JP6940659B2 - Pachinko machine - Google Patents

Description

The present invention relates to a game machine such as a pachinko machine, an arrange ball machine, a sparrow ball game machine, and a slot machine. More specifically, a game capable of reducing noise and thus reducing the possibility that a display device is not displayed normally. Regarding the machine.

As a game machine such as a conventional pachinko machine, for example, a game machine as described in Patent Document 1 is known. This gaming machine is provided with a plurality of winning openings, and the winning balls are awarded according to the entry of the gaming ball into the winning openings.

Japanese Unexamined Patent Publication No. 2015-066268

By the way, in recent years, there has been an increasing demand for confirming a set value when the probability of generating a special gaming state advantageous to a player can be selectively set from a plurality of stages.

However, the above-mentioned gaming machines have a problem that the set value cannot be confirmed. Therefore, it is conceivable to provide a display device on the substrate capable of confirming such a set value. However, if the display device is simply provided on the substrate, noise is generated, and there is a problem that the display device may not be displayed normally.

Therefore, in view of the above problems, it is an object of the present invention to provide a gaming machine capable of reducing noise and thus reducing the possibility that the display device is not displayed normally.

The above object of the present invention is achieved by the following means. In addition, although the reference numerals of the embodiments described later are added in parentheses, the present invention is not limited thereto.

According to the gaming machine according to the invention of claim 1, a control CPU that controls the gaming operation (for example, the one-chip microprocessor 600 shown in FIG. 7) and
A display means (for example, the setting display device 620 shown in FIG. 7) for displaying a set value for the probability of generating a special gaming state advantageous to the player, and
A display control means (for example, the LED driver 621a shown in FIG. 7) for displaying the display means (for example, the setting display device 620 shown in FIG. 7) and a display means (for example, the LED driver 621a shown in FIG. 7).
Solenoid driving means (for example, solenoid drive drivers Q1 to Q4 shown in FIG. 7) for driving a solenoid (for example, the ordinary electric accessory solenoid 45c shown in FIG. 6 and the special electric accessory solenoid 46b shown in FIG. 6).
Electrically between the solenoid (for example, the ordinary electric accessory solenoid 45c shown in FIG. 6 and the special electric accessory solenoid 46b shown in FIG. 6) and the solenoid driving means (for example, the solenoid drive drivers Q1 to Q4 shown in FIG. 7). A connection means (for example, the connector CN7 shown in FIG. 7) for relaying a connection is provided.
The control CPU (for example, the one-chip microcomputer 600 shown in FIG. 7), the display means (for example, the setting display device 620 shown in FIG. 7), and the display control means (for example, the LED driver 621a shown in FIG. 7). And the solenoid driving means (for example, the solenoid drive drivers Q1 to Q4 shown in FIG. 7) and the connecting means (for example, the connector CN7 shown in FIG. 7) are the same substrate (for example, the main control board shown in FIG. 7). 60) As well as being placed on top
The substrate (for example, the center line O2 shown in FIG. 7) is used as a reference for the center line (for example, the center line O2 shown in FIG. 7) passing through the center point (for example, the center point O shown in FIG. 7) of the substrate (for example, the main control substrate 60 shown in FIG. 7). When the main control board 60 shown in FIG. 7 is divided into a first region and a second region, the display means (for example, the setting display device 620 shown in FIG. 7) and the display control means (for example, FIG. 7) The LED driver 621a) shown in FIG. 7 is arranged in the first region, and the solenoid driving means (for example, the solenoid driving drivers Q1 to Q4 shown in FIG. 7) and the connecting means (for example, the connector shown in FIG. 7). CN7) and is arranged in front Stories second region, further,
The distance of the wiring length for electrical connection between the control CPU (for example, the one-chip microcomputer 600 shown in FIG. 7) and the connection means (for example, the connector CN7 shown in FIG. 7) (for example, FIGS. 8 and 14). The distance L1a) is the wiring length for electrical connection between the control CPU (for example, the one-chip microcomputer 600 shown in FIG. 7) and the display means (for example, the setting display device 620 shown in FIG. 7). It is characterized in that it is arranged so as to be longer than the distance (for example, the distance L3 shown in FIGS. 8 and 12 and 13).

According to the present invention, it is possible to reduce noise and thus reduce the possibility that the display device is not displayed normally.

It is a perspective view which shows the appearance of the gaming machine which concerns on one Embodiment of this invention. It is a front side perspective view which shows the state which opened the door of the game machine before mounting the game board which concerns on this embodiment. It is a front view which shows the state which opened the door of the game machine before mounting the game board which concerns on the same embodiment. It is a perspective view of the back side which shows the appearance of the gaming machine which concerns on this embodiment. It is a front view of the game board which concerns on the same embodiment. It is a block diagram which shows the control device of the gaming machine which concerns on this embodiment. It is a component layout drawing of the main control board which concerns on the same embodiment. It is a circuit diagram around the one-chip microprocessor mounted on the main control board which concerns on the same embodiment. It is a circuit diagram around the measurement display device mounted on the main control board which concerns on the same embodiment. It is a circuit diagram around the disconnection / short circuit monitoring driver mounted on the main control board which concerns on the same embodiment. It is a circuit diagram around the buffer which generates the data signal which is input and received into the one-chip microprocessor mounted on the main control board which concerns on this embodiment. It is a circuit diagram around the LED driver which drives the setting display device mounted on the main control board which concerns on this embodiment. It is a circuit diagram around the setting display device mounted on the main control board which concerns on the same embodiment. It is a circuit diagram around the solenoid drive driver mounted on the main control board which concerns on the same embodiment. It is a partial vertical sectional view which shows the state of the measurement display device and the setting display device mounted on the main control board which concerns on the same embodiment. It is explanatory drawing which shows the memory area of the main control RAM which concerns on this embodiment. It is a flowchart explaining the main process of the main control which concerns on this embodiment. It is a flowchart explaining the timer interrupt processing of the main control which concerns on the same embodiment. It is a flowchart explaining the switch input process shown in FIG. It is a flowchart explaining the winning invalidation processing shown in FIG. It is a flowchart explaining the prize ball management process shown in FIG. It is a flowchart explaining the setting confirmation process shown in FIG. It is a flowchart explaining the prize ball prize number management process shown in FIG. It is a flowchart explaining the initial setting process of the measurement RAM area shown in FIG. 23. It is a flowchart explaining the counting process shown in FIG. It is a flowchart explaining the display process shown in FIG. It is a flowchart explaining the common setting and 7-segment output processing. It is a flowchart explaining the setting process for a measurement display device. It is a flowchart explaining the output process for a measurement display device.

Hereinafter, an embodiment of the gaming machine according to the present invention will be specifically described with reference to the drawings, taking a pachinko gaming machine as an example. In the following description, when the directions of up, down, left, and right are shown, it means the up, down, left, and right when viewed from the front of the illustration.

<Explanation of the appearance configuration of pachinko game machines>
First, the appearance configuration of the pachinko gaming machine according to the present embodiment will be described with reference to FIGS. 1 to 5.

<Explanation of the appearance configuration of the front of the pachinko machine>
As shown in FIG. 1, the pachinko gaming machine 1 has a wooden outer frame 2 and a hinge 4a (see FIG. 2) provided on the left side of the front surface of the outer frame 2 so as to be around the vertical axis. It is provided with a rectangular front frame 3 that is pivotally attached so as to be openable and closable and detachable.

As shown in FIGS. 2 and 3, the front frame 3 includes an upper mounting portion 5 and a lower mounting portion 6 provided below the upper mounting portion 5. On the front side of the upper mounting portion 5, an upper opening / closing door 7 supporting transparent glass pivotally attached around the center of the vertical axis via the hinge 4a is provided, and the front side of the lower mounting portion 6 is provided. The lower opening / closing door 8 is pivotally attached to the lower opening / closing door 8 by a hinge 4b provided on the same side as the hinge 4a so as to be openable / closable and detachable.

Then, as shown in FIG. 1, the lower opening / closing door 8 has an upper tray 9 for storing the discharged game balls and a lower tray 9 for receiving and storing the surplus balls when the upper tray 9 is full. The saucer 10 is integrally formed. Further, the lower opening / closing door 8 is provided with a ball lending button 11 and a prepaid card ejection button 12 (card return button 12), and a built-in lamp (not shown) is lit on the upper plate surface portion of the upper tray 9. A push-button type effect button device 13 that can change the effect by pressing the button occasionally is provided. Further, the upper saucer 9 is provided with a ball removal button 14 for pulling out the game ball stored in the upper saucer 9 downward, and further, a setting button 15 composed of a substantially cross key is provided. The setting button 15 can be operated by the player, and includes a circular decision key 15a provided at the center, a triangular upper key 15b provided on the upper side of the decision key 15a in the drawing, and a decision thereof. The triangular left key 15c provided on the left side of the key 15a, the triangular right key 15d provided on the right side of the decision key 15a, and the triangular shape provided on the lower side of the decision key 15a. It is composed of a lower key 15e.

On the other hand, on the right end side of the lower opening / closing door 8, as shown in FIG. 1, launch handles 16 for operating the launch unit are provided, and as shown in FIGS. 1 to 3, both upper sides of the front frame 3 are provided. A speaker 17 that emits BGM (Background music) or a sound effect is provided on the surface side and in the vicinity of the launch handle 16. Decorative lamps such as LED lamps that bring out the effect of the decoration of light are arranged at various places of the upper opening / closing door 7 and the lower opening / closing door 8.

On the other hand, as shown in FIGS. 2 and 3, the upper mounting portion 5 is provided with a game board mounting frame 18, and the game board YB (see FIG. 1) is attached to the game board mounting frame 18 in FIG. The game area 40 shown is mounted so as to face the front surface, and is fixed in the game board mounting frame 18. That is, as shown in FIG. 3, since the upper mounting portion 5 is provided with a plurality of connection connectors 19 (4 in the drawing) at the lower part on the right side surface side, the game board YB is provided on these connection connectors 19. By connecting a connector for connection (not shown) provided on the back surface of the game board, the game board YB is mounted in the game board mounting frame 18. Then, the game board YB is fixed in the game board mounting frame 18 by the fixtures 20a and 20b provided in the vertical direction on the right side surface side. As a result, the game board YB is mounted in the game board mounting frame 18, and the upper opening / closing door 7 supporting the transparent glass is provided on the front side of the game area 40 of the game board YB (see FIG. 1). ). The game area 40 is composed of an area surrounded by a ball guide rail UR (see FIG. 5) arranged on the surface of the game board YB.

On the other hand, as shown in FIGS. 2 and 3, the lower mounting portion 6 has a firing mechanism 21 arranged substantially in the center in the left-right direction, and a speaker 17 is arranged on the right side of the firing mechanism 21. As shown in FIG. 3, the launch mechanism 21 includes a support plate 22 made of sheet metal, a launch rail 23 mounted on the front surface of the support plate 22, and a game ball mounted on the front surface of the support plate 22 for launching. A ball holding portion 25 that holds the ball at the launch standby position 24 on the launch rail 23, a striking mallet 27 that is swingably supported around the drive shaft 26 in the front-rear direction on the front surface of the support plate 22, and the back side of the support plate 22. The striking mallet 27 is provided with a launch control board 71 provided with a launch motor that drives the striking mallet 27 in the striking direction via a drive shaft 26.

<Explanation of the appearance configuration of the game board>
On the other hand, in the game area 40 of the game board YB, as shown in FIG. 5, a liquid crystal display device 41 composed of an LCD (Liquid Crystal Display) or the like is arranged in a substantially central portion. The liquid crystal display device 41 divides the display area into three areas, left, middle, and right, and can independently display numbers, characters, characters (character conversation, lyric telop, etc.) or special symbols in a variable manner. Is. Around such a liquid crystal display device 41, a decorative upper decoration 42a, a left decoration 42b, and a right decoration 42c are provided, and on the back side of the upper decoration 42a, the left decoration 42b, and the right decoration 42c. A movable accessory device 43 is arranged.

As shown in FIG. 5, the movable accessory device 43 has an upper movable accessory 43a, a left movable accessory 43b, a right movable accessory 43c, and an upper left movable accessory that perform a predetermined effect operation as the game progresses. It is composed of an object 43d and a motor (not shown) such as a two-phase stepping motor that drives the upper, left, right, and upper left movable accessories 43a to 43d, respectively. Decorative lamps such as LED lamps that produce an effect by decorating the light are arranged on the upper, left, right, and upper left movable accessories 43a to 43d.

On the other hand, a special symbol 1 starting port 44 is arranged directly below the liquid crystal display device 41, and a special symbol 1 starting port switch 44a (see FIG. 6) for detecting a winning ball is provided inside the special symbol 1 starting port 44. Then, the number of effective winning balls detected by the special symbol 1 start port switch 44a (see FIG. 6), that is, the number of first start hold balls is displayed on the liquid crystal display device 41. .. The number of balls on hold for the first start is incremented by 1 (+1) when a game ball wins a special symbol 1 start port 44 and is detected by the special symbol 1 start port switch 44a (see FIG. 6). When the variable display of a special symbol such as a number, a character, or a symbol (decorative symbol) is started, 1 subtraction (-1) is performed.

On the other hand, a special symbol 2 starting port 45 is arranged on the lower right side of the liquid crystal display device 41, and a special symbol 2 starting port switch 45a (see FIG. 6) for detecting a winning ball is provided inside the special symbol 2 starting port 45. Then, the number of effective winning balls detected by the special symbol 2 start port switch 45a (see FIG. 6), that is, the number of second start hold balls is displayed on the liquid crystal display device 41. .. The number of balls on hold for the second start is incremented by 1 (+1) when the game ball wins the special symbol 2 start port 45 and is detected by the special symbol 2 start port switch 45a (see FIG. 6). When the variable display of a special symbol such as a number, a character, or a symbol (decorative symbol) is started, 1 subtraction (-1) is performed.

On the other hand, as shown in FIG. 5, the special symbol 2 starting port 45 is provided with an opening / closing member 45b, and when the opening / closing member 45b is opened, the game ball is likely to win a prize. The opening / closing member 45b is opened a predetermined number of times for a predetermined time when a lottery for a normal symbol described later is won, and the opening / closing operation is controlled by a normal electric accessory solenoid 45c (see FIG. 6). In the following, a device combining such an opening / closing member 45b and an ordinary electric accessory solenoid 45c may be referred to as an ordinary electric accessory.

On the other hand, as shown in FIG. 5, a winning device 46 is arranged on the right side of the special symbol 1 starting port 44. The winning device 46 opens and closes so that the large winning opening (not shown) closed by the opening / closing door 46a opens when the lottery of the special symbol described later is won, that is, in the special game state generated by the big hit. The door 46a is driven and controlled by the special electric accessory solenoid 46b (see FIG. 6), and the game ball can enter the large winning opening (not shown). The game ball that has entered the large winning opening (not shown) is detected as a winning ball by the large winning opening switch 46c provided inside the large winning opening (not shown).

On the other hand, when the special symbol lottery is not won, that is, when the game is not in the special game state, the opening / closing door 46a is driven and controlled by the special electric accessory solenoid 46b (see FIG. 6), and the large winning opening (not shown). Is closed. As a result, the game ball cannot enter the large winning opening (not shown). In the following, a device combining such an opening / closing door 46a and a special electric accessory solenoid 46b may be referred to as a special electric accessory.

On the other hand, as shown in FIG. 5, a normal symbol start port 47 composed of a gate is arranged in the upper right portion of the liquid crystal display device 41, and inside the normal symbol start port switch 47a (which detects the passage of a game ball). (See FIG. 6) is provided. Further, general winning openings 48 are arranged on the right side of the winning device 46 and on the left side of the special symbol 1 starting port 44, respectively. The general winning opening 48 is the upper right general winning opening 48a arranged on the right side of the winning device 46, the upper left general winning opening 48b arranged on the left side of the special symbol 1 starting opening 44, and the left middle general winning opening 48b. It is composed of a mouth 48c and a lower left general winning mouth 48d. The upper right general winning opening switch 48a1 (see FIG. 6) for detecting the passage of the game ball is provided inside the upper right general winning opening 48a, and the upper left for detecting the passage of the game ball inside the upper left general winning opening 48b. A general winning opening switch 48b1 (see FIG. 6) is provided, and inside the left middle general winning opening 48c, a left middle general winning opening switch 48c1 (see FIG. 6) for detecting the passage of a game ball is provided, and a lower left general winning opening switch 48c1 is provided. Inside the mouth 48d, a lower left general winning opening switch 48d1 (see FIG. 6) for detecting the passage of a game ball is provided.

