symbol information corresponding to the analyzed stop symbol type, the first variation information corresponding to the analyzed variation mode content, and the second corresponding to the analyzed variation pattern content Hold information including fluctuation information is generated. Then, the generated hold information is stored (saved) in the second hold information storage area.
In the following description, the hold information stored in the hold information storage area in step S33-2 is referred to as “prefetch target hold information”. Further, among the hold information stored in the first hold information storage area, the hold information for which notification display (variable display and stop display) is executed before the prefetch target hold information is referred to as “preceding hold information”.

In step S33-3, it is determined whether or not the prefetching notice effect is being executed. If it is determined that the prefetching notice effect is not being executed (No), the process proceeds to step S33-4 and the prefetching notice effect is displayed. If it is determined that the process is being executed (Yes), the series of processes is terminated and the process proceeds to the next process (step S32-5).
In the present embodiment, “1” is set in the prefetching notice effect flag area in the RAM of the effect control circuit 300 during execution of the prefetching notice effect. Therefore, in step S33-3, it is determined whether or not the prefetching notice effect is being executed based on whether or not “1” is set in the prefetching notice effect flag area in the RAM of the effect control circuit 300. .
In step S33-4, it is determined whether or not the prefetching notice effect execution condition is satisfied. If it is determined that the prefetching notice effect execution condition is satisfied (Yes), the process proceeds to step S33-5, and the prefetching notice effect execution condition is satisfied. If it is determined that the condition is not satisfied (No), the series of processes is terminated and the process proceeds to the next process (step S32-5).
In the present embodiment, (1) the prefetch target hold information is the hold information corresponding to the special figure 1 start information, and (2) the predecessor hold information of a predetermined number (“2” in the present embodiment) or more is stored. (3) No preceding hold information indicating the type (variation pattern number) belonging to “normal reach fluctuation” or “super reach fluctuation” as the type of fluctuation pattern, and (4) the time-saving control is stopped. It is determined that the pre-reading notice effect execution condition is satisfied when all conditions of (5) that the big hit gaming state is not occurring are satisfied.
Note that the contents of the pre-reading notice effect execution condition can be changed as appropriate. In other words, not all of the above conditions (1) to (5) but a condition in which it is determined that the pre-reading notice effect execution condition is satisfied when one or more of the above conditions (1) to (5) are satisfied. It doesn't matter. Further, as the pre-reading notice effect execution condition, other conditions different from the above conditions (1) to (5) may be included.

In step S33-5, a pre-reading notice effect lottery process is executed, and the process proceeds to step S33-6. In the prefetching notice effect lottery process, a prefetching notice effect lottery for determining whether or not to execute the prefetch notice effect is executed.
The ROM of the effect control circuit 300 stores a prefetching notice effect lottery table in which the winning value of the prefetching notice effect lottery is registered.
In the prefetching notice effect lottery process, first, a prefetching notice effect lottery random number is acquired from a predetermined random number counter. Then, based on the acquired prefetching notice effect lottery random number and the prefetching notice effect lottery table, it is determined whether to execute the prefetching notice effect.
In step S33-6, it is determined whether or not the prefetching notice effect lottery executed in step S33-5 has been won. If it is determined that the prefetching notice effect lottery has been won (Yes), the process proceeds to step S33-7. If it is determined that it has been lost in the pre-reading notice effect lottery (No), the series of processes is terminated and the process proceeds to the next process (step S32-5).

In step 33-7, a pre-reading notice effect setting process is executed, the series of processes is terminated, and the process proceeds to the next process (step S32-5). In the prefetching notice effect setting process, the contents of the prefetching notice effect (holding notice effect) are set.
Specifically, in the prefetch notice effect setting process, first, a hold final mode selection process is executed. In the hold final mode selection process, the hold final mode is selected and set.
The “holding final mode” refers to a mode of the notice target holding symbol hy that finally changes in the holding notice effect.
The ROM of the effect control circuit 300 stores a hold final color lottery table in which correspondence between the hold final mode lottery random number and the hold final mode is registered.
In addition, a hold final mode lottery table corresponding to each type of variation pattern is stored as the hold final mode lottery table.
In the hold final mode selection process, first, a hold final mode lottery random number is acquired from a predetermined random number counter. Further, the type of the variation pattern indicated by the prefetch target hold information is confirmed, and the hold final mode lottery table corresponding to the check result is read. Then, the final hold mode is selected (determined) based on the acquired final hold mode lottery random number and the read final hold mode lottery table.

Next, in the pre-reading notice effect setting process, a hold change opportunity selection process is executed. In the hold change opportunity selection process, a hold change opportunity is selected and set.
The ROM of the effect control circuit 300 stores a hold change opportunity lottery table in which correspondences between hold change opportunity lottery random numbers and hold change patterns are registered.
The “holding change pattern” is information (scenario data) for specifying a combination of the holding change triggers.
In addition, a hold change opportunity lottery table corresponding to each combination of the special figure 1 hold number ("2" to "4") and the hold final mode is stored as the hold change opportunity lottery table.
In the hold change opportunity selection process, first, a hold change opportunity lottery random number is acquired from a predetermined random number counter. Moreover, the number of special figure 1 hold | maintenance and the hold | maintenance last aspect selected by the hold | maintenance last aspect selection process are confirmed, and the hold | maintenance change opportunity lottery table corresponding to this confirmation result is read. Then, a hold change pattern is determined (determined) based on the acquired hold change trigger lottery random number and the read hold change trigger lottery table. Then, according to the determined hold change pattern, one or more hold change triggers related to the hold notice effect are set.

In the pre-reading notice effect setting process, next, a pending change content selection process is executed. In the hold change content selection process, the hold change content corresponding to each hold change opportunity is selected and set.
Specifically, in the pending change content selection process, as the pending change content corresponding to each pending change opportunity, the mode of the advance notice target hold symbol hy before the change and the mode of the advance notice target hold symbol hy after the change are: Is set.
In this embodiment, among one or more hold change triggers set in the hold change trigger selection process, each hold is performed in order from the hold change trigger (later hold change trigger) that arrives (occurs) later. The pending change content corresponding to the change opportunity is selected.
For example, when a hold change opportunity of 3 [times] is set in the hold change opportunity selection process, a third (last) hold change opportunity, a second hold change opportunity, and a first hold change opportunity are arranged in this order. Then, the hold change content corresponding to each hold change opportunity is selected.
Further, when selecting the hold change content corresponding to each hold change opportunity, first the aspect of the notice target hold symbol hy after the change is selected, and then the form of the notice target hold symbol hy before the change is selected. Selected. At this time, a mode with a low expectation is determined as a mode of the notification target reserved symbol hy before the change, compared with a mode of the notification target reserved symbol hy after the change. Thereby, according to the arrival of the hold change opportunity of each time, the aspect of the notice target hold symbol hy is changed (promoted) to a form with high expectation.
The ROM of the effect control circuit 300 stores a pending change content lottery table in which correspondences between the pending change content lottery random numbers and the mode of the notice target pending symbol hy before change are registered.
In addition, a hold change content lottery table corresponding to each mode of the hold symbol h (a mode of the notification target hold symbol hy after the change) is stored as the hold change content lottery table.
Then, in the pending change content lottery table corresponding to each aspect of the reserved symbol h (aspect of the notification target reserved symbol hy after the change), the notification target reserved symbol hy after the change is set as the aspect of the preliminary notification target reserved symbol hy before the change. Only the mode with low expectation is registered as compared with the above mode.
In the pending change content selection processing, first, the pending change content is selected for the last pending change timing among the pending change timings set in the pending change timing selection processing. In order to do this, first, the mode of the notice target reserved symbol hy after the change related to the last change change opportunity is selected. At this time, the final hold mode selected in the final hold mode selection process is selected as the post-change notice target hold symbol hy related to the final hold change opportunity. Next, the aspect of the notice subject hold symbol hy before the change related to the last hold change opportunity is selected. To this end, first, a pending change content lottery random number is obtained from a predetermined random number counter. In addition, the holding change content lottery table corresponding to the mode of the notice target holding symbol hy after the change selected for the last holding change opportunity is read. Then, based on the acquired hold change content lottery random number and the read hold change content lottery table, the mode of the notice target hold symbol hy before the change related to the last hold change opportunity is selected.
In the hold change content selection process, next, the hold change contents are selected for each hold change opportunity except for the last hold change trigger among the hold change triggers set in the hold change trigger selection process. At this time, the hold change content corresponding to each hold change trigger is determined in order from the hold change trigger that comes later.
In order to determine the hold change content corresponding to each hold change trigger, first, the mode of the notice target hold symbol hy after the change related to the hold change trigger is determined. At this time, as the mode of the notice target reserved symbol hy after the change related to the current hold change trigger, the mode of the notice target hold symbol hy before the change already selected for the next hold change trigger is selected. Next, the mode of the notice target hold symbol hy before the change related to the hold change opportunity this time is determined. To this end, first, a pending change content lottery random number is obtained from a predetermined random number counter. In addition, the holding change content lottery table corresponding to the mode of the notification target holding symbol hy after the change selected for the current holding change opportunity is read. Then, based on the acquired hold change content lottery random number and the read hold change content lottery table, the mode of the notice target hold symbol hy before change related to the current hold change opportunity is selected.
In the pending change content selection process, next, the pending change content selected for each pending change trigger is set in association with the pending change trigger. As a result, according to the arrival of each hold change opportunity, the mode of the notice target hold symbol hy changes (promotes) according to the hold change content set for the hold change trigger.