On the other hand, directly below the special symbol 1 starting port 44, an out port 49 is arranged in which a game ball (out ball) that has flowed down to the most downstream portion of the game area 40 without winning a prize is inserted. The game ball that has entered the out port 49 is detected by the out port switch 49a (see FIG. 6) provided inside as a non-winning ball, and the above-mentioned winning ball also presses the back side of the game board 4. Since it flows down to the most downstream part through the passage, it is detected by the out port switch 49a (see FIG. 6). Therefore, the out port switch 49a (see FIG. 6) detects the total number of discharged outs, that is, the same number of game balls as the game balls launched into the game area 40 by the launch handle 16.

On the other hand, three 7 segments are arranged side by side in the lower right peripheral portion of the game area 40 of the game board 4, of which two 7 segments are special symbol display devices 50 and the other 7 segments are special. The number of start-holding balls of symbol 1 and special symbol 2 is displayed. As shown in FIG. 5, the special symbol display device 50 is composed of a special symbol 1 display device 50a and a special symbol 2 display device 50b, and two special symbol 1 display devices 50a are on the left side of the special symbol 1 display device 50a. An ordinary symbol display device 51 composed of LEDs is provided. Although not shown, a plurality of game nails are arranged in the game area 40 of the game board 4, and a windmill 52 as a falling direction changing member of the game ball is arranged.

<Explanation of the appearance configuration on the back of the pachinko machine>
Thus, as shown in FIG. 4, a frame-shaped back mechanism plate 53 that covers the game board mounting frame 18 and presses the game board YB from the back side is attached to the back surface of the pachinko game machine 1 configured in this way. There is. A game ball storage tank 54 for storing game balls supplied from a game ball replenishment device (not shown) of the pachinko hall side island facility is provided on the upper right side of the back mechanism plate 53, and further. A tank rail 55 for drawing out a ball from the game ball storage tank 54 is provided.

A payout device 56 and a payout passage 57 are attached to the lower end of the inclination of the tank rail 55, and when a game ball wins a prize opening such as a large winning opening (not shown), or a game ball lending device. When there is a ball lending command from (not shown), the game balls in the game ball storage tank 54 are paid out by the payout device 56 via the tank rail 55, and the game balls are paid out through the payout passage 57 to the upper tray 9 (not shown). (See Fig. 1).

Further, a transparent back cover 58 (see also FIG. 3) detachably attached to the back side of the game board YB is mounted in the substantially center of the back mechanism plate 53, and the effect is produced in the back cover 58. A transparent effect control board case 90a containing the control board 90 and a transparent liquid crystal board case 120a containing the liquid crystal control board 120 are detachably provided. A transparent main control board case 60a containing the main control board 60 is detachably provided below the effect control board case 90a, and the payout control board 70 is below the main control board case 60a. A transparent payout control board case 70a containing the above is detachably provided. Further, below the main control board case 60a, a power supply board case 130a containing the power supply board 130 is detachably provided.

<Explanation of control device>
Next, a control device provided in the pachinko gaming machine 1 having the above-mentioned appearance configuration and performing electronic control according to the progress of the game will be described with reference to FIG. As shown in FIG. 6, this control device includes a main control board 60 that controls overall game operations, a payout control board 70 that pays out game balls based on control commands from the main control board 60, and an image. It is mainly composed of a sub control board 80 that controls light and sound. As shown in FIG. 6, the sub-control board 80 is composed of an effect control board 90, a decorative lamp board 100, and a liquid crystal control board 120.

<Explanation of main control board>
The main control board 60 is a one-chip microcomputer composed of a main control CPU 600a, a main control ROM 600b that stores a game program or the like that describes a series of game control procedures, and a main control RAM 600c that functions as a work area, a buffer memory, or the like. A computer 600, a measurement display device 610 consisting of 7 segments that display the content related to the ratio of how many prize balls were won at the time of low probability (the winning lottery probability is a normal low probability state), and a special game advantageous to the player. It is mainly equipped with a setting display device 620 composed of 7 segments that displays the setting contents of the probability of generating a state.

A payout control board 70 that controls the payout motor M to pay out the game ball is connected to the main control board 60 configured in this way. Further, a special symbol 1 start port switch 44a for detecting a prize in the special symbol 1 start port 44, a special symbol 2 start port switch 45a for detecting a prize in the special symbol 2 start port 45, and a normal symbol start port 45a. The normal symbol start port switch 47a that detects the passage of 47 and the general winning opening 48 (upper right general winning opening 48a, upper left general winning opening 48b, left middle general winning opening 48c, lower left general winning opening 48d) are detected. Upper right general winning opening switch 48a1, upper left general winning opening switch 48b1, left middle general winning opening switch 48c1, lower left general winning opening switch 48d1, and large winning opening (not shown) opened or closed by the opening / closing door 46a. The large winning opening switch 46c to be detected and the out opening switch 49a capable of detecting the same number of game balls as the game balls launched into the game area 40 by the launch handle 16 are connected. Furthermore, a normal electric accessory solenoid 45c that controls the operation of the opening / closing member 45b, a special electric accessory solenoid 46b that controls the operation of the opening / closing door 46a, a special symbol 1 display device 50a, and a special symbol 2 display device 50b. And the normal symbol display device 51 are connected.

When the main control board 60 configured in this way receives a signal from the special symbol 1 start port switch 44a, the special symbol 2 start port switch 45a, or the normal symbol start port switch 47a by the main control CPU 600a, it is advantageous for the player. A lottery is performed to determine whether to generate a special gaming state (so-called "hit") or not to generate a special gaming state advantageous to the player (so-called "loss"), and depending on the winning / failing information which is the result of the lottery. The variation pattern of the special symbol, the stop symbol, or the display content of the normal symbol is determined, and the determined information is transmitted to the special symbol 1 display device 50a, the special symbol 2 display device 50b, or the normal symbol display device 51. As a result, the lottery result is displayed on the special symbol 1 display device 50a, the special symbol 2 display device 50b, or the ordinary symbol display device 51. Further, the main control board 60, that is, the main control CPU 600a, generates an effect control command DI_CMD containing the determined information and transmits it to the effect control board 90. The main control board 60, that is, the main control CPU 600a, has a special symbol 1 start port switch 44a, a special symbol 2 start port switch 45a, an upper right general winning opening switch 48a1, an upper left general winning opening switch 48b1, and a left middle general winning opening switch. When a signal is received from 48c1, the lower left general winning opening switch 48d1, and the large winning opening switch 46c, it is decided how much game ball to be paid out to the player, and the payout control command PAY_CMD including the decided information is paid out. By transmitting to the control board 70, the payout control board 70 pays out the game ball to the player.

Further, as a result of the lottery, when the lottery of the ordinary symbol is won, the normal electric accessory solenoid 45c is driven and controlled so that the opening / closing member 45b is opened a predetermined number of times for a predetermined time, and when the lottery of the special symbol is won. The special electric accessory solenoid 46b is controlled to open the large winning opening (not shown).

On the other hand, the main control board 60, that is, the main control CPU 600a, has a special symbol 1 start port switch 44a, a special symbol 2 start port switch 45a, an upper right general winning opening switch 48a1, an upper left general winning opening switch 48b1, and a left middle general winning opening switch. The number of prize balls is measured each time a signal is received from 48c1, the lower left general winning opening switch 48d1, and the large winning opening switch 46c, and the total number of game balls discharged each time a signal from the out opening switch 49a is received. To measure. Then, the main control board 60, that is, the main control CPU 600a, measures and displays the content related to the ratio of how many prize balls were awarded at the time of low accuracy based on the measured number of prize balls and the total number of discharged game balls. Output to. As a result, the measurement display device 610 displays the content related to the ratio of how many prize balls were awarded at the time of low accuracy.

<Explanation of payout control board>
On the other hand, the payout control board 70 receives the payout control command PAY_CMD from the main control board 60 (main control CPU 600a), and generates a payout motor signal based on the received payout control command PAY_CMD. Then, the payout motor M is controlled by the generated payout motor signal, and the game ball is paid out to the player. Further, the payout control board 70 transmits a prize ball counting signal indicating the payout operation of the game ball and a status signal related to an abnormality in the payout operation, and launches the game ball in response to the player's operation. Performs a process of transmitting a launch control signal for starting or stopping the operation of.

<Explanation of production control board>
The effect control board 90 stores an effect control CPU 900 that receives the effect control command DI_CMD from the main control board 60 (main control CPU 600a) to execute and control various effects, a control program that describes the effect control procedure, and the like. It is composed of an effect control ROM 910 composed of a flash memory and an effect control RAM 920 that functions as a work area, a buffer memory, and the like. Further, the effect control board 90 is equipped with a sound LSI 930 that generates a desired BGM and sound effects, and a sound ROM 940 that stores sound data such as BGM and sound effects in advance.

A decorative lamp board 100 on which a decorative lamp such as an LED lamp that exhibits a lamp effect effect is mounted is connected to the effect control board 90 configured in this way, and a built-in lamp (not shown) is further connected. ) A push-button type effect button device 13 that can change the effect by pressing the player when the lamp is lit is connected, and a speaker 17 that emits a BGM, a sound effect, or the like is connected. Further, a movable accessory device 43 that performs a predetermined effect operation as the game progresses is connected to the effect control board 90, and a setting button 15 capable of various settings is connected to the liquid crystal display device 41 to control the liquid crystal display device 41. The control board 120 is connected. Needless to say, the decorative lamp substrate 100 is also equipped with decorative lamps arranged on the upper, left, right, and upper left movable accessories 43a to 43d.

Thus, the effect control board 90 configured in this way has a special symbol variation pattern based on the jackpot lottery result (whether jackpot or loss) transmitted from the main control board 60 (main control CPU 600a), the current gaming state, and the first The effect control CPU 900 receives the effect control command DI_CMD containing the basic information required for the number of balls held for one start, the number of balls reserved for second start, the decorative symbol to be stopped based on the lottery result, and the like. Then, the effect control CPU 900 determines the effect pattern corresponding to the received effect control command DI_CMD by lottery from a large number of effect patterns stored in advance in the effect control ROM 910, and executes the determined effect pattern. The instruction control signal is temporarily stored in the effect control RAM 920.

Then, the effect control CPU 900 transmits a control signal related to sound among the control signals for instructing execution of the effect pattern stored in the effect control RAM 920 to the sound LSI 930. In response to this, the sound LSI 930 reads the sound data corresponding to the control signal from the sound ROM 940 and outputs it to the speaker 17. As a result, the BGM and sound effects corresponding to the above-determined effect pattern are emitted from the speaker 17.

Further, the effect control CPU 900 transmits a control signal related to light among the control signals for instructing the execution of the effect pattern stored in the effect control RAM 920 to the decorative lamp substrate 100. As a result, the decorative lamp substrate 100 controls to turn on or off the decorative lamp such as the LED lamp that produces the lamp effect effect, so that the lamp effect corresponding to the determined effect pattern is executed. ..

Further, the effect control CPU 900 transmits the liquid crystal control command LCD_CMD related to the image to the liquid crystal control board 120 among the control signals for instructing the execution of the effect pattern stored in the effect control RAM 920. As a result, the liquid crystal control board 120 controls the liquid crystal display device 41 so as to display an image based on the liquid crystal control command LCD_CMD, so that an image corresponding to the above-determined effect pattern is displayed on the liquid crystal display device 41. The Rukoto. The liquid crystal control board 120 stores various image data for displaying an image according to the effect content, and is further equipped with a VDP (Video Display Processor) that controls the overall effect output.

Further, the effect control CPU 900 transmits the control signal related to the movable accessory among the control signals for instructing the execution of the effect pattern stored in the effect control RAM 920 to the movable accessory device 43. As a result, the movable accessory device 43 is movable in accordance with the above-determined effect pattern.

By the way, the power supply to each of the above-described boards is supplied from the power supply board 130 shown in FIG. The power supply board 130 includes a voltage generation unit 1300, a voltage monitoring unit 1310, and a system reset generation unit 1320. The voltage generation unit 1300 receives an AC voltage AC24V, which is an external power supply supplied from a transformer (not shown) installed in a game store, and generates a plurality of types of DC voltage. Although not shown, it is supplied to each substrate.

Further, the voltage monitoring unit 1310 monitors the voltage of the AC voltage AC24V, and when this voltage is interrupted or a power failure occurs and a voltage abnormality is detected, the voltage abnormality signal ALARM is sent to the main control board 60. It is output to. The voltage abnormality signal ALARM outputs an "L" level signal when the voltage is abnormal, and outputs an "H" level signal when the voltage is normal.

On the other hand, the system reset generation unit 1320 generates a system reset signal when the power is turned on, and the generated system reset signal is output to each board although not shown.

<Specific explanation of the main control board>
Here, since the feature of the present invention relates to the main control substrate, this point will be specifically described with reference to FIGS. 7 to 15.

As shown in FIG. 7, the main control board 60 mainly includes a one-chip microprocessor 600, a measurement display device 610, and a setting display device 620.

<Explanation of wiring for one-chip microcomputer>
The wiring contents of the one-chip microcomputer 600 will be specifically described with reference to FIG. 8. In the one-chip microcomputer 600, as shown in FIG. 8, the voltage generation unit 1300 of the power supply board 130 (see FIG. 6) The DC5V voltage 601a generated in (see FIG. 6) is input, and the ground 601b is input. A capacitor C20 (see FIG. 7) is connected between the wiring pattern of the DC5V voltage 601a and the wiring pattern of the ground 601b.

Further, as shown in FIG. 8, the one-chip microcomputer 600 is input with the backup voltage 601c generated by the voltage generation unit 1300 (see FIG. 6) of the power supply board 130 (see FIG. 6). A capacitor C22 (see FIG. 7) is connected between the wiring pattern of the backup voltage 601c and the wiring pattern of the ground 601d.

On the other hand, as shown in FIG. 8, the one-chip microcomputer 600 is input with the voltage abnormality signal ALARM generated by the voltage monitoring unit 1310 (see FIG. 6), and further, the system reset generation unit 1320 (FIG. 6). The system reset signal RST generated in (see) is input. A pull-up resistor R33 (see FIG. 7) is connected to the wiring pattern of the voltage abnormality signal ALARM, and a pull-up resistor R34 (see FIG. 7) is connected to the wiring pattern of the system reset signal RST. ..

On the other hand, as shown in FIG. 8, the output unit of the one-chip microcomputer 600 outputs the internally generated clock signal 601e, and the direction in which the clock signal 601e is output (left direction in the drawing). An 8-bit data signal 601f is input / output from a direction opposite to that of the above (opposite direction (right direction in the drawing)).

Thus, by outputting the clock signal 601e output from the one-chip microcomputer 600 and the 8-bit data signal 601f output from the one-chip microcomputer 600 from opposite directions (opposite directions). It is possible to reduce the situation where the noise due to the clock signal 601e output from the one-chip microcomputer 600 affects the 8-bit data signal 601f output from the one-chip microcomputer 600. Therefore, as will be described later, it is possible to reduce the influence of noise on the 8-bit data signal 601f related to the display contents of the measurement display device 610 and the setting display device 620, and thus the measurement display device 610 and the setting display device. It is possible to reduce the possibility that the display content of 620 is not displayed normally.

On the other hand, as shown in FIG. 8, the switch signal 601h from the special symbol 1 start port switch 44a (see FIG. 6) and the special symbol 2 start port switch 45a (see FIG. 6) is input to the one-chip microcomputer 600. Has been done. In the figure, three signal lines can be input, but in the present embodiment, only two signal lines are used.

On the other hand, as shown in FIG. 8, the clock signal generated by the clock generation unit 601i is input to the one-chip microcomputer 600, and a plurality of chips (15 in the figure) are selected from the one-chip microcomputer 600. The signal 601j is output. A capacitor C30 (see also FIG. 7) is provided between the voltage wiring pattern input to the clock generation unit 601i and the ground wiring pattern, and among the plurality of chip select signals 601j. A pull-up resistor RA2 (see also FIG. 7) is connected to the 1st to 7th chip select signals 601j shown in the drawing, and a pull-up resistor RA3 (see also FIG. 7) is connected to the 8th to 10th chip select signals 601j shown in the drawing. (See also FIG. 7) is connected.

<Explanation of wiring related to measurement display device>
By the way, the 8-bit data signal 601f output from the one-chip microcomputer 600 is output to the measurement display device 610 side. This point will be specifically described with reference to FIG. The 8-bit data signal 601f output from the one-chip microcomputer 600 is also output as an 8-bit data signal 601k. This is a signal for transmitting the effect control command DI_CMD to the effect control board 90.

As shown in FIG. 9, the measurement display device 610 is connected to the signals output from the LED drivers 611a to 611c. The LED drivers 611a to 611c select which 7 segments of the special symbol display device 50 composed of 2 7 segments and the measurement display device 610 composed of 4 7 segments are to be turned on. , The signal is output. More specifically, the LED driver 611a receives the 8-bit data signal 601f output from the one-chip microcomputer 600 shown in FIG. 8 as the 8-bit data signal 611a1 and dynamically lights the 4-bit LED for the special symbol display device. The common data signal 611a2 is output to the special symbol display device 50, and the 4-bit LED dynamic lighting common data signal 611a3 for the measurement display device is output to the measurement display device 610. That is, the LED dynamic lighting common data signal 611a2 for the special symbol display device output from the LED driver 611a selects 7 segments that receive the LED dynamic lighting data signal 611b2 for the special symbol display device output from the LED driver 611b described later. Common data for. The 4-bit LED dynamic lighting common data signal 611a2 for the special symbol display device is a 1-bit first LED dynamic lighting common data signal 611a2a for the special symbol display device and a 1-bit LED for the second special symbol display device. It is composed of a dynamic lighting common data signal 611a2b, a 1-bit LED dynamic lighting common data signal 611a2c for a third special symbol display device, and a 1-bit LED dynamic lighting common data signal 611a2d for a fourth special symbol display device. Has been done.

Further, the LED dynamic lighting common data signal 611a3 for the measurement display device output from the LED driver 611a is for selecting seven segments that receive the LED dynamic lighting data signal 611c2 for the measurement display device output from the LED driver 611c described later. It is common data. The 4-bit LED dynamic lighting common data signal 611a3 for the measurement display device is the 1-bit LED dynamic lighting common data signal 611a3a for the first measurement display device and the 1-bit LED dynamic lighting common for the second measurement display device. It is composed of a data signal 611a3b, a 1-bit LED dynamic lighting common data signal 611a3c for a third measurement display device, and a 1-bit LED dynamic lighting common data signal 611a3d for a fourth measurement display device. The LED dynamic lighting common data signal 611a3a for the measurement display device 1 is output to the first measurement display device 610A located on the right side of the measurement display device 610, and the LED dynamic lighting common data signal for the second measurement display device is output. 611a3b is output to the second measurement display device 610B located on the left side of the drawing of the first measurement display device 610A among the measurement display devices 610, and the LED dynamic lighting common data signal 611a3c for the third measurement display device is the measurement display. Of the devices 610, the third measurement display device 610C located on the left side of the second measurement display device 610B is output, and the LED dynamic lighting common data signal 611a3d for the fourth measurement display device is the measurement display device 610. , It is output to the fourth measurement display device 610D located on the left side of the drawing of the third measurement display device 610C.

Thus, in the measurement display device 610 to which the common data is connected in this way, the LED dynamic lighting common data signal 611a3a for the first measurement display device ⇒ the second measurement display is performed for each timer interrupt process shown in FIG. LED dynamic lighting for device Common data signal 611a3b ⇒ LED dynamic lighting for third measurement display device Common data signal 611a3c ⇒ LED dynamic lighting for fourth measurement display device Common data signal 611a3d ⇒ LED dynamic lighting for first measurement display device The signals are output in the order of the common data signal 611a3a ⇒ ..., Therefore, the first measurement display device 610A ⇒ the second measurement display device 610B ⇒ the third measurement display device 610C ⇒ the fourth measurement display device 610D ⇒ The first measurement display device 610A ⇒ ... Will be lit and displayed in this order. As shown in FIG. 9, the LED driver 611a is input with the fifth chip select signal 611a4 from the top of the drawing among the plurality of chip select signals 601j shown in FIG. 8, and the system reset generation unit 1320 (FIG. 9). The system reset signal RST generated in 6) is input. Further, a capacitor C45 (see also FIG. 7) is provided between the wiring pattern of the voltage input to the LED driver 611a and the wiring pattern of the ground.

On the other hand, the LED driver 611b receives the 8-bit data signal 601f output from the one-chip microcomputer 600 shown in FIG. 8 as the 8-bit data signal 611b1, and receives the LED dynamic lighting data signal 611b2 for the special symbol display device as the special symbol. It is output to the display device 50. As a result, the lottery result is displayed on the special symbol display device 50. As shown in FIG. 9, damping resistors R53 to R46 (see also FIG. 7) are connected to the special figure display data signal 611b2, and the LED driver 611b is shown in FIG. 8 as shown in FIG. Of the plurality of chip select signals 601j, the sixth chip select signal 611b3 from the top of the drawing is input, and the system reset signal RST generated by the system reset generation unit 1320 (see FIG. 6) is input. Further, a capacitor C40 (see also FIG. 7) is provided between the wiring pattern of the voltage input to the LED driver 611b and the wiring pattern of the ground.

On the other hand, the LED driver 611c receives the 8-bit data signal 601f output from the one-chip microcomputer 600 shown in FIG. 8 as the 8-bit data signal 611c1, and the 8-bit LED dynamic lighting data signal 611c2 for the measurement display device. Is output to the measurement display device 610. As a result, the measurement display device 610 displays the content related to the ratio of how many prize balls were awarded at the time of low accuracy. At this time, the 8-bit LED dynamic lighting data signal 611c2 for the measurement display device is output to the measurement display device 610 slightly later than the LED dynamic lighting common data signal 611a3 for the measurement display device. Then, by outputting the 8-bit LED dynamic lighting data signal 611c2 for the measurement display device to the measurement display device 610, the first LED dynamic lighting common data for the measurement display device is output for each timer interrupt process shown in FIG. Signal 611a3a ⇒ LED dynamic lighting common data signal for the second measurement display device 611a3b ⇒ LED dynamic lighting common data signal for the third measurement display device 611a3c ⇒ LED dynamic lighting common data signal for the fourth measurement display device 611a3d ⇒ 1st LED dynamic lighting for measurement display device Common data signal 611a3a ⇒ ... Signals are output in this order, so that the first measurement display device 610A ⇒ second measurement display device 610B ⇒ third measurement display device 610C ⇒ In the order of the fourth measurement display device 610D ⇒ first measurement display device 610A ⇒ ..., The contents related to the ratio of how many prize balls were awarded at the time of low accuracy are displayed. As shown in FIG. 9, damping resistors R3 to R10 (see also FIG. 7) are connected to the measurement display data signal 611c2, and a plurality of damping resistors R3 to R10 (see also FIG. 7) are connected to the LED driver 611c as shown in FIG. Of the chip select signals 601j of the above, the seventh chip select signal 611c3 from the top of the figure is input, and the system reset signal RST generated by the system reset generation unit 1320 (see FIG. 6) is input. Further, a capacitor C2 (see also FIG. 7) is provided between the wiring pattern of the voltage input to the LED driver 611c and the wiring pattern of the ground.

<Explanation of signals related to measurement display device>
Next, the wiring contents of the signal necessary for calculating the ratio of how many prize balls were won at the time of low accuracy displayed on the measurement display device 610 will be specifically described with reference to FIGS. 10 and 11. .. As shown in FIG. 10, any one of the upper right general winning opening switch 48a1, the upper left general winning opening switch 48b1, the left middle general winning opening switch 48c1, the lower left general winning opening switch 48d1, and the data signal 612a1 relating to the out opening switch 49a is the connector CN8. It is input to the disconnection / short circuit monitoring driver 612a via. Then, as shown in FIG. 10, a data signal 612a2 relating to the special symbol 1 start port switch 44a is also input to the disconnection / short circuit monitoring driver 612a via the connector CN4 (see also FIG. 7).

Thus, the disconnection / short circuit monitoring driver 612a to which such data signals 612a1 and 612a2 are input determines that the voltage level of these data signals 612a1 and 612a2 is normal unless the voltage level is equal to or higher than the predetermined voltage or lower than the predetermined voltage. Then, the data signals 612a3 related to the input data signals 612a1 and 612a2 are output, and if any of these data signals 612a1 and 612a2 has a voltage level of a predetermined voltage or more or a predetermined voltage or less, it is abnormal. It determines that there is, and outputs an error signal 612a4. Pull-up resistors R65, R63, R61, R59, R74, R75, and R76 (see also FIG. 7) are connected to the data signals 612a1 and 612a2, and the voltage input to the disconnection / short-circuit monitoring driver 612a. Capacitors C17 and C18 (see also FIG. 7) are provided between the wiring pattern of the above and the wiring pattern of the ground. Further, pull-up resistors R39 and RA6 (see also FIG. 7) are connected to the data signals 612a3 and error signals 612a4 output from the disconnection / short-circuit monitoring driver 612a.

Thus, in this way, any one of the upper right general winning opening switch 48a1, the upper left general winning opening switch 48b1, the left middle general winning opening switch 48c1, the lower left general winning opening switch 48d1 and the out opening switch 49a are monitored for the same disconnection / short circuit. By using the wiring to be input to the driver 612a, the circuit configuration can be simplified, and further, it becomes easy to find an error due to a disconnection or a short circuit. In this embodiment, any one of the upper right general winning opening switch 48a1, the upper left general winning opening switch 48b1, the left middle general winning opening switch 48c1, and the lower left general winning opening switch 48d1 is input to the disconnection / short circuit monitoring driver 612a. Of course, all signals may be input to the disconnection / short circuit monitoring driver 612a. However, if all the signals are input to the disconnection / short-circuit monitoring driver 612a, it becomes difficult to immediately determine which switch has an error. It is preferable to connect to the driver 612b.

That is, as shown in FIG. 10, a data signal 612b1 relating to any one of the upper right general winning opening switch 48a1, the upper left general winning opening switch 48b1, the left middle general winning opening switch 48c1, and the lower left general winning opening switch 48d1 is transmitted via the connector CN8. It is input to the disconnection / short circuit monitoring driver 612b. Then, as shown in FIG. 10, a data signal 612b2 relating to the special symbol 2 start port switch 45a is also input to the disconnection / short circuit monitoring driver 612b via the connector CN5 (see also FIG. 7).

Thus, the disconnection / short circuit monitoring driver 612b to which such data signals 612b1 and 612b2 are input determines that the voltage level of these data signals 612b1 and 612b2 is normal unless the voltage level is equal to or higher than the predetermined voltage or lower than the predetermined voltage. Then, the data signals 612b3 related to the input data signals 612b1 and 612b2 are output, and if any of these data signals 612b1 and 612b2 has a voltage level of a predetermined voltage or more or a predetermined voltage or less, it is abnormal. It is determined that the error signal 612b4 is output. The pull-up resistors R64, R62, R60, R58, R57, R56, R55, and R54 (see also FIG. 7) are connected to the data signals 612b1 and 612b2, and are input to the disconnection / short-circuit monitoring driver 612b. Capacitors C38 and C39 (see also FIG. 7) are provided between the wiring pattern of the current voltage and the wiring pattern of the ground. Further, a pull-up resistor RA5 (see also FIG. 7) is connected to the data signal 612b3 and the error signal 612b4 output from the disconnection / short-circuit monitoring driver 612b. Only one of the data signals 612b3 output from the disconnection / short-circuit monitoring driver 612b is connected to the pull-up resistor RA6 (see also FIG. 7).

By monitoring the disconnection with separate disconnection / short-circuit monitoring drivers in this way, it is possible to immediately determine which switch has an error. Although not shown, general winning opening switches (upper right general winning opening switch 48a1, upper left general winning opening switch 48b1, left middle general winning opening switch 48c1, lower left general winning opening switch 48d1), count switch, out opening switch 49a, etc. Separate disconnection / short-circuit monitoring drivers may be provided according to the switches of the same system. In this way, it is possible to immediately determine which system of switches has an error.

Although the connector CN6 is shown in FIGS. 7 and 10, the connector CN6 is provided as a spare when the number of special symbol start port switches increases, and is not used in the present embodiment. It is a connector of.

By the way, the error signal 612a4 output from the disconnection / short circuit monitoring driver 612a and the error signal 612b4 output from the disconnection / short circuit monitoring driver 612b are the 8-bit data signal 601f shown in FIG. 8 via the buffer 613a shown in FIG. Will be input to the one-chip microcomputer 600 shown in FIG. Then, among the data signal 612a3 output from the disconnection / short circuit monitoring driver 612a and the data signal 612b3 output from the disconnection / short circuit monitoring driver 612b, the general winning opening switch (upper right general winning opening switch 48a1, upper left general winning opening switch 48b1). , Left middle general winning opening switch 48c1, lower left general winning opening switch 48d1), as the 8-bit data signal 601f shown in FIG. 8 via the buffer 613b shown in FIG. 11, the one-chip micro shown in FIG. It will be input to the computer 600. Further, among the data signals 612a3 output from the disconnection / short circuit monitoring driver 612a, the data signal relating to the out port switch 49a is referred to as the 8-bit data signal 601f shown in FIG. 8 via the buffer 613c shown in FIG. It will be input to the one-chip microcomputer 600 shown in FIG. Of the plurality of chip select signals 601j shown in FIG. 8, the eighth chip select signal 613a1 from the top of the drawing is input to the buffer 613a, and the wiring pattern of the voltage input to the buffer 613a and the ground wiring. A capacitor C8 (see also FIG. 7) is provided between the pattern. Then, among the plurality of chip select signals 601j shown in FIG. 8, the ninth chip select signal 613b1 from the top of the drawing is input to the buffer 613b, and the wiring pattern of the voltage input to the buffer 613b and the ground wiring. A capacitor C12 (see also FIG. 7) is provided between the pattern. Further, the 10th chip select signal 613c1 from the top of the drawing is input to the buffer 613c among the plurality of chip select signals 601j shown in FIG. 8, and the wiring pattern of the voltage input to the buffer 613c and the ground are A capacitor C16 (see also FIG. 7) is provided between the wiring pattern and the wiring pattern.

<Explanation of wiring related to the setting display device>
Next, the wiring content of the setting display device 620 for displaying the setting content of the probability of generating a special gaming state advantageous to the player will be specifically described with reference to FIGS. 12 and 13.

As shown in FIG. 12, the 8-bit data signal 601f output from the one-chip microprocessor 600 shown in FIG. 8 is also output to the setting display device 620 side. The 8-bit data signal 601f is input to the LED driver 621a as a 7-bit data signal 621a1 and is input to the LED driver 621a as an 8-bit data signal 621a1. When the LED driver 621a receives the 7-bit data signal 621a1, it outputs the 1-bit selection data signal 621a2 to the setting display device 620 as shown in FIG. Then, whether or not to display the setting display device 620 is selected by the 1-bit selection data signal 621a2.

On the other hand, when the LED driver 621b shown in FIG. 12 receives the 8-bit data signal 621b1, the 8-bit setting display data signal 621b2 is shown in FIG. 13 via the damping resistors R80 to R87 (see also FIG. 7). As described above, the data is output to the setting display device 620. As a result, the setting display device 620 displays the setting content of the probability of generating a special gaming state that is advantageous to the player. The 11th chip select signal 621b3 from the top of the drawing is input to the LED driver 621b among the plurality of chip select signals 601j shown in FIG. 8, and is generated by the system reset generation unit 1320 (see FIG. 6). The system reset signal RST is input. A capacitor C50 (see also FIG. 7) is provided between the voltage wiring pattern input to the LED driver 621b and the ground wiring pattern. A pull-up resistor R17 (see also FIG. 7) is connected to the chip select signal 621b3.

<Explanation of wiring related to solenoid>
Next, the wiring contents related to the solenoid drive driver for driving the normal electric accessory solenoid 45c (see FIG. 6) and the special electric accessory solenoid 46b (see FIG. 6) will be specifically described with reference to FIG.

As shown in FIG. 14, in the solenoid drive drivers Q1 to Q4, of the 8-bit data signals 601f output from the one-chip microcomputer 600 shown in FIG. 8, 1-bit data signals 631a to 631d are damping resistors R26. It is input via ~ R29 (see also FIG. 7). Then, from the solenoid drive drivers Q1 to Q4, as shown in FIG. 14, the ordinary electric accessory solenoid 45c (see FIG. 6) and the special electric motor are connected to the connector CN7 (see also FIG. 7) via the diodes D1 to D4. The drive signal 631e of the accessory solenoid 46b (see FIG. 6) is output. As a result, when the lottery of the ordinary symbol is won, the ordinary electric accessory solenoid 45c (see FIG. 6) is driven and controlled so that the opening / closing member 45b (see FIG. 5) is opened a predetermined number of times for a predetermined time, and the special symbol lottery is performed. Is won, the special electric accessory solenoid 46b (see FIG. 6) is controlled to open the large winning opening (not shown).