In the pre-reading notice effect setting process, next, “1” is set in the pre-reading notice effect flag area in the RAM of the effect control circuit 300.
Thus, the hold notice effect is started.
Note that “0” is set in the pre-reading notice effect flag area in the RAM of the effect control circuit 300 in accordance with the end of the hold notice effect by a process not shown.

Next, the variable command reception process in step S32-5 will be described.
FIG. 39 is a flowchart showing the variable command reception process.
When the variable command reception process is executed in step S32-5, the process proceeds to step S34-1 as shown in FIG.
In step S34-1, it is determined whether a predetermined control command has been received. If it is determined that the predetermined control command has been received (Yes), the process proceeds to step S34-2, and the predetermined control command is changed. If it is determined that it has not been received (No), the series of processes is terminated and the process proceeds to the next process (step S32-6).
Here, the predetermined control commands are a symbol type designation command, a variation mode designation command, and a variation pattern designation command.
In step S34-2, a stop effect determination process is executed, and the process proceeds to step S34-3. In the stop effect determination process, a stop effect mode (stop effect number) is determined.
Specifically, in the stop effect determination process, the stop effect mode (stop effect number) is determined based on the stop symbol type specified by the symbol type specifying command. Then, the determined stop production number is stored in a predetermined area of the RAM of the production control circuit 300.

In step S34-3, a variation effect determination process is executed, and the process proceeds to step S34-4. In the variation effect determination process, a variation effect mode (variation effect number) is determined.
Specifically, in the variation effect determination process, first, a first variation effect determination process for determining the mode (variation effect number) of the first variation effect is executed.
The ROM of the effect control circuit 300 stores a first variation effect lottery table in which the correspondence between the variation mode type (variation mode number) and the first variation effect mode (variation effect number) is registered. .
In the first variation effect determination process, first, the first variation effect lottery table is read. The first variation effect corresponding to the variation mode type (variation mode number) designated by the variation mode designation command among the first variation effect modes (variation effect numbers) registered in the first variation effect lottery table. The mode is determined (selected).

In the variation effect determination process, next, a second variation effect determination process for determining a mode (variation effect number) of the second variation effect is executed.
The ROM of the effect control circuit 300 stores a second variation effect lottery table in which the correspondence between the variation pattern type (variation pattern number) and the second variation effect mode (variation effect number) is registered. .
In the second variation effect determination process, first, the second variation effect lottery table is read. The second variation effect corresponding to the variation pattern type (variation pattern number) specified by the variation pattern designation command among the second variation effect modes (variation effect numbers) registered in the second variation effect lottery table. The mode is determined (selected).