<Explanation of the placement position of each part>
Thus, each of the above-described components is arranged on the main control board 60 as shown in FIG. 7. That is, when connecting the one-chip microcomputer 600 arranged on the main control board 60 and the solenoid drive drivers Q1 to Q4 as shown in FIG. 7, the one-chip microcomputer is connected as shown in FIGS. 8 and 14. The 600 and the solenoid drive drivers Q1 to Q4 are connected so that the distance of the wiring length is L1. Then, as shown in FIG. 7, the drive signals of the one-chip microcomputer 600 arranged on the main control board 60, the ordinary electric accessory solenoid 45c (see FIG. 6), and the special electric accessory solenoid 46b (see FIG. 6). When connecting to the connector CN7 from which 631e (see FIG. 14) is output, as shown in FIGS. 8 and 14, the one-chip microcomputer 600 and the connector CN7 are connected so that the wiring length distance is L1a. ing. Further, when connecting the one-chip microcomputer 600 arranged on the main control board 60 and the measurement display device 610 as shown in FIG. 7, the LED driver 611a or the LED is further connected as shown in FIGS. 8 and 9. The one-chip microcomputer 600 and the measurement display device 610 are connected via the driver 611c so that the distance of the wiring length is L2. Furthermore, when connecting the one-chip microcomputer 600 arranged on the main control board 60 and the setting display device 620 as shown in FIG. 7, the LED driver is shown in FIGS. 8, 12, and 13. The one-chip microcomputer 600 and the setting display device 620 are connected via the 621a or the LED driver 621b so that the distance of the wiring length is L3.

Thus, such a wiring length distance L1 or L1a is set longer than L2 or longer than L3. In this way, it is possible to reduce the influence of noise generated from the solenoid drive drivers Q1 to Q4 or the connector CN7 on the measurement display device 610 or the setting display device 620, and thus the measurement display device 610 and the setting display. It is possible to reduce the possibility that the display content of the device 620 is not displayed normally.

On the other hand, when connecting the one-chip microcomputer 600 arranged on the main control board 60 and the connector CN8 to which the signal line relating to the out port switch 49a is connected as shown in FIG. 7, FIGS. 8 and 10 and As shown in FIG. 11, the one-chip microcomputer 600 and the connector CN8 are connected via the disconnection / short-circuit monitoring drivers 612a, 612b and the buffers 613a, 613b, 613b so that the wiring length is L4. ing.

Thus, such a wiring length distance L4 is set longer than L2 or longer than L3. By doing so, it is possible to reduce the situation in which the influence of noise generated from the connector CN8 affects the measurement display device 610 or the setting display device 620, and thus the display contents of the measurement display device 610 and the setting display device 620 are normal. It is possible to reduce the possibility that it will not be displayed in.

Further, as shown in FIG. 7, the measurement display device 610 is arranged so as to be above the center line O1 passing through the center point O of the main control board 60, and the solenoid drive drivers Q1 to Q4 are arranged so as to be above the center line O1. It is arranged so as to be near or below O1. Thus, if the measurement display device 610 and the solenoid drive drivers Q1 to Q4 are arranged at positions facing each other with the center line O1 passing through the center point O of the main control board 60 in between, the solenoid drive is performed. It is possible to reduce the situation in which the influence of noise generated by the drivers Q1 to Q4 affects the measurement display device 610, and thus reduce the possibility that the display content of the measurement display device 610 is not normally displayed. Since the measurement display device 610 and the solenoid drive drivers Q1 to Q4 may be arranged at opposite positions, they are arranged above / below the main control board 60, not limited to the arrangement positions shown in the present embodiment. It may be arranged on the right / left side, diagonally, or the like.

On the other hand, as shown in FIG. 7, the setting display device 620 is arranged so as to be on the left side of the center line O2 passing through the center point O of the main control board 60, and the solenoid drive drivers Q1 to Q4 are arranged at the center. It is arranged so as to be on the right side of the line O2. Thus, if the setting display device 620 and the solenoid drive drivers Q1 to Q4 are arranged at positions facing each other with the center line O2 passing through the center point O of the main control board 60 in between, the solenoid drive is performed. It is possible to reduce the situation in which the influence of noise generated by the drivers Q1 to Q4 affects the setting display device 620, and thus reduce the possibility that the display content of the setting display device 620 is not normally displayed. Since the measurement display device 620 and the solenoid drive drivers Q1 to Q4 may be arranged at opposite positions, they are arranged above / below the main control board 60, not limited to the arrangement positions shown in the present embodiment. It may be arranged on the right / left side, diagonally, or the like.

On the other hand, as shown in FIG. 7, the measurement display device 610 is arranged so as to be above the center line O1 passing through the center point O of the main control board 60, and the ordinary electric accessory solenoid 45c (see FIG. 6). The connector CN7 from which the drive signal 631e (see FIG. 14) of the special electric accessory solenoid 46b (see FIG. 6) is output is arranged so as to be below the center line O1. As described above, the measurement display device 610, the ordinary electric accessory solenoid 45c (see FIG. 6), and the special electric accessory solenoid 46b (FIG. 6) sandwich the center line O1 passing through the center point O of the main control board 60. If the drive signal 631e (see FIG. 14) (see FIG. 14) is output at a position opposite to the connector CN7, the normal electric accessory solenoid 45c (see FIG. 6) and the special electric accessory solenoid 46b (see FIG. 6) are arranged. 6) The drive signal 631e (see FIG. 14) is output. The influence of noise generated from the connector CN7 on the measurement display device 610 can be reduced, so that the display content of the measurement display device 610 is normal. It is possible to reduce the possibility that it will not be displayed in. The position where the measurement display device 610 faces the connector CN7 from which the drive signal 631e (see FIG. 14) of the normal electric accessory solenoid 45c (see FIG. 6) and the special electric accessory solenoid 46b (see FIG. 6) is output. Therefore, it may be arranged above / below the main control board 60, not limited to the arrangement position shown in the present embodiment, and further, right / left, diagonally, etc. It may be arranged.

On the other hand, as shown in FIG. 7, the setting display device 620 is arranged so as to be on the left side of the center line O2 passing through the center point O of the main control board 60, and the ordinary electric accessory solenoid 45c (see FIG. 6). The connector CN7 from which the drive signal 631e (see FIG. 14) of the special electric accessory solenoid 46b (see FIG. 6) is output is arranged so as to be on the right side of the center line O2. Thus, the setting display device 620, the ordinary electric accessory solenoid 45c (see FIG. 6), and the special electric accessory solenoid 46b (FIG. 6) sandwich the center line O2 passing through the center point O of the main control board 60. If the drive signal 631e (see FIG. 14) (see FIG. 14) is output at a position opposite to the connector CN7, the normal electric accessory solenoid 45c (see FIG. 6) and the special electric accessory solenoid 46b (see FIG. 6) are arranged. 6) The drive signal 631e (see FIG. 14) is output. The influence of noise generated from the connector CN7 on the setting display device 620 can be reduced, so that the display content of the setting display device 620 is normal. It is possible to reduce the possibility that it will not be displayed in. The position where the setting display device 620 faces the connector CN7 from which the drive signal 631e (see FIG. 14) of the normal electric accessory solenoid 45c (see FIG. 6) and the special electric accessory solenoid 46b (see FIG. 6) is output. Therefore, it may be arranged above / below the main control board 60, not limited to the arrangement position shown in the present embodiment, and further, right / left, diagonally, etc. It may be arranged.

On the other hand, as shown in FIG. 7, the measurement display device 610 is arranged so as to be above the center line O1 passing through the center point O of the main control board 60 or above the one-chip microcomputer 600 with reference to the out port. The connector CN8 to which the signal line related to the switch 49a is connected is arranged so as to be below the center line O1 or below the one-chip microcomputer 600 as a reference. Then, in this way, the measurement display device 610 and the connector CN8 to which the signal line relating to the out port switch 49a is connected are connected with the center line O1 passing through the center point O of the main control board 60 or the one-chip microcomputer 600. By arranging them at opposite positions, it is possible to reduce the influence of noise generated from the connector CN8 to which the signal line related to the out port switch 49a is connected on the measurement display device 610, and thus the measurement display. It is possible to reduce the possibility that the display content of the device 610 is not displayed normally. Since the measurement display device 610 and the connector CN8 to which the signal line related to the out port switch 49a is connected may be arranged at opposite positions, the main control is not limited to the arrangement position shown in the present embodiment. It may be arranged above / below the substrate 60 or the one-chip microcomputer 600, and may be arranged on the right / left side, diagonally, or the like.

On the other hand, as shown in FIG. 7, the setting display device 620 is arranged so as to be on the left side of the center line O2 passing through the center point O of the main control board 60, and the signal line relating to the out port switch 49a is connected. The connector CN8 is arranged so as to be on the right side of the center line O2. Thus, in this way, the setting display device 620 and the connector CN8 to which the signal line relating to the out port switch 49a is connected are arranged at positions facing each other with the center line O2 passing through the center point O of the main control board 60 interposed therebetween. By doing so, it is possible to reduce the influence of noise generated from the connector CN8 to which the signal line related to the out port switch 49a is connected on the setting display device 620, and thus the display content of the setting display device 620. Can be reduced from the possibility that is not displayed normally. Since the setting display device 620 and the connector CN8 to which the signal line related to the outlet switch 49a is connected may be arranged at opposite positions, the main control is not limited to the arrangement position shown in the present embodiment. It may be arranged above / below the substrate 60 or the one-chip microcomputer 600, and may be arranged on the right / left side, diagonally, or the like.

On the other hand, as shown in FIG. 7, when connecting the one-chip microcomputer 600 arranged on the main control board 60 and the LED driver 611c as shown in FIG. 7, as shown in FIGS. 8 and 9. The one-chip microcomputer 600 and the LED driver 611c are connected so that the distance of the wiring length is L5.

Therefore, the distance L5 of such a wiring length is set to be shorter than L2. By doing so, the distance for transmitting the 8-bit data signal 611c1 shown in FIG. 9 to the LED driver 611c is shortened, so that the influence of noise can be reduced. Therefore, it is possible to reduce the possibility that the display content of the measurement display device 610 is not normally displayed.

Further, the distance (L2-L5) of the wiring length between the LED driver 611c and the measurement display device 610 shown in FIG. 9 is the wiring length between the one-chip microcomputer 600 and the LED driver 611c shown in FIGS. 8 and 9. It is set to be longer than the distance L5 (L2-L5> L5). By doing so, the distance for transmitting the 8-bit data signal 611c1 shown in FIG. 9 to the LED driver 611c is further shortened, so that the influence of noise can be further reduced. Therefore, it is possible to reduce the possibility that the display content of the measurement display device 610 is not normally displayed.

On the other hand, as shown in FIG. 7, when connecting the one-chip microcomputer 600 arranged on the main control board 60 and the LED driver 621b as shown in FIG. 7, as shown in FIGS. 8 and 12. The one-chip microcomputer 600 and the LED driver 621b are connected so that the distance of the wiring length is L6.

Therefore, the distance L6 of such a wiring length is set to be shorter than L3. By doing so, the distance for transmitting the 8-bit data signal 621b1 shown in FIG. 12 to the LED driver 621b is shortened, so that the influence of noise can be reduced. Therefore, it is possible to reduce the possibility that the display content of the setting display device 620 is not normally displayed.

Further, the distance (L3-L6) of the wiring length between the LED driver 621b and the setting display device 620 shown in FIG. 12 is the wiring length between the one-chip microcomputer 600 and the LED driver 621b shown in FIGS. 8 and 12. It is set to be longer than the distance L6 (L3-L6> L6). By doing so, the distance for transmitting the 8-bit data signal 621b1 shown in FIG. 12 to the LED driver 621b is further shortened, so that the influence of noise can be further reduced. Therefore, it is possible to reduce the possibility that the display content of the setting display device 620 is not normally displayed.

<Explanation of measurement display device, setting display device layout, and wiring pattern>
By the way, as shown in FIG. 7, the measurement display device 610 and the setting display device 620 arranged on the main control board 60 are set so that the wiring length distance L2 is shorter than the wiring length distance L3. There is. By arranging the one-chip microcomputer 600, which is larger in size than the other parts, in this way, the display content of the measurement display device 610 is more noticeable than the display content of the setting display device 620. Therefore, it becomes easy to confirm the display contents of the measurement display device 610. In the present embodiment, an example in which the measurement display device 610 and the setting display device 620 are arranged on the main control board 60 is shown, but in order to improve visibility, a separate board different from the main control board 60 ( For example, the measurement display device 610 or the setting display device 620 may be arranged on a relay board or the like.

Further, as shown in FIG. 7, the arrangement relationship between the measurement display device 610 and the setting display device 620 is such that the measurement display device 610 and the setting display device 620 can be easily distinguished from each other. It is preferable to arrange the one-chip microcomputer 600, which is larger in size than the other components, between the two.

By the way, as shown in FIG. 7, the four 7 segments constituting the measurement display device 610 are provided with five leg portions 610a on each of the left and right ends as shown by black circles in the figure. Of the second selection data signal 611a3 and the measurement display data signal 611c2 shown in FIG. 9 input to the 610, as shown in FIG. 7, at least one wiring pattern H1 to H4 constitutes four of the measurement display device 610. It is wired so as to pass between the leg portions 610a provided on each of the left and right ends of the seven segments of the above. In this way, the circuit configuration can be simplified.

Further, as shown in FIG. 7, one 7-segment constituting the setting display device 620 is provided with five leg portions 620a on each of the left and right ends as shown by black circles in the figure, and is provided with a measurement display device. Of the selection data signal 621a2 and the setting display data signal 621b2 of FIG. 13 input to the 610, as shown in FIG. 7, at least one wiring pattern H10 is one of the seven segments constituting the setting display device 620. It is wired so as to pass between the leg portions 620a provided on each of the left and right ends. In this way, the circuit configuration can be simplified.

On the other hand, the measurement display device 610 and the setting display device 620 are arranged on the main control board 60 as shown in FIG. That is, as shown in FIG. 15, the main control board 60 has an insulating layer 60a1 made of resin or the like, a component surface 60b1 formed on the upper surface of the insulating layer 60a1, and a solder formed on the lower surface of the insulating layer 60a1. It is composed of a surface 60c1. A plurality of mounting holes 60d1 are formed in the main control board 60. The legs 610a and 620a are inserted into the mounting holes 60d1 so that the measurement display device 610 and the setting display device 620 are arranged on the component surface 60b1 of the main control board 60 thus formed, and the legs 610a, By soldering the 620a on the solder surface 60c1 side, the measurement display device 610 and the setting display device 620 are arranged on the main control board 60. Thus, if the measurement display device 610 and the setting display device 620 are arranged on the main control board 60 in a so-called non-through hole in which the inside of the mounting hole 60d1 is not plated, the circuit configuration can be simplified. Can be transformed into.

By the way, as described above, the main control board 60 is provided with a transparent main control board case 60a detachably as shown in FIG. 4, and the main control board case 60a is provided with the name of the company and the name of the company. A sticker or the like with a description or the like of each terminal printed or printed on the surface is attached. However, if the measurement display device 610 or the setting display device 620 is placed in such a portion where the name of the company, the description of each terminal, or the like is printed or a sticker on which the printed description is printed, the measurement display device 610 or the setting display device 620 is placed. The main control board case 60a must be removed from the main control board 60 to check the display contents of the measurement display device 610 and the setting display device 620. Therefore, in order to prevent such a situation, the name of the company, the description of each terminal, etc. are printed or printed on the main control board case 60a at the arrangement position of the measurement display device 610 and the setting display device 620. It is preferable not to stick such as.

Further, as shown in FIG. 7, since the setting display device 620 is arranged at the lower end of the main control board 60, the main control board is as shown in FIG. 7 in order to protect the display contents of the setting display device 620. A part of the case 60a may be projected downward to provide a protruding portion 60aA for protecting the setting display device 620.

<Explanation of RAM clear switch, setting key switch, setting change switch>
By the way, as shown in FIG. 7, a RAM clear switch 630 is arranged on the main control board 60. When the RAM clear switch 630 is pressed, not all the memory areas of the main control RAM 600c (see FIG. 6) are cleared, but only a part of the memory areas are cleared. That is, as shown in FIG. 16, the main control RAM 600c has a normal RAM area 600ca used as a work area and the like, and the number of prize balls and the number of non-winning balls measured by the main control board 60, that is, the main control CPU 600. It is composed of a measurement RAM area 600 cc that stores the total number of game balls fired in the game area 40 including the game area 40. Then, in the main control RAM 600c configured in this way, when the RAM clear switch 630 is pressed, the measurement RAM area 600cc of the main control RAM 600c is not cleared, and only the normal RAM area 600ca is cleared. There is. By doing so, it is possible to prevent a situation in which the total number of game balls fired in the game area 40 including the measured number of prize balls and the number of non-winning balls is erroneously cleared.

Further, as shown in FIG. 7, a setting key switch 640 and a setting change switch 650 are arranged on the main control board 60. When a dedicated key is inserted into the setting key switch 640 and turned on, the setting change switch 650 sets the setting content of the probability of generating a special gaming state advantageous to the player, for example, 6 of "1" to "6". The setting can be changed in stages (for example, the setting "6" has the highest probability of generating a special gaming state advantageous to the player, and the setting "1" is a special advantageous to the player. The probability of generating a gaming state is the lowest). Then, the setting change content is displayed on the setting display device 620, and when the setting change content is confirmed, the dot on the lower right side of the 7 segment lights up, and it is displayed that the setting content has been confirmed. There is. In the following description, the setting change switch 650 has a function of changing the setting content of the probability of generating a special gaming state advantageous to the player (setting change function) and a function of confirming the setting change content (setting change). The explanation will be made on the premise that it has both the completion function), but of course, the setting change switch 650 has only a function of changing the setting content of the probability of generating a special gaming state that is advantageous to the player, and the setting change content is provided. May be determined by providing another switch.

<Program description>
Here, regarding the process of displaying the display contents on the measurement display device 610 and the setting display device 620 described above, the outline of the program stored in the main control ROM 600b (see FIG. 6) processed by the main control board 60. Will be described in more detail by referring to FIGS. 17 to 29.

<Explanation of main processing>
First, when the power is turned on to the pachinko gaming machine 1, a power-on signal indicating that the DC voltage generated by the voltage generation unit 1300 of the power supply board 130 (see FIG. 6) is applied to each control board is sent. In response to the signal, the main control CPU 600a (see FIG. 6) performs the main control main process shown in FIG. The main control CPU 600a first sets itself in the interrupt disabled state (step S1).

Next, the main control CPU 600a performs initial setting such as a register value in the main control CPU 600a (step S2).

Subsequently, the main control CPU 600a sets the start waiting time of the sub control board 80 (step S3), decrements the set waiting time (-1) (step S4), and clears the watchdog timer (WDT) (not shown). (Step S5).

Next, the main control CPU 600a confirms whether or not the set waiting time has become "0" (step S6), and if it has not become "0" (step S6: ≠ 0), returns to the process of step S4. , If it is "0" (step S6: = 0), the process proceeds to step S7.

Next, the main control CPU 600a acquires the voltage abnormality signal ALARM (see FIG. 6) output from the power supply board 130 (voltage monitoring unit 1310) (see FIG. 6) twice, and the acquired voltage abnormality signal ALARM twice. After confirming whether or not the levels of the above are the same, the voltage abnormality signal ALARM is stored in the internal register of the main control CPU 600a (not shown), and the level of the voltage abnormality signal ALARM is confirmed (step S7). Then, if the level of the voltage abnormality signal ALARM is "L" level (step S8: YES), the process returns to step S7, and if the level of the voltage abnormality signal ALARM is "H" level (step S8: NO), The process proceeds to step S9. That is, the main control CPU 600a repeats the same process until the voltage abnormality signal ALARM changes to a normal level (that is, “H” level) (steps S7 to S8). By acquiring the voltage abnormality signal ALARM twice in this way, an accurate signal can be read.

Next, the main control CPU 600a clears the watchdog timer (WDT) (not shown) (step S9), and confirms whether or not a signal (power-on signal) indicating that the power has been turned on has come from the payout control board 70 (step S9). Step S10). If the power-on signal has not arrived (step S10: OFF), the process returns to step S9, and if the power-on signal has arrived (step S10: ON), the process has a fixed cycle provided inside the main control CPU 600a. Set the CTC (Counter Timer Signal) that has a function to create a pulse output, a function to measure time, and the like. That is, the main control CPU 600a sets the time constant register of the CTC so that a timer interrupt is periodically applied every 4 ms (step S11).

<Main processing: Explanation of setting display device>
Next, the main control CPU 600a confirms whether or not the dedicated key is inserted into the setting key switch 640 shown in FIG. 7 and is turned on (step S12). If the setting key switch 640 is turned on (step S12: YES), the main control CPU 600a confirms whether or not the upper opening / closing door 7 and the lower opening door 8 are open (step). S13). If the upper opening / closing door 7 and the lower opening door 8 are open (step S13: YES), the main control CPU 600a is the normal RAM area 600ca of the main control RAM 600c shown in FIG. 16 in the main control RAM 600c (see FIG. 6). Are all cleared (step S14).

Next, the main control CPU 600a sets the setting changing flag SH_FLG to ON (step S15), and permits data writing to the main control RAM 600c (see FIG. 6) (step S16).

Next, the main control CPU 600a transmits a processing command (effect control command DI_CMD) for displaying to the effect control board 90 that the liquid crystal display device 41 is changing the setting (step S17), and the main control RAM 600c (FIG. 6). (See), the set value of the probability of generating a special gaming state advantageous to the player (for example, the set value of "1" to "6") stored in the player is acquired (step S18).

Next, the main control CPU 600a confirms whether or not the acquired set value indicates any of "1" to "6" (step S19). If the acquired set value does not indicate any of "1" to "6" (step S19: NO), "1" is set for the acquired set value (step S20). On the other hand, if the acquired set value indicates any of "1" to "6" (step S19: YES), the process proceeds to step S21.

Next, the main control CPU 600a performs a process of displaying the set value on the setting display device 620 (see FIGS. 6 to 7 and 13) (step S21). As a result, any value of "1" to "6" is displayed on the setting display device 620.

Next, the main control CPU 600a clears a watchdog timer (WDT) (not shown) (step S22).

Next, the main control CPU 600a confirms whether or not the setting change completion function is turned on by the setting change switch 650 (see FIG. 7) (step S23). If the setting change completion function is not turned on by the setting change switch 650 (see FIG. 7) (step S23: NO), the setting change function of the main control CPU 600a is turned on by the setting change switch 650 (see FIG. 7). It is confirmed whether or not it is (step S24). If the setting change function is not turned on by the setting change switch 650 (see FIG. 7) (step S24: NO), the main control CPU 600a returns to the process of step S22 and presses the setting change switch 650 (see FIG. 7). If the setting change function is turned on (step S24: YES), the main control CPU 600a increments (+1) the current set value (step S25) and returns to the process of step S19.

On the other hand, if the setting change completion function is turned on by the setting change switch 650 (see FIG. 7) (step S23: YES), the main control CPU 600a sets the current set value in the main control RAM 600c (see FIG. 6) (see FIG. 6). A process of storing in the normal RAM area 600ca of the main control RAM 600c shown in FIG. 16 (step S26) and causing the setting display device 620 (see FIGS. 6 to 7 and 13) to display that the set value has been determined. (Step S27). As a result, the dots on the lower right side of the 7 segments constituting the setting display device 620 (see FIGS. 7 and 13) are lit, and it is displayed that the setting contents have been confirmed.

Next, the main control CPU 600a clears a watchdog timer (WDT) (not shown) (step S28).

Next, the main control CPU 600a confirms whether or not the setting key switch 640 shown in FIG. 7 is turned off (step S29). If it is not turned off (step S29: NO), the processes of steps S28 to S29 are repeated until it is turned off, and if it is turned off (step S29: YES), the set value set on the effect control board 90 is shown. The set value command (effect control command DI_CMD) is transmitted (step S30), the setting changing flag SH_FLG is set to OFF (step S31), and the process proceeds to step S40.

<Explanation of main processing>
On the other hand, in the main control CPU 600a, if the setting key switch 640 (see FIG. 7) is OFF (step S12: NO) and the upper opening / closing door 7 and the lower opening door 8 are not opened as shown in FIG. 2 (step S13). : NO), the main control CPU 600a permits data writing to the main control RAM 600c (see FIG. 6) (step S32), and causes the effect control board 90 to display the standby screen on the liquid crystal display device 41 (effect). Control command DI_CMD) is transmitted (step S33),

Next, the main control CPU 600a confirms the contents of the backup flag BFL (step S34). The backup flag BFL is data indicating whether or not the backup process has been executed when a voltage drop due to a power failure or the like is detected in the voltage monitoring process shown in FIG.

If the backup flag BFL is in the OFF state (step S34: OFF), the backup process is not executed when a voltage drop due to a power failure or the like is detected in the voltage monitoring process shown in FIG. 18 described later. The main control CPU 600a transmits a processing command (effect control command DI_CMD) indicating that a RAM error has occurred to the effect control board 90 (step S35), and performs an infinite loop process.

On the other hand, if the backup flag BFL is in the ON state (step S34: ON), the backup process is executed when a voltage drop due to a power failure or the like is detected in the voltage monitoring process shown in FIG. 18 described later. Therefore, the main control CPU 600a performs a checksum calculation for calculating the checksum value. Then, when the checksum value is calculated, the main control CPU 600a performs a process of comparing the calculation result with the stored value of the SUM address in the main control RAM 600c (step S36). The checksum calculation is an 8-bit addition calculation for the main control RAM 600c, and the stored calculation result is the power supply board 130 shown in FIG. 6 together with other data stored in the main control RAM 600c. It is maintained by the backup power source generated by.

If the stored value of the SUM address and the calculated checksum value do not match (step S36: NO), the main control CPU 600a indicates to the effect control board 90 that a RAM error has occurred (effect control command DI_CMD). Is transmitted (step S35), and an infinite loop process is performed.

On the other hand, if they match (step S36: YES), the main control CPU 600a confirms the contents of the RAM clear switch 630 (see FIG. 7) (step S37). If the edge data of the RAM clear switch 630 is ON (step S37: ON), the main control CPU 600a determines that the RAM clear switch 630 has been pressed, and the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c is set. Without clearing, only the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c is cleared (step S39), and the process proceeds to step S40.

Thus, as described above, when the backup flag is OFF (step S34: OFF) or when the checksum values do not match (step S36: NO), the RAM clear switch 630 (see FIG. 7) is turned ON. Even so, the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c is not cleared. This is because if there is an abnormality in the backup process or the checksum value is abnormal, the setting value displayed on the setting display device 620 (see FIGS. 6 to 7 and 13) may be abnormal. Because it is expensive. Therefore, as shown in the present embodiment, after the process of step S35, the infinite loop process is executed, the power is turned on again, and the set value change process is performed before the game can be restarted. By doing so, it is possible to prevent a situation in which the player and the game hall (hall) side are disadvantaged.

On the other hand, if the edge data of the RAM clear switch 630 is OFF (step S37: OFF), the main control CPU 600a determines that the RAM clear switch 630 is not pressed, and the data stored in the main control RAM 600c is stored. Based on this, a process of returning to the game operation when the power is cut off is performed (step S38).

Thus, after finishing the process of step S38 or step S39, the main control CPU 600a permits data writing to the main control RAM 600c (see FIG. 6) (step S40), and clears the watchdog timer (WDT) (not shown). (Step S41).

Next, the main control CPU 600a sets the launch control signal to ON and transmits it to the payout control board 70 (step S42). As a result, the payout control board 70 controls to start the operation of the launch control board 71.

Next, the main control CPU 600a performs various random number counter update processes (step S44) in a state in which interrupts to itself are set to the disabled state (step S43), and then returns to the interrupt enabled state (step S45). , Returning to step S43, a loop process is performed in which the processes of steps S43 to S45 are repeated.

Thus, when the RAM clear switch 630 (see FIG. 7) is pressed, the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c is not cleared, and the normal RAM area of the main control RAM 600c is not cleared. By clearing only 600ca (see FIG. 16), it is possible to prevent a situation in which the total number of game balls fired in the game area 40 including the measured number of prize balls and the number of non-winning balls is erroneously cleared. ..

<Explanation of timer interrupt processing>
Next, with reference to FIG. 18, a timer interrupt program that interrupts the above-mentioned main processing and is started every 4 ms will be described. When this timer interrupt occurs, a save process for saving the contents of the register group in the main control CPU 600a to the stack area of the main control RAM 600c is executed (step S50), and then a voltage monitoring process is executed (step S51). This voltage monitoring process determines the level of the voltage abnormality signal ALARM output from the power supply board 130 (see FIG. 6), and if the voltage abnormality signal ALARM is at the “L” level (abnormal level), it is in the main control RAM 600c. The backup process of the stored data, that is, the process of calculating the checksum value of the data and storing the calculated checksum value as backup data in the main control RAM 600c is performed.

Next, when the voltage monitoring process (step S51) is completed, the main control CPU 600a performs a timer subtraction process for various timers (ordinary symbol variation timer, ordinary symbol accessory timer, etc.) that manage the time of each game operation. (Step S52).

Subsequently, the main control CPU 600a includes a special symbol 1 start port switch 44a (see FIG. 6), a special symbol 2 start port switch 45a (see FIG. 6), and a normal symbol start port switch 47a (see FIG. 6). Upper right general winning opening switch 48a1 (see FIG. 6), upper left general winning opening switch 48b1 (see FIG. 6), left middle general winning opening switch 48c1 (see FIG. 6), lower left general winning opening switch 48d1 (see FIG. 6), ON / OFF signals of various switches including the out port switch 49a (see FIG. 6) and the grand prize opening switch 46c (see FIG. 6) are input, and the ON / OFF signal level and the ON / OFF signal level are input to the work area in the main control RAM 600c. The rising state is stored (step S53). The details of this process will be described later.

Next, the main control CPU 600a performs a random number management process (step S54). Specifically, the process of updating random numbers such as ordinary symbols and special symbols used in the winning / failing lottery is performed.

Next, the main control CPU 600a performs an error management process (step S55). In the error management process, the supply of the game ball is stopped, or the game ball is clogged, the special symbol 1 start port switch 44a (see FIG. 6), the special symbol 2 start port switch 45a (see FIG. 6), Normal symbol start port switch 47a (see FIG. 6), upper right general winning opening switch 48a1 (see FIG. 6), upper left general winning opening switch 48b1 (see FIG. 6), left middle general winning opening switch 48c1 (see FIG. 6), lower left It determines whether there is any abnormality inside the device such as disconnection of the general winning opening switch 48d1 (see FIG. 6), the out opening switch 49a (see FIG. 6), and the large winning opening switch 46c (see FIG. 6). be.

Next, the main control CPU 600a determines whether or not the set value of the probability of generating a special gaming state advantageous to the player stored in the main control RAM 600c (see FIG. 6) is within the range of "1" to "6". The RAM error flag ER_FLG indicating the above is confirmed (step S56). If the RAM error flag ER_FLG is set to ON (step S56: YES), the main control CPU 600a has a probability of generating a special gaming state stored in the main control RAM 600c (see FIG. 6), which is advantageous to the player. It is determined that the set value of is out of the range of "1" to "6", the process related to the symbol is skipped, and the process proceeds to step S69. On the other hand, if the RAM error flag ER_FLG is set to OFF (step S56: NO), the main control CPU 600a generates a special gaming state stored in the main control RAM 600c (see FIG. 6), which is advantageous to the player. It is determined that the set value of the probability of causing the error is within the range of "1" to "6", and the process proceeds to step S47.

Next, the main control CPU 600a confirms the setting changing flag SH_FLG (step S57). If the setting changing flag SH_FLG is set to ON (step S57: YES), the main control CPU 600a determines that the setting value of the probability of generating a special gaming state advantageous to the player is being changed, and steps. Proceed to the process of S67. On the other hand, if the setting changing flag SH_FLG is set to OFF (step S57: NO), the main control CPU 600a determines that the setting value of the probability of generating a special gaming state advantageous to the player is not being changed. The process proceeds to step S58.

Next, the main control CPU 600a confirms the setting confirmation flag SK_FLG (step S58). If the setting confirmation flag SK_FLG is set to ON (step S58: YES), the main control CPU 600a determines that the setting value of the probability of generating a special gaming state advantageous to the player is being confirmed, and is in step S64. Proceed to the process of. On the other hand, if the setting confirmation flag SK_FLG is set to OFF (step S58: NO), the main control CPU 600a determines that the setting value of the probability of generating a special gaming state advantageous to the player is not being confirmed, and steps. Proceed to the process of S59.