In step S34-4, a notice effect determination process is executed, and the process proceeds to step S34-5. In the notice effect determination process, the mode of the main notice effect is selected.
The ROM of the effect control circuit 300 stores a main notice category lottery table in which correspondences between main notice category lottery random numbers and notice effects are registered.
In addition, a main notice category lottery table corresponding to each variation pattern is stored as the main notice category lottery table.
In the notice effect determination process, first, the main notice category lottery table corresponding to the type of the variation pattern designated by the variation pattern designation command is read. Also, a main notice category lottery random number is acquired from a predetermined random number counter. Based on the read main notice category lottery table and the acquired main notice category lottery random number, the mode of the main notice effect is selected (determined).

In step S34-5, a variation effect setting process is executed, a series of processes are terminated, and the process proceeds to the next process (step S32-6). In the variation effect setting process, an effect control table for the variation effect is set.
Specifically, in the variation effect setting process, the effect control table corresponding to the first variation effect mode (variation effect number) determined in step S34-3 and the second variation effect mode determined in step S34-3. An effect control table corresponding to (variable effect number) is read out.
Next, the effect control tables that have been read out are combined to generate an effect control table related to the change effect. Then, the generated effect control table is set in a predetermined area of the RAM of the effect control circuit 300. Thereby, the fluctuating effect is started.
Moreover, the effect control table corresponding to the aspect of the main notice effect selected at step S34-4 is read. Then, the read effect control table is set in a predetermined area of the RAM of the effect control circuit 300. Accordingly, the main notice effect is started at a predetermined timing during the execution of the variable effect.

Next, stop command reception processing in step S32-6 will be described.
FIG. 40 is a flowchart showing stop command reception processing.
When the stop command reception process is executed in step S32-6, the process proceeds to step S35-1, as shown in FIG.
In step S35-1, it is determined whether or not a stop designation command has been received. If it is determined that a stop designation command has been received (Yes), the process proceeds to step S35-2 and the stop designation command has been received. If it is determined that there is not (No), the series of processes is terminated and the process proceeds to the next process (step S32-7).
In step S35-2, a stop effect setting process is executed, a series of processes are terminated, and the process proceeds to the next process (step S32-7). In the stop effect setting process, an effect control table for stop effect is set.
Specifically, in the stop effect setting process, an effect control table corresponding to the stop effect number determined in step S34-2 is read. Then, the read effect control table is set in a predetermined area of the RAM of the effect control circuit 300. Thereby, a stop effect is started.
Here, in the stop effect, the left symbol, the middle symbol, and the right symbol that were temporarily stopped at the end of the variation effect are stopped and displayed.