Next, the main control CPU 600a executes the prize ball management process (step S59). This prize ball management process outputs a payout control command PAY_CMD for causing the payout control board 70 (see FIG. 6) to perform a payout operation. The details of this process will be described later.

Next, the main control CPU 600a executes the normal symbol processing (step S60). In this normal symbol processing, a winning / failing lottery of the normal symbol is executed, and the fluctuation pattern of the normal symbol and the stop display state of the normal symbol are determined based on the lottery result.

Next, the main control CPU 600a executes the normal electric accessory management process (step S61). In this ordinary electric accessory management process, a signal related to the control of the ordinary electric accessory solenoid 45c (see FIG. 6) required for generating the ordinary electric accessory opening game is generated based on the lottery result of the ordinary symbol processing (step S60). It is a thing.

Next, the main control CPU 600a executes a special symbol processing (step S62). In this special symbol processing, the winning / failing lottery of the special symbol is executed, and the variation pattern of the special symbol and the stop display mode of the special symbol are determined based on the result of the lottery. At this time, the main control CPU 600a has a special symbol based on a set value of a probability of generating a special gaming state which is advantageous to the player, which is stored in the main control RAM 600c (see FIG. 6) in relation to the winning / losing lottery of the special symbol. Win / fail lottery will be held. Therefore, does the main control CPU 600a have a set value of the probability of generating a special gaming state favorable to the player stored in the main control RAM 600c (see FIG. 6) within the range of "1" to "6"? Check if it is out of range, and if it is out of the range, set the RAM error flag ER_FLG to ON.

Next, the main control CPU 600a executes the special electric accessory management process (step S63). In this special electric accessory management process, mainly, when the big hit lottery result is "big hit" or "small hit", the setting process necessary for executing and controlling the winning game corresponding to the hit is performed. be. At this time, a signal relating to the control of the special electric accessory solenoid 46b (see FIG. 6) is also generated.

Next, the main control CPU 600a performs a process of confirming a set value of the probability of generating a special gaming state that is advantageous to the player, which is stored in the main control RAM 600c (see FIG. 6) (step S64). The details of this process will be described later.

Next, the main control CPU 600a executes the prize ball winning management process (step S65). In this prize ball winning management process, the total number of game balls fired in the game area 40 including the number of prize balls and the number of non-winning balls is measured, and the measured number of prize balls or the game area 40 including the number of non-winning balls is set. The process of displaying the content based on the total number of fired game balls on the measurement display device 610 is performed. The details of this process will be described later.

Next, the main control CPU 600a performs a solenoid drive process (step S66). At this time, the main control CPU 600a confirms the signal related to the control of the ordinary electric accessory solenoid 45c (see FIG. 6) generated in the ordinary electric accessory management process (step S61), and also confirms the special electric accessory management process (step S61). The signal related to the control of the special electric accessory solenoid 46b (see FIG. 6) generated in step S63) is confirmed. Then, based on this signal, the operation / stop of the normal electric accessory solenoid 45c or the special electric accessory solenoid 46b is controlled, and the opening / closing member 45b (see FIG. 5) is opened or closed, or a large winning opening (not shown). The opening / closing door 46a (see FIG. 5) operates so that the door opens or closes.

Next, the main control CPU 600a executes the LED management process (step S67). This LED management process generates output data to the special symbol display device 50 (see FIG. 5) and the normal symbol display device 51 (see FIG. 5) according to the progress of the process, or a control signal based on the data. Or, if the setting changing flag SH_FLG and the setting confirmation flag SK_FLG are set to ON, output data to the setting display device 620 (see FIGS. 6 to 7 and 13) can be generated. , It is a process of outputting a control signal based on the data. By this process, the lottery result is displayed on the special symbol display device 50 and the normal symbol display device 51, and the set value of the probability of generating a special game state advantageous to the player is displayed on the setting display device 620.

Next, the main control CPU 600a executes the external terminal management process (step S68). In this external terminal management process, the hall computer (not shown) used for managing the game islands of the amusement park is exposed to the number of hits during the game, the number of changes in the special symbol, the winning ball detection information to the winning opening, etc. , Predetermined game information is output. If the setting changing flag SH_FLG and the setting confirmation flag SK_FLG are set to ON, a security signal is output.

Next, the main control CPU 600a returns to the interrupt enable state (step S69), restores the contents of the registers saved in the stack area of the main control RAM 600c, and ends the timer interrupt (step S70). As a result, the interrupt processing routine returns to the main processing (see FIG. 17).

<Explanation of switch input processing>
Next, the switch input process will be described in detail with reference to FIGS. 19 to 20. As shown in FIG. 19, the switch input process first acquires the input data of each input port. That is, the main control CPU 600a includes the upper right general winning opening switch 48a1, the upper left general winning opening switch 48b1, the left middle general winning opening switch 48c1, the lower left general winning opening switch 48d1, the large winning opening switch 46c, the out opening switch 49a, and the special symbol 1. The ON / OFF signal data of various switches including the start port switch 44a, the special symbol 2 start port switch 45a, and the normal symbol start port switch 47a are acquired from the input port, and the acquired ON / OFF signals of the various switches are acquired. Create edge data for various switches based on the data. Then, the main control CPU 600a stores the edge data of the various switches created by the main control CPU 600a in the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c (step S80).

Next, the main control CPU 600a confirms whether or not there has been an illegal winning, that is, whether or not the large winning opening (not shown) is open despite the gaming state in which the opening / closing door 46a must be closed. If it is open, it is judged that the prize has been illegally won, and among the edge data of various switches stored in the main control RAM 600c area, the data judged to be the illegal prize is invalidated. Process (step S81).

<Explanation of prize invalidation processing>
In this respect, to be described in more detail with reference to FIG. 20, as shown in FIG. 20, the main control CPU 600a first confirms the value of the normal power open extension state flag FKE_FLG (step S90). If the value of the normal power opening extension state flag FKE_FLG is 05AH (step S90: = 05AH), the opening / closing member 45b (see FIG. 5) extends and opens the special symbol 2 starting port 45 (see FIG. 5). The main control CPU 600a determines that the state is in the state, and proceeds to the process of step S97.

On the other hand, if the value of the normal power open extension state flag FKE_FLG is not 05AH (step S90: ≠ 05AH), the value of the normal power operation flag FS_FLG is confirmed (step S91). If the value of the flag FS_FLG during normal operation is 05AH (step S91: = 05AH), it is determined that the opening / closing member 45b (see FIG. 5) is operating (the special symbol 2 starting port 45 is opened / closed). Then, the main control CPU 600a proceeds to the process of step S97.

On the other hand, if the value of the flag FS_FLG during normal operation is not 05AH (step S91: ≠ 05AH), it is determined that the operation of the opening / closing member 45b (see FIG. Check the value of FDN_TIMEr (step S92). If the value of the FDN_TIMEr effective timer for winning a prize is not 0 (step S92: ≠ 0), the opening / closing member 45b (see FIG. 5) is trying to close the special symbol 2 starting port 45 (see FIG. 5). The main control CPU 600a proceeds to the process of step S97.

On the other hand, if the value of the Fuden winning valid timer FDN_TIMER is 0 (step S92: = 0), the opening / closing member 45b (see FIG. 5) closes the special symbol 2 starting port 45 (see FIG. 5). In step S80 shown in FIG. 19, edge data of the special symbol 2 start port switch 45a stored in the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c is acquired (step S93). Then, the edge data is confirmed (step S94), and if it is OFF (step S94: NO), it is determined that there is no prize in the special symbol 2 start port 45 and no fraud has been performed, and the main control CPU 600a determines. The process proceeds to step S97.

On the other hand, if the edge data is ON (step S94: YES), the special symbol 2 start port 45 (see FIG. 5) is closed by the opening / closing member 45b (see FIG. 5), but the special symbol 2 start is started. Since the mouth 45 (see FIG. 5) has been awarded, it is determined that fraud has been performed, and the main control CPU 600a clears the edge data of the special symbol 2 start port switch 45a and turns it off. Then, the data is stored in the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c (step S95).

Next, the main control CPU 600a performs a process of setting 30s in the fraudulent information timer FJ_TIMEr (step S96). During the period when the fraudulent information timer FJ_TIMEr is not 0, in the error management process (step S55 shown in FIG. 18), error processing such as issuing an alarm sound from the speaker 17 (see FIG. 1) is performed.

Next, after completing the above processing, the main control CPU 600a acquires the edge data of the large winning opening switch 46c stored in the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c (step S97). Then, the edge data is confirmed (step S98), and if the edge data is OFF (step S98: NO), it is determined that there is no prize in the large winning opening (not shown) and no fraud has been performed. , Finish the prize invalidation process.

On the other hand, if the edge data is ON (step S98: YES), the value of the special electric accessory operation flag TDY_FLG is confirmed (step S99). If the value of the special electric accessory operation flag TDY_FLG is 05AH (step S99: = 05AH), the large winning opening (not shown) is in a state of being opened by the opening / closing door 46a (see FIG. 5), which is illegal. Judges that has not been performed, and finishes the prize invalidation process.

On the other hand, if the value of the special electric accessory operation flag TDY_FLG is not 05AH (step S99: ≠ 05AH), the grand prize opening (not shown) is closed by the opening / closing door 46a (see FIG. 5). However, since there is a prize, it is determined that fraud is being performed, and the main control CPU 600a performs a process of clearing the edge data of the large winning opening switch 46c and turning it off, and the normal RAM area of the main control RAM 600c. It is stored in 600 ca (see FIG. 16) (step S100).

Next, the main control CPU 600a sets 30s in the fraudulent information timer FJ_TIMEr (step S101), and finishes the winning invalidation process.

<Explanation of switch input processing>
Thus, after completing the above processing, the main control CPU 600a acquires edge data of various switches stored in the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c (step S82). .. If all of these edge data are in the OFF state (step S82: NO), the switch input process is completed.

On the other hand, if any one of the edge data is in the ON state (step S82: YES), the main control CPU 600a performs a process of adding a winning counter corresponding to each number of prize balls (step S83).

Specifically, when the game ball wins the upper right general winning opening switch 48a1 (edge data is turned ON), the first winning counter N1_CNT is incremented (+1). Then, when a game ball wins (edge data is ON) in any of the upper left general winning opening switch 48b1, the left middle general winning opening switch 48c1, and the lower left general winning opening switch 48d1, the second winning counter N2_CNT is set by the number of winnings. Performs the process of incrementing (+1). Further, when the game ball wins the large winning opening switch 46c (edge data is turned ON), the third winning counter N3_CNT is incremented (+1). Further, when the game ball wins (edge data is ON) in any of the special symbol 1 start port switch 44a and the special symbol 2 start port switch 45a, the fourth winning counter N4_CNT is incremented (+1) by the number of winnings. Perform processing.

Thus, the main control CPU 600a finishes the switch input process after performing the above process.

<Explanation of prize ball management process>
Next, with reference to FIG. 21, the prize ball management process will be described in detail. In the prize ball management process, as shown in FIG. 21, first, the total number of prize counters is set in the loop counter LOOP_CNT (step S110). That is, in the present embodiment, there are four winning counters: the first winning counter N1_CNT, the second winning counter N2_CNT, the third winning counter N3_CNT, and the fourth winning counter N4_CNT (see the explanation in step S83 shown in FIG. 19). Therefore, 4 is set in the loop counter LOOP_CNT.

Next, the main control CPU 600a sets 1 to the number of the winning counter. More specifically, in the present embodiment, there are four winning counters, the first winning counter N1_CNT, the second winning counter N2_CNT, the third winning counter N3_CNT, and the fourth winning counter N4_CNT. Will be assigned a number. That is, the number of the first winning counter N1_CNT is 1, the number of the second winning counter N2_CNT is 2, the number of the third winning counter N3_CNT is 3, the number of the fourth winning counter N4_CNT is 4, and so on. , The numerical value indicating the assigned number is N, and 1 is set to the numerical value N (step S111).

Next, the main control CPU 600a confirms the number set in the numerical value N, and confirms the value of the winning counter corresponding to the number (step S112). That is, if 1 is set in the numerical value N, it is confirmed whether or not the value of the first winning counter N1_CNT is 0, and if 2 is set in the numerical value N, the value of the second winning counter N2_CNT is set. Check if it is 0, if 3 is set in the numerical value N, check whether the value of the 3rd winning counter N3_CNT is 0, and if 4 is set in the numerical value N, check the 4th. Check whether the value of the winning counter N4_CNT is 0 or not.

Then, if the value of the winning counter is 0 (step S112: = 0), the main control CPU 600a performs a process of incrementing (+1) the numerical value N (step S113) and subtracts the value of the loop counter LOOP_CNT (-1). ) Is performed (step S114). Then, if the value of the loop counter LOOP_CNT becomes 0 (step S115: = 0) by the processing, the prize ball management processing is finished, and if it is not 0 (step S115: ≠ 0), the process returns to step S112, and steps S112 to S112 to The process of step S115 is repeated.

On the other hand, if the value of the winning counter is not 0 (step S112: ≠ 0), the main control CPU 600a subtracts (-1) the value of the first winning counter N1_CNT when the numerical value N is set to 1. If 2 is set in the numerical value N, the value of the second winning counter N2_CNT is subtracted (-1), and if 3 is set in the numerical value N, the value of the third winning counter N3_CNT is subtracted (-1). Is subtracted (-1), and when 4 is set in the numerical value N, the value of the fourth winning counter N4_CNT is subtracted (-1) (step S116).

Then, after this processing, the main control CPU 600a transmits the payout control command PAY_CMD, which specifies the number of payouts, to the payout control board 70 (see FIG. 6). Specifically, when the value of the first winning counter N1_CNT is subtracted in the process of step S96, the value obtained by subtracting the counter value, that is, the game ball (for example, 5) corresponding to 1 is paid. The payout control command PAY_CMD specified to be issued is transmitted to the payout control board 70 (see FIG. 6). Then, when the value of the second winning counter N2_CNT is subtracted, the value obtained by subtracting the counter value, that is, the payout control command PAY_CMD designated to pay out the game balls (for example, 10 pieces) corresponding to 1 is paid out. It is transmitted to the substrate 70 (see FIG. 6). Further, when the value of the third winning counter N3_CNT is subtracted, the value obtained by subtracting the counter value, that is, the payout control command PAY_CMD specified to pay out the game balls (for example, 15 pieces) corresponding to 1 is paid out. It is transmitted to the control board 70 (see FIG. 6). Furthermore, when the value of the 4th winning counter N4_CNT is subtracted, the value obtained by subtracting the counter value, that is, the payout control command PAY_CMD specified to pay out the game balls (for example, 3 pieces) corresponding to 1 is paid out. It is transmitted to the control board 70 (see FIG. 6) (step S117). As a result, the payout control board 70 controls the payout motor M to pay out the game ball based on the payout control command PAY_CMD.

Thus, the main control CPU 600a finishes the prize ball management process after finishing the above process.

<Explanation of setting confirmation process>
Next, with reference to FIG. 22, the above setting confirmation process will be described in detail. In the setting confirmation process, as shown in FIG. 22, the main control CPU 600a first sets the setting confirmation flag SK_FLG indicating whether or not the setting value of the probability of generating a special gaming state advantageous to the player is being confirmed to ON. It is confirmed whether or not it has been done (step S120). If the setting confirmation flag SK_FLG is set to ON (step S120: YES), it is determined that the setting value of the probability of generating a special gaming state advantageous to the player is being confirmed, and the process proceeds to step S122. If the setting confirmation flag SK_FLG is set to OFF (step S120: NO), it is determined that the set value of the probability of generating a special gaming state advantageous to the player is not being confirmed, and the process proceeds to step S121.

Next, the main control CPU 600a confirms whether or not the condition for confirming the set value of the probability of generating the special gaming state advantageous to the player is satisfied (step S121). That is, the conditions under which the set value may be confirmed include an error other than that the setting change switch 650 (see FIG. 7) is not pressed or the upper opening / closing door 7 and the lower opening door 8 are opened. It is not occurring, or the fluctuation of the special symbol has stopped (there is no start hold ball, the standby screen is displayed on the liquid crystal display device 41), or the fluctuation of the normal symbol has stopped (there is no start hold ball). State) and other conditions.

Thus, if any of the above-exemplified conditions is not satisfied, the main control CPU 600a ends the setting confirmation process, while any of the above-exemplified conditions is satisfied. If it is satisfied (step S121: YES), as shown in FIG. 2, it is confirmed whether or not the upper opening / closing door 7 and the lower opening door 8 are open (step S122).

If the upper opening / closing door 7 and the lower opening door 8 are open (step S122: YES), the main control CPU 600a confirms whether or not the dedicated key is inserted into the setting key switch 640 shown in FIG. 7 and is turned on. (Step S123). If the setting key switch 640 is ON (step S123: YES), the main control CPU 600a sets the setting confirmation flag SK_FLG to ON (step S124), and produces a processing command (effect control command DI_CMD) indicating this. It is transmitted to the control board 90 (step S125). Then, the main control CPU 600a sets the firing control signal to OFF, transmits it to the payout control board 70 (step S126), and ends the setting confirmation process. As a result, the payout control board 70 is controlled so as to stop the operation of the launch control board 71.

On the other hand, in the main control CPU 600a, if the upper opening / closing door 7 and the lower opening door 8 are not opened (step S122: NO), or if the setting key switch 640 shown in FIG. 7 is turned off (step S123: NO). ), The setting confirmation flag SK_FLG is set to OFF (step S127), and a processing command (effect control command DI_CMD) indicating this is transmitted to the effect control board 90 (step S128). Then, the main control CPU 600a sets the launch control signal to ON, transmits it to the payout control board 70 (step S129), and ends the setting confirmation process. As a result, the payout control board 70 controls to start the operation of the launch control board 71.

<Explanation of prize ball winning number management process>
Next, with reference to FIGS. 23 to 26, the above-mentioned prize ball winning number management process will be described in detail. As shown in FIG. 23, the prize ball winning number management process first executes a save process of saving the contents of the register group in the main control CPU 600a to the stack area of the main control RAM 600c (step S150).

Next, the main control CPU 600a initially sets the measurement RAM area 600 cc (see FIG. 16) of the main control RAM 600c (step S151).

<Explanation of initial setting of measurement RAM area>
In this respect, to be described in more detail with reference to FIG. 24, in this initial setting, as shown in FIG. 24, first, the value of the initialized flag INI_FLG is acquired (step S160). Next, the main control CPU 600a confirms whether or not the acquired value of the initialized flag INI_FLG is 5AH (step S161). If it is not 5AH (step S161: NO), 5AH is set in the initialized flag INI_FLG (step S162), the measurement RAM area 600cc (see FIG. 16) is initialized (cleared) (step S163), and the measurement is performed. Finish the initial setting process of the RAM area. On the other hand, if it is 5AH (step S161: YES), it is determined that the measurement RAM area 600cc (see FIG. 16) has already been initialized, and the initial setting process of the measurement RAM area is completed.

<Explanation of prize ball winning number management process>
Thus, as shown in FIG. 23, the main control CPU 600a performs the initial setting of the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c (step S151), and then executes the counting process (step S152).

<Explanation of counting process>
In this respect, to be described in more detail with reference to FIG. 25, as shown in FIG. 25, the main control CPU 600a confirms whether or not the game state is a low probability (a normal low probability state of the winning lottery probability) (step). S170). If the gaming state is not a low probability state (step S170: NO), the process proceeds to step S180.

On the other hand, if the gaming state is in a low probability state (step S170: YES), the main control CPU 600a is stored in the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c in step S80 shown in FIG. The edge data of the upper right general winning opening switch 48a1, the upper left general winning opening switch 48b1, the left middle general winning opening switch 48c1, the lower left general winning opening switch 48d1, and the special symbol 1 starting opening switch 44a are acquired (step S171). Then, these edge data are confirmed (step S172), and if all of the edge data are in the OFF state (step S172: NO), the process proceeds to step S174, and if any one of the edge data is in the ON state (step S172). Step S172: YES), the value of the cumulative prize ball counter RS_CNT is added (step S173). Specifically, if the edge data of the upper right general winning opening switch 48a1 is in the ON state, five prize balls are won, so the cumulative prize ball counter RS_CNT is added by +5. Then, if the edge data of the upper left general winning opening switch 48b1, the left middle general winning opening switch 48c1, and the lower left general winning opening switch 48d1 are in the ON state, 10 prize balls are awarded for one edge data in the ON state. Therefore, the cumulative prize ball counter RS_CNT is added by +10 (for the number of edge data in the × ON state). Further, if the edge data of the special symbol 1 start port switch 44a is in the ON state, three prize balls are awarded, so the cumulative prize ball counter RS_CNT is added by +3 (for the number of edge data in the × ON state). The cumulative prize ball counter RS_CNT is stored in the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c.

Next, in step S80 shown in FIG. 19, the main control CPU 600a acquires the edge data of the special symbol 2 start port switch 45a stored in the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c (see FIG. 16). Step S174). If this edge data is in the OFF state (step S175: NO), the process proceeds to step S177, and if this edge data is in the ON state (step S175: YES), the value of the first accessory cumulative prize ball counter YRS1_CNT. Is added (step S176). Specifically, if the edge data of the special symbol 2 start port switch 45a is in the ON state, three prize balls are awarded, so the first bonus cumulative prize ball counter YRS1_CNT is added by +3. The first accessory cumulative prize ball counter YRS1_CNT is stored in the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c.

Next, in step S80 shown in FIG. 19, the main control CPU 600a acquires the edge data of the large winning opening switch 46c stored in the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c (step S177). ). If this edge data is in the OFF state (step S178: NO), the process proceeds to step S180, and if this edge data is in the ON state (step S178: YES), the value of the second accessory cumulative prize ball counter YRS2_CNT. Is added (step S179). Specifically, if the edge data of the large winning opening switch 46c is in the ON state, 15 prize balls are awarded, so the second prize cumulative prize ball counter YRS2_CNT is added by +15. The second accessory cumulative prize ball counter YRS2_CNT is stored in the measurement RAM area 600 cc (see FIG. 16) of the main control RAM 600 c.

Next, in step S65 shown in FIG. 20, the main control CPU 600a acquires the edge data of the out port switch 49a stored in the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c (step S180). If this edge data is in the OFF state (step S181: NO), the counting process is completed, and if this edge data is in the ON state (step S181: YES), the cumulative out counter RO_CNT is incremented (+1) (step). S182). The cumulative out counter RO_CNT is stored in the measurement RAM area 600 cc (see FIG. 16) of the main control RAM 600 c.

Next, the main control CPU 600a confirms whether or not the game is in a low-probability game state (the winning lottery probability is a normal low-probability state) (step S183). If the gaming state is not in the low-accuracy state (step S183: NO), the counting process is finished, and if the gaming state is in the low-accuracy state (step S183: YES), the low-accuracy cumulative out counter TRO_CNT is incremented (+1) (+1). Step S184), the counting process is completed. The low-accuracy cumulative out counter TRO_CNT is stored in the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c.

<Explanation of prize ball winning number management process>
Thus, after completing the above processing, the main control CPU 600a executes the display processing (step S153) as shown in FIG. 23, and saves the contents of the registers saved in the stack area of the main control RAM 600c. It is returned (step S154), and the prize ball winning number management process is completed.

<Explanation of display processing>
In this respect, to be described in more detail with reference to FIG. 26, the main control CPU 600a first confirms whether or not the initial setting flag SS_FLG is set to ON (step S200). If the initial setting flag SS_FLG is not set to ON (step S200: NO), the cumulative out counter RO_CNT stored in the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c is acquired, and a predetermined number (step S200: NO) is acquired. For example, it is confirmed whether or not the number has reached (300) (step S201). If the cumulative out counter RO_CNT has not reached a predetermined number (for example, 300) (step S201: NO), the main control CPU 600a displays real-time measurement display data to be displayed on the measurement display device 610 (see FIGS. 7 and 9). It is created and stored in the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c (step S202). Further, the main control CPU 600a creates the previous measurement result display data to be displayed on the measurement display device 610 (see FIGS. 7 and 9), and stores the data in the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c. (Step S203).

Next, the main control CPU 600a increments (+1) the display counter HY_CNT (step S204).

Next, the main control CPU 600a confirms whether or not the display counter HY_CNT has reached a value corresponding to 5 seconds (first predetermined value) (step S205), and if it has not reached the first predetermined value (step S205: NO), the real-time measurement display data created in step S202 is output to the measurement display device 610 (see FIGS. 7 and 9) (step S206). As a result, the identification information "bL" blinks in the 7 segments of the fourth measurement display device 610D and the third measurement display device 610C (see FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9). Then, the ratio information “−−” is lit and displayed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9). The blinking display has a 0.6-second cycle of turning on for 0.3 seconds and turning off for 0.3 seconds.

On the other hand, if the first predetermined value is reached (step S205: YES), the main control CPU 600a confirms whether or not the display counter HY_CNT has reached the value corresponding to 10 seconds (second predetermined value) (step). S207), if the second predetermined value has not been reached (step S207: NO), the previous measurement result display data created in step S203 is output to the measurement display device 610 (see FIGS. 7 and 9) (step). S208). As a result, the identification information "b6" blinks in the 7 segments of the fourth measurement display device 610D and the third measurement display device 610C (see FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9). Then, the ratio information “−−” is lit and displayed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9). The blinking display has a 0.6-second cycle of turning on for 0.3 seconds and turning off for 0.3 seconds.

On the other hand, if the second predetermined value is reached (step S207: YES), the main control CPU 600a sets 0 in the display counter HY_CNT (step S209).

Thus, in this way, the display contents of the measurement display device 610 (see FIGS. 7 and 9) are displayed in real-time measurement display data (fourth measurement display device 610D, third measurement display device 610C) every 5 seconds. The identification information "bL" is blinking and displayed in the 7 segments of FIG. 9), and the ratio information "-" is displayed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9). -”Is lit), and the identification information“ b6 ”is blinking and displayed in the 7 segments of the previous measurement result display data (fourth measurement display device 610D, third measurement display device 610C (see FIG. 9)). The ratio information “−−” is lit and displayed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9)).

After the processing of step S206, step S208, and step S209, the main control CPU 600a finishes the display processing.

On the other hand, if the cumulative out counter RO_CNT has reached a predetermined number (for example, 300) (step S201: YES), the main control CPU 600a sets the initial setting flag SS_FLG to ON (step S210), and in step S211. Proceed to processing. Further, if the initial setting flag SS_FLG is set to ON (step S200: YES), the main control CPU 600a proceeds to the process of step S211.

Next, the main control CPU 600a acquires the low probability cumulative out counter TRO_CNT stored in the measurement RAM area 600 cc (see FIG. 16) of the main control RAM 600c, and determines whether or not the predetermined number (for example, 6000) has been reached. Is confirmed (step S211). If the low-probability cumulative out counters TRO_CNT have not reached a predetermined number (for example, 6000) (step S211: NO), the main control CPU 600a is stored in the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c. Acquire the values of the cumulative prize ball counter RS_CNT, the cumulative prize ball counter YRS1_CNT of the first character, the cumulative prize ball counter YRS2_CNT of the second character, and the low probability cumulative out counter TRO_CNT, and the cumulative prize ball counter RS_CNT and the first character. By adding the values of the cumulative prize ball counter YRS1_CNT and the second accessory cumulative prize ball counter YRS2_CNT and dividing the added value by the value of the low probability cumulative out counter TRO_CNT, the low probability cumulative out counter TRO_CNT is used as a reference. , The ratio of how many prize balls were won at the time of low accuracy will be calculated. Then, the main control CPU 600a creates real-time measurement blinking display data to be displayed on the measurement display device 610 (see FIGS. 7 and 9) based on the calculated ratio, and the measurement RAM area 600cc (FIG. 16) of the main control RAM 600c. (See) (see step S212). As a result, the identification information "bL" blinks in the 7 segments of the fourth measurement display device 610D and the third measurement display device 610C (see FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9). Then, the calculated ratio information is lit and displayed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9). The blinking display has a 0.6-second cycle of turning on for 0.3 seconds and turning off for 0.3 seconds.

On the other hand, if the low probability cumulative out counter TRO_CNT reaches a predetermined number (for example, 6000) (step S211: YES), the main control CPU 600a has a measurement RAM area 600 cc of the main control RAM 600c (FIG. 16), the cumulative prize ball counter RS_CNT, the first character cumulative prize ball counter YRS1_CNT, the second character cumulative prize ball counter YRS2_CNT, and the low probability cumulative out counter TRO_CNT are acquired, and the cumulative prize ball counter. Low accuracy by adding the values of RS_CNT, the first accessory cumulative prize ball counter YRS1_CNT, and the second accessory cumulative prize ball counter YRS2_CNT, and dividing the added value by the value of the low probability cumulative out counter TRO_CNT. Based on the cumulative out counter TRO_CNT, the ratio of how many prize balls were won at the time of low accuracy will be calculated. Then, the main control CPU 600a creates real-time measurement display data to be displayed on the measurement display device 610 (see FIGS. 7 and 9) based on the calculated ratio, and the measurement RAM area 600cc of the main control RAM 600c (see FIG. 16). ) (Step S213). As a result, the identification information "bL" is lit and displayed on the 7 segments of the 4th measurement display device 610D and the 3rd measurement display device 610C (see FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9). Then, the calculated ratio information is lit and displayed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9).

Next, the main control CPU 600a acquires the cumulative out counter RO_CNT stored in the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c, and confirms whether or not the predetermined number (for example, 60,000) has been reached. (Step S214). If the cumulative out counter RO_CNT has not reached a predetermined number (for example, 60,000) (step S214: NO), the main control CPU 600a confirms the measurement number flag KK_FLG indicating the measurement number (step S215). If the measurement count flag KK_FLG is 1 or more (step S215: YES), the measurement data stored in the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c is acquired, and the previous measurement result display data (cumulative) is acquired. When the number of outcounters RO_CNT reaches a predetermined number (for example, 60,000), the ratio of how many prize balls were won at the time of low probability based on the low probability cumulative outcounter TRO_CNT) is created and used for measurement of the main control RAM 600c. It is stored in the RAM area 600 cc (see FIG. 16) (step S216). As a result, the identification information "b6" is lit and displayed in the 7 segments of the fourth measurement display device 610D and the third measurement display device 610C (see FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9). Then, the ratio information, which is the previous measurement result, is lit and displayed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9).

On the other hand, if the measurement count flag KK_FLG is not 1 or more (step S215: NO), the main control CPU 600a creates the previous measurement result blinking display data to be displayed on the measurement display device 610 (see FIGS. 7 and 9). It is stored in the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c (step S217). As a result, the identification information "b6" blinks in the 7 segments of the fourth measurement display device 610D and the third measurement display device 610C (see FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9). Then, the ratio information “−−” is lit and displayed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9). The blinking display has a 0.6-second cycle of turning on for 0.3 seconds and turning off for 0.3 seconds.

On the other hand, if the cumulative out counter RO_CNT has reached a predetermined number (for example, 60,000) (step S214: YES), the main control CPU 600a increments (+1) the measurement count flag KK_FLG (step S218), and the cumulative out counter The values of RO_CNT, low probability cumulative out counter TRO_CNT, cumulative prize ball counter RS_CNT, first character cumulative prize ball counter YRS1_CNT, and second character cumulative prize ball counter YRS2_CNT are cleared (step S219).

Next, the main control CPU 600a increments (+1) the display counter HY_CNT after completing any of the processes of step S216, step S217, and step S219 (step S220).

Next, the main control CPU 600a confirms whether or not the display counter HY_CNT has reached a value corresponding to 5 seconds (first predetermined value) (step S221), and if it has not reached the first predetermined value (step S221: 1). NO), the real-time measurement display data created in step S212 or step S213 is output to the measurement display device 610 (see FIGS. 7 and 9) (step S206). As a result, until the low-accuracy cumulative out counter TRO_CNT reaches a predetermined number (for example, 6000), the fourth measurement display device 610D and the third measurement display device of the measurement display device 610 (see FIGS. 7 and 9) The identification information "bL" is blinking and displayed in the 7 segments of the 610C (see FIG. 9), and the calculation is performed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9). The ratio information will be lit and displayed. Then, when the low-accuracy cumulative out counter TRO_CNT reaches a predetermined number (for example, 6000), the fourth measurement display device 610D and the third measurement display device 610C (see FIGS. 7 and 9) of the measurement display device 610 (see FIGS. 7 and 9) The identification information "bL" is lit and displayed in the 7 segments of FIG. 9), and the calculated ratio information is displayed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9). Will be lit and displayed.