(Operation of pachinko machine 1)
Next, the operation of the pachinko machine 1 will be described.
In the pachinko machine 1, when a predetermined condition is satisfied (for example, when various effects are executed to suggest (notify) that the result of the special figure winning determination is “big hit” during execution of the fluctuation effect, When the stop effect with “” is executed, when various notice effects are executed, etc., the lamp effect based on the “lamp effect scenario table 01” shown in FIG. 41A is executed.
In the scenario control data registered in the “ramp effect scenario table 01”, “lamp scenario data 00” is designated as “layer 1”, and “lamp scenario data 01” is designated as “layer 2”. .
As a result, during the period when the “lamp effect scenario table 01” is selected and set, “lamp scenario data 00” and “lamp scenario data 01” are combined to generate lamp output data.
Here, the “lamp scenario data 01” is data for executing an operation in which the eight light-emitting blocks L1 to L8 emit light in “rainbow colors” (hereinafter referred to as “rainbow-colored lighting operation”). .
On the other hand, the “lamp scenario data 00” is a predetermined pattern, in which some of the eight light emitting blocks L1 to L8 are sequentially selected, and the selected light emitting block blinks (hereinafter referred to as “lighting block data 00”). This is data for executing “random flashing operation”.
Therefore, by combining “lamp scenario data 00” and “lamp scenario data 01” to generate lamp output data, it is possible to add a random lighting operation to the rainbow lighting operation. It becomes.
Therefore, an effect that a confetti is dancing can be added to the rainbow-colored lighting operation, and the expression of the lamp effect can be made gorgeous.
Here, in the present embodiment, the establishment of a predetermined condition (for example, the start of various effects that suggest (notify) that the result of the special figure winning determination is “big hit” during execution of the fluctuation effect, The lamp effect based on the “ramp effect scenario table 01” is started in response to the displayed stop effect, the start of various notice effects, and the like. In the lamp effect based on the “lamp effect scenario table 01”, a random flashing operation is added to the rainbow-colored lighting operation from the start to the end. However, in the lamp effect based on the “lamp effect scenario table 01”, a random blinking operation may be added to the rainbow-colored lighting operation only during a period from the start until a predetermined time elapses. .
Specifically, in the lamp effect based on the “lamp effect scenario table 01”, the rainbow lighting operation is executed from the start to the end. In particular, in the lamp effect based on the “lamp effect scenario table 01”, the addition of the random flashing operation to the rainbow lighting operation is started in response to the start, and the first predetermined time has elapsed since the start of the lamp effect. Accordingly, the addition of the random flashing operation to the rainbow lighting operation is terminated, and the rainbow lighting operation is performed in response to the elapse of a second predetermined time (second predetermined time> first predetermined time) from the start of the lamp effect. May be terminated, and the lamp effect may be terminated.

Further, in the pachinko machine 1, when a predetermined condition is satisfied (for example, when various effects that suggest (notify) that the result of the special figure winning determination is “hit” during execution of the variation effect, When a stop effect in which “hit symbol” is displayed, when various notice effects are executed, etc., a lamp effect based on the “ramp effect scenario table 02” shown in FIG. 41B is executed. .
In the “lamp effect scenario table 02”, scenario control data “No. 1” and scenario control data “No. 2” are registered.
In the scenario control data “No. 1”, the lamp scenario data corresponding to “Layer 1” is not designated, and “Ramp scenario data 02” is designated as “Layer 2”.
On the other hand, in the scenario control data of “No. 2”, “ramp scenario data 00” is designated as “layer 1”, and “lamp scenario data 02” is designated as “layer 2”.
As a result, during the period in which the scenario control data “No. 1” is selected and set, the lamp output data is generated based only on the “lamp scenario data 02”.
On the other hand, during the period when the scenario control data of “No. 2” is selected and set, the lamp output data is generated by synthesizing “lamp scenario data 00” and “lamp scenario data 02”. .
Here, the “lamp scenario data 02” is data for the eight light emitting blocks L1 to L8 to perform an operation of emitting “red” light (hereinafter referred to as “red lighting operation”).
On the other hand, as described above, “lamp scenario data 00” is data for executing a random blinking operation.
Accordingly, during the period when the scenario control data “No. 1” is selected and set, the lamp output data is generated based only on the “lamp scenario data 02”. As a result, it is possible to execute the red lighting operation in a state where no effect (effect) is added.
On the other hand, during the period when the “No. 2” scenario control data is selected and set, “lamp scenario data 00” and “lamp scenario data 02” are combined to generate lamp output data. The As a result, a random lighting operation can be added to the red lighting operation. That is, it is possible to add an effect that a confetti is dancing to the red lighting operation, and it is possible to make the expression of the lamp effect gorgeous.
As described above, in the lamp production based on the “ramp production scenario table 02”, the expression of the lamp production can be promoted from the plain content to the gorgeous content during the execution, and the production effect can be improved. Become.