On the other hand, if the first predetermined value is reached (step S221: YES), the main control CPU 600a confirms whether or not the display counter HY_CNT has reached the value corresponding to 10 seconds (second predetermined value) (step). S223), if the second predetermined value is not reached (step S223: NO), the previous measurement result display data created in step S216 or step S217 is displayed on the measurement display device 610 (see FIGS. 7 and 9). Is output to (step S224). As a result, until the total number of cumulative outs for the first time reaches 60,000, the fourth measurement display device 610D and the third measurement display device 610C (see FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9). The identification information "b6" is blinking and displayed in the 7-segment of the second measurement display device 610B, and the ratio information "---" is lit in the 7-segment of the first measurement display device 610A (see FIG. 9). It will be displayed. Then, when the total number of cumulative outs for the first time reaches 60,000, after that, the fourth measurement display device 610D and the third measurement display device 610C (FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9) are used. The identification information "b6" is lit and displayed in the 7 segments of (see), and the previous measurement results are shown in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9). The ratio information will be lit and displayed. The blinking display has a 0.6-second cycle of turning on for 0.3 seconds and turning off for 0.3 seconds.

On the other hand, if the second predetermined value is reached (step S223: YES), the main control CPU 600a sets 0 in the display counter HY_CNT (step S225).

Thus, in this way, the display content of the measurement display device 610 (see FIGS. 7 and 9) can be switched to the real-time measurement display data and the previous measurement result display data every 5 seconds. The main control CPU 600a finishes the display process after finishing the processes of step S222, step S224, and step S225.

<Explanation of common setting and 7-segment output processing>
Here, the process for causing the measurement display device 610 to display a predetermined display (step S202, step S203, step S206, step S208, step S213, step S212, step S216, step S217, step S222, step S224 shown in FIG. 26). ) Will be specifically described with reference to FIG. 27.

The main control CPU 600a first updates the common counter COM_CNT as shown in FIG. 27 when the measurement display device 610 is made to display a predetermined value (step S300).

Next, the main control CPU 600a sets the common counter COM_CNT as an offset, and shows the first special symbol display device LED dynamic lighting common data signal 611a2a, the second special symbol display device LED dynamic lighting common data signal 611a2b, One of the third special symbol display device LED dynamic lighting common data signal 611a2c and the fourth special symbol display device LED dynamic lighting common data signal 611a2d is selected, and for example, "0" to "9". The output LED data table (not shown) in which the display pattern of is stored is selected (step S301).

Next, the main control CPU 600a includes the LED dynamic lighting common data signal 611a2a for the first special symbol display device, the LED dynamic lighting common data signal 611a2b for the second special symbol display device, and the LED dynamic lighting for the third special symbol display device. A selection signal of either the common data signal 611a2c or the fourth LED dynamic lighting common data signal 611a2d for the special symbol display device is output from the LED driver 611a (see FIG. 9) (step S302).

Next, the main control CPU 600a offsets the output LED data table (not shown) in which the display patterns of "0" to "9" are stored and the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c. , The output LED bit data relating to the special symbol display device 50 stored in the normal RAM area 600ca (see FIG. 16) of the main control RAM 600c is selected (step S303).

Next, the main control CPU 600a outputs the selected output LED bit data to the LED driver 611b (see FIG. 9). As a result, the LED dynamic lighting data signal 611b2 for the special symbol display device is output from the LED driver 611b (see FIG. 9), and the lottery result is displayed on the special symbol display device 50.

<Explanation of setting process for measurement display device>
Next, with reference to FIG. 28, a process for setting the display contents of the measurement display device 610 will be described.

As shown in FIG. 28, the main control CPU 600a confirms whether or not to turn off the third measurement display device 610C (see FIG. 9) and the fourth measurement display device 610D (see FIG. 9). That is, whether or not to turn off the fourth measurement display device 610D and the third measurement display device 610C (see FIG. 9) when the blinking display of step S202, step S203, step S212, and step S217 shown in FIG. (Step S350). When the lights are turned off (step S350: YES), the main control CPU 600a sets the bit data for turning off (step S351), and proceeds to the process of step S355.

On the other hand, when the lights are not turned off (step S350: NO), the main control CPU 600a has the fourth measurement display device 610D and the third measurement display device based on step S206, step S208, step S222, and step S224 shown in FIG. It is confirmed whether or not it is "bL" that is set to 610C (see FIG. 9) (step S352). If it is "bL" (step S352: YES), the bit data of "bL" is set (step S353), if it is not "bL" (step S352: NO), the bit data of "b6" is set (step S352: NO). Step S354), the process proceeds to step S355.

Thus, the main control CPU 600a is for measuring the main control RAM 600c in which the ratios calculated in steps S212 and S213 shown in FIG. 26 are stored after the processes of steps S351, S353, and S354 are completed. With the RAM area 600 cc (see FIG. 16) as an offset, for example, output LED bit data is selected from an output LED data table (not shown) in which display patterns of “0” to “9” are stored (step S355). ..

Next, the main control CPU 600a is set to display the selected output LED bit data on the second measurement display device 610B and the first measurement display device 610A (see FIG. 9) (step S356).

<Explanation of setting process for measurement display device>
Next, with reference to FIG. 29, a process for outputting the display contents set in FIG. 28 to the measurement display device 610 will be described.

As shown in FIG. 29, the main control CPU 600a sets the common counter COM_CNT updated in step S300 shown in FIG. 27 as an offset and outputs digits (that is, the first measurement display device 610A and the second measurement display device 610B). , The third measurement display device 610C or the fourth measurement display device 610D) is selected from the measurement RAM area 600cc (see FIG. 16) of the main control RAM 600c, and this is set as the RAM area to be output (step). S400).

Next, the main control CPU 600a outputs the output LED bit data from the RAM area to be output to the LED driver 611c (see FIG. 9) (step S401). As a result, the timer is in the order of the first measurement display device 610A ⇒ the second measurement display device 610B ⇒ the third measurement display device 610C ⇒ the fourth measurement display device 610D ⇒ the first measurement display device 610A ⇒ ... It will be turned on or off for each interrupt process. The common counter COM_CNT shares the LED dynamic lighting common data signal 611a2a for the first special symbol display device and the LED dynamic lighting common data signal 611a3a for the first measurement display device, and is the second special. The LED dynamic lighting common data signal 611a2b for the symbol display device and the LED dynamic lighting common data signal 611a3b for the second measurement display device are shared, and the LED dynamic lighting common data signal 611a2c for the third special symbol display device is shared. And the LED dynamic lighting common data signal 611a3c for the third measurement display device are shared, and the LED dynamic lighting common data signal 611a2d for the fourth special symbol display device and the LED dynamic for the fourth measurement display device are shared. The lighting common data signal 611a3d is shared. Therefore, when the LED dynamic lighting common data signal 611a2a for the first special symbol display device is output from the LED driver 611a (see FIG. 9) in step S302 shown in FIG. 27, the first measurement display device LED. Dynamic lighting Common data signal 611a3a is also output, and when the LED driver 611a (see FIG. 9) outputs the second special symbol display device LED dynamic lighting common data signal 611a2b, the second measurement display device LED dynamic lighting When the common data signal 611a3b is also output and the third special symbol display device LED dynamic lighting common data signal 611a2c is output from the LED driver 611a (see FIG. 9), the third measurement display device LED dynamic lighting common data When the signal 611a3c is also output and the fourth special symbol display device LED dynamic lighting common data signal 611a2d is output from the LED driver 611a (see FIG. 9), the fourth measurement display device LED dynamic lighting common data signal 611a3d Will also be output.

<Explanation of display contents of measurement display device and setting display device>
By performing such processing, the display contents of the measurement display device 610 (see FIGS. 7 and 9) can be displayed in two patterns of real-time measurement display data and previous measurement result display data every 5 seconds. It can be switched alternately. Further, in the initial setting when the power is turned on, the fourth measurement display device 610D and the third measurement of the measurement display device 610 (see FIGS. 7 and 9) are used as real-time measurement displays until the total number of cumulative outputs reaches 300. The identification information "bL" is blinked on the 7 segments of the display device 610C (see FIG. 9), and the ratio information is displayed on the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9). "---" is lit and displayed. Then, in the initial setting when the power is turned on, until the total number of cumulative outputs reaches 300, the fourth measurement display device 610D, third of the measurement display device 610 (see FIGS. 7 and 9) is displayed as the previous measurement result display. The identification information "b6" is blinked on the 7 segments of the measurement display device 610C (see FIG. 9), and the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9) are displayed. The ratio information "---" is lit and displayed.

Furthermore, until the total number of low-probability cumulative outs reaches 6000, the fourth measurement display device 610D and the third measurement display device 610C (see FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9) The identification information "bL" is blinking and displayed in the 7 segments, and the calculated ratio information is lit and displayed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9). .. Then, when the total number of low-probability cumulative outs reaches 6000, the 7 segments of the fourth measurement display device 610D and the third measurement display device 610C (see FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9). The identification information "bL" is lit and displayed, and the calculated ratio information is lit and displayed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9).

Furthermore, until the total number of cumulative outs for the first time reaches 60,000, the fourth measurement display device 610D and the third measurement display device 610C (see FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9). The identification information "b6" is blinking and displayed in the 7-segment of the second measurement display device 610B, and the ratio information "---" is lit in the 7-segment of the first measurement display device 610A (see FIG. 9). It will be displayed. Then, when the total number of cumulative outs for the first time reaches 60,000, after that, the fourth measurement display device 610D and the third measurement display device 610C (FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9) are used. The identification information "b6" is lit and displayed in the 7 segments of (see), and the previous measurement results are shown in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9). The ratio information will be lit and displayed.

Thus, the measurement display device 610 can blink or lightly display various contents as described above. Thus, in this way, various contents can be displayed on one measurement display device 610, so that the number of parts can be reduced and the circuit configuration can be simplified.

Further, unlike the measurement display device 610, the setting display device 620 displays only the setting content of the probability of generating a special gaming state that is advantageous to the player. By dividing the display contents in this way, it is possible to easily distinguish the display contents.

By the way, in the present embodiment, only an example in which the setting display device 620 is lit and displayed is shown as a display method, but the present invention is not limited to this, and the display of the setting display device 620 may be blinked during the setting change. good. At this time, it is preferable not to blink the display contents of the measurement display device 610. This is because it becomes difficult to distinguish the displayed contents if all of them are displayed blinking.

The ratio information displayed in the 7 segments of the second measurement display device 610B and the first measurement display device 610A (see FIG. 9) of the measurement display device 610 (see FIGS. 7 and 9) is the calculated value. If there are numbers after the decimal point, they are rounded off, and if the calculated value is one digit, 0 is displayed in the tens digit, and if the calculated value is 100, 99 is displayed. Just do it.

By the way, in the present embodiment, an example in which the measurement display device 610 and the setting display device 620 are separately provided is shown, but the present invention is not limited to this, and one of the four 7 segments constituting the measurement display device 610 is set. The display device 620 may be used, and the measurement display device 610 and the setting display device 620 may be used in combination.

Further, in the present embodiment, the setting change switch 650 has only a function of changing the setting content of the probability of generating a special gaming state advantageous to the player, and another switch is provided to confirm the setting change content. Although it has been explained that this may be performed, the switch is to allow the game ball to pass through the normal symbol start port 47 composed of a gate, and to detect the game ball with the normal symbol start port switch 47a (see FIG. 6). Depending on the situation, the setting change contents may be confirmed. By doing so, the number of parts can be reduced.

Further, in the present embodiment, when a dedicated key is inserted into the setting key switch 640 and turned on, the setting content of the probability of generating a special gaming state advantageous to the player is set by the setting change switch 650, for example. It was explained that the setting can be changed in 6 steps from "1" to "6", but the setting is not limited to this, and the operation of turning the launch handle 16 (see FIG. 1) or the launch handle 16 is provided. The setting may be changed or the setting may be confirmed by pressing the launch stop switch (not shown). By doing so, the number of parts can be reduced.

Further, in the present embodiment, an example in which the setting display device 620 is configured by one 7-segment is shown, but the present invention is not limited to this, and a configuration in which a plurality of LEDs are combined may be used.

Further, in the present embodiment, an example in which the setting display device 620, the setting key switch 640, and the setting change switch 650 are configured by separate parts is shown, but the present invention is not limited to this, and the setting display device 620 and the setting key are not limited to the above. The switch 640 and the setting change switch 650 may be unitized into one component. By doing so, the number of parts can be reduced.

Further, in the present embodiment, FIG. 7 shows an example in which a part of the main control board case 60a is projected downward to provide a protruding portion 60aA for protecting the setting display device 620, but the present invention is not limited to this. A special case for the setting display device 620 may be provided separately from the main control board case 60a to protect the setting display device 620. Even when the setting display device 620, the setting key switch 640, and the setting change switch 650 are unitized into one component, a dedicated case may be provided separately from the main control board case 60a to protect the setting display device 620, the setting key switch 640, and the setting change switch 650. ..

Further, in the present embodiment, an example in which the setting contents are displayed on the setting display device 620 is shown, but in the pachinko gaming machine 1 in which the setting of the probability of generating a special gaming state advantageous to the player is not provided, the pachinko gaming machine 1 is not provided. It is also possible to hide the setting contents of the probability of generating a special gaming state that is advantageous to the player.

Further, in the present embodiment, it is illustrated that the setting change switch 650 can change the setting content of the probability of generating a special gaming state advantageous to the player in 6 steps of, for example, "1" to "6". However, the present invention is not limited to this, and the RAM clear switch 630 mounted on the main control board 60, a volume change switch (not shown), or the like may be used. In this way, it is not necessary to newly provide the setting change switch 650, and the number of parts can be reduced. As for the switch whose setting can be changed, it is preferable that the switch has a click feeling.

Further, in the present embodiment, as shown in FIG. 17, the CTC is such that a timer interrupt is periodically interrupted every 4 ms before changing the set value of the probability of generating a special gaming state advantageous to the player. An example of setting a time constant register is shown, but the present invention is not limited to this, and the CTC's CTC interrupts the timer interrupt periodically every 4 ms after changing the set value of the probability of generating a special gaming state advantageous to the player. A time constant register may be set. For example, it may be provided after the processing of step S33 or step S34.

Further, in the present embodiment, as the content to be displayed on the measurement display device 610, an example of displaying the content relating to the ratio of how many prize balls have been won at the time of low accuracy is shown, but the content is not limited to this, and the accessory ratio and the continuous value are displayed. Various contents such as a prize ratio can be displayed.

1 Pachinko game machine 41 Liquid crystal display device 44 Special symbol 1 Starting port 44a Special symbol 1 Starting port switch 45 Special symbol 2 Starting port 45a Special symbol 2 Starting port switch 45c Ordinary electric accessory solenoid (solenoid)
46 Winning device 46b Special electric accessory solenoid (solenoid)
46c Large winning opening switch 48 General winning opening 48a Upper right general winning opening 48a1 Upper right general winning opening switch 48b Upper left general winning opening 48b1 Upper left general winning opening switch 48c Left middle general winning opening 48c1 Left middle general winning opening switch 48d Lower left general winning opening 48d1 Lower left general winning opening switch 49a Out opening switch 60 Main control board (board)
600 One-chip microcomputer (control CPU)
600a main control CPU
600b main control ROM
600c main control RAM
601f 8-bit data signal 601e Clock signal 610 Measurement display device 620 Setting display device (display means)
621a LED driver (display control means)
RO_CNT Cumulative Out Counter TRO_CNT Low Probability Cumulative Out Counter RS_CNT Cumulative Prize Ball Counter YRS1_CNT 1st Character Cumulative Prize Ball Counter YRS2_CNT 2nd Character Cumulative Prize Ball Counter CN7 Connector (Connecting Means)
Q1 to Q4 Solenoid drive driver (solenoid drive means)
O Center point O2 Center line L1a Wiring length distance (between the one-chip microcomputer and connector CN7) Wiring length distance L3 (between the one-chip microcomputer and the setting display device)

Claims (1)

A control CPU that controls game operations,
A display means that displays a set value for the probability of generating a special gaming state that is advantageous to the player, and
A display control means for displaying the display means and
Solenoid driving means to drive the solenoid and
A connecting means for relaying an electrical connection between the solenoid and the solenoid driving means is provided.
The control CPU, the display means, the display control means, the solenoid driving means, and the connection means are arranged on the same substrate, and the control CPU, the display means, the display control means, the solenoid driving means, and the connection means are arranged on the same substrate.
When the substrate is divided into a first region and a second region with reference to a center line passing through the center point of the substrate, the display means and the display control means are arranged in the first region and the a solenoid driving means and the connecting means, it is placed in front Stories second region, further,
A game in which the distance of the wiring length for electrical connection between the control CPU and the connection means is longer than the distance for the wiring length for electrical connection between the control CPU and the display means. Machine.

Images