(Operation of pachinko machine 1)
Next, the operation of the pachinko machine 1 will be described.
In the pachinko machine 1, during the execution of the first light emission control (light emission control based on the “lamp scenario data 01” or “lamp scenario data 02”), the light emission blocks L1 to L8 to be operated change in a predetermined pattern. Light emission control (light emission control based on “lamp scenario data 00”) is executed. In particular, in the second light emission control, the light emission blocks L1 to L8 to be operated are operated in a mode different from the first light emission control.
Thereby, during the operation of the plurality of light emission blocks L1 to L8 based on the first light emission control, the operation of some of the light emission blocks can be changed based on the second light emission control.
Therefore, compared with the case where only the effect operation (rainbow lighting operation or red lighting operation) based on the first light emission control is executed, the expression of the lamp effect can be gorgeous and the effect effect of the lamp effect is improved. It becomes possible to do.

In particular, in the pachinko machine 1, control data for executing the first light emission control (rainbow lighting operation or red lighting operation) and control data for executing the second light emission control (random flashing operation) are individually provided. Is provided.
Accordingly, it is possible to execute an effect operation based on only one light emission control and an effect operation based on both light emission controls of the first light emission control and the second light emission control.
In particular, when generating lamp output data by combining multiple lamp control data, execute control data for executing random flashing operation, control data for executing rainbow lighting operation, and red lighting operation Can be diverted to both of the control data.
Therefore, it is possible to diversify lamp effects while suppressing an increase in the amount of control data.

(Modification 1)
As mentioned above, although embodiment of this invention was described, in the said embodiment, a various change is possible.
For example, in the above embodiment, the rainbow lighting operation and the random flashing operation are executed based on the individual control data.
However, a configuration may be adopted in which both the rainbow-colored lighting operation and the random flashing operation are executed based on one control data.
Similarly, in the above-described embodiment, a red lighting operation and a random blinking operation are executed based on individual control data.
However, a configuration in which both the red lighting operation and the random flashing operation are executed based on one control data may be used.

(Modification 2)
Moreover, in the said embodiment, the panel lamp 21 is comprised including eight light emission blocks L1-L8.
However, the number of light-emitting blocks constituting the panel lamp 21 can be changed as appropriate.
At this time, as the number of light-emitting blocks constituting the panel lamp 21 is increased, it is possible to execute a lamp effect with a precise expression.
Moreover, in the said embodiment, full color LED is used as each light emitting element L contained in each light emission block L1-L8.
However, monochromatic LEDs may be used as the light emitting elements L included in the light emitting blocks L1 to L8.

(Modification 3)
In the above embodiment, “lamp scenario data 01” and “lamp scenario data 02” are exemplified as basic lamp scenario data, and “lamp scenario data 00” is exemplified as additional lamp scenario data.
However, lamp scenario data with various contents (operations) can be defined as basic lamp scenario data.
Further, lamp scenario data having various contents (operations) can be defined as additional lamp scenario data.
As the number of basic lamp scenario data increases and as the number of additional lamp scenario data increases, the combination of basic lamp scenario data and additional lamp scenario data increases, and the expression pattern of the lamp effect increases. Is possible.

(Modification 4)
In the above embodiment, the present invention is applied to the control of the panel lamp 21.
However, the present invention can be applied to control of all lamps such as the frame lamp 20 and the button lamp.

DESCRIPTION OF SYMBOLS 1 Pachinko machine 16 Panel illumination board 16a LED driver 21 Panel lamp 200 Main control circuit 300 Production control circuit L Light emitting element L1-L8 Light emitting block

Claims (4)

A plurality of light emitting blocks;
Control means for controlling the operation of each light-emitting block,
During the execution of the first light emission control for operating the plurality of light emission blocks in a predetermined manner, the second light emission control in which the light emission block to be operated among the plurality of light emission blocks is changed in a predetermined pattern is executed.
The second light emission control causes the light emission block to be operated to operate in a mode different from the first light emission control. Based on the individual control data, the first light emission control and the second light emission control are executed,
The gaming machine according to claim 1, wherein the second light emission control is executed with priority over the first light emission control.   3. The gaming machine according to claim 1, wherein in the second light emission control, the light emission block to be operated is operated in the second mode after being operated in the first mode. One aspect of the first aspect and the second aspect is an aspect in which the light emitting block to be operated is turned on, and the other aspect is an aspect in which the light emitting block to be operated is turned off. The gaming machine according to claim 3.

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