JP6963582B2 - 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, and more particularly to a game machine capable of continuing a game without the player feeling unnatural.

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 restarts from the setting change state when a power failure occurs during the setting change state and the power failure is restored.

Japanese Unexamined Patent Publication No. 2018-82868

However, the above-mentioned gaming machine has a problem that the gaming cannot be continued without the player feeling unnatural.

Therefore, in view of the above problems, it is an object of the present invention to provide a gaming machine capable of continuing a game without the player feeling unnatural.

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 main control means (for example, the main control CPU 600a shown in FIG. 7) capable of comprehensively controlling the gaming operation and transmitting a predetermined control command, and
When a plurality of types of identification information are variablely displayed when a predetermined start condition is satisfied, the right to perform variable display of the identification information for which the start condition is satisfied but has not been started is stored up to a predetermined upper limit. Means (for example, the normal RAM area 600ca shown in FIG. 9A) and
Sub-control means (for example, sub-control CPU 800a shown in FIG. 7) that controls various effect operations based on receiving the predetermined control command, and
It has a display means (for example, the liquid crystal display device 41 shown in FIG. 5) for displaying various images including decorative patterns.
The number of first rights (for example, the number of start-holding balls is 3) is stored in the hold storage means (for example, the normal RAM area 600ca shown in FIG. 9A), and the display means (for example, FIG. 5). In a state where the number of the first rights (for example, the number of start-holding balls is 3) is displayed on the liquid crystal display device 41) shown in (1) (see, for example, FIG. 19 (a-2)).
The variable display of the identification information is started, and the number of first rights stored in the hold storage means (for example, the normal RAM area 600ca shown in FIG. 9A) (for example, the number of start hold balls is 3). The hold command indicating that the number of second rights (for example, the number of start hold balls is 2) is subtracted from the number of the main control means (for example, the number of start hold balls is 2), and the fluctuation pattern command is the main control means (for example, the main control CPU 600a shown in FIG. 7). ), But the sub-control means (for example, the sub-control CPU 800a shown in FIG. 7) could receive the variation pattern command, but could not receive the hold command, the display means. (For example, the liquid crystal display device 41 shown in FIG. 5) does not display the number of the second rights (for example, the number of start-holding balls is two), and the number of the first rights (for example, the start-holding balls). While displaying (the number is 3), the decorative pattern is variablely displayed (see, for example, FIG. 19 (c-1)).
The number of the second rights (for example, the number of start-holding balls is 2) is stored in the hold storage means (for example, the normal RAM area 600ca shown in FIG. 9A), and the display means (for example, FIG. When the variable display of the identification information is started while the number of the first rights (for example, the number of start-holding balls is 3) is still displayed on the liquid crystal display device 41) shown in 5, the hold The number of the third right is subtracted from the number of the second right (for example, the number of start-holding balls is 2) stored in the storage means (for example, the normal RAM area 600ca shown in FIG. 9A). (For example, a hold command indicating that the number of start-holding balls has reached one) and a variation pattern command are transmitted from the main control means (for example, the main control CPU 600a shown in FIG. 7), and the hold command and the variation When the pattern command is received by the sub-control means (for example, the sub-control CPU 800a shown in FIG. 7), the display means (for example, the liquid crystal display device 41 shown in FIG. 5) receives the number of the first rights (for example, the number of the first rights). The number of the first rights displayed (for example, the number of balls held for starting is 3) is the number of the second rights (for example, the number of balls held for starting), not the subtraction from the state where the number of balls held for starting is displayed. , in terms of starting holding cell counts were switched and displayed to two), the number of the number of second rights (e.g., is subtracted from the state start pending counts has displayed two) the third right (For example, the animation corresponding to the number of balls on hold for starting is one) is displayed, and the decorative symbol is varied and displayed (for example, FIGS. 19 (c-3) to (c-5)). See).

According to the present invention , the game can be continued without the player feeling unnatural .

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 front perspective view which enlarged-displayed the X part shown in FIG. It is a block diagram which shows the control device of the gaming machine which concerns on this embodiment. It is a circuit diagram around the measurement / setting display device mounted on the main control board which concerns on the same embodiment. (A) is an explanatory diagram for explaining a memory map showing a memory area of a main control ROM according to the same embodiment, and (b) is an explanatory diagram showing a memory area of a main control ROM according to the same embodiment. A diagram of the effect scenario table according to the same embodiment is shown, (a) shows a diagram in which a plurality of effect scenario data are stored, and (b) is stored in one layer data of the effect scenario data shown in (a). (C) is a diagram showing a control table referred to by the control code data shown in (b). It is a block diagram which shows the VDP which concerns on the embodiment. (A) is an explanatory diagram showing the conventional data arrangement of the main control ROM, and (b) is an explanatory diagram showing the data arrangement of the main control ROM according to the same embodiment. (A) shows an example of a program for arranging the data shown in FIG. 12 (b), and (b) is a diagram showing an example of a program for reading out the data shown in FIG. 12 (b). It is a figure which shows the program example which shows the other embodiment different from the program example shown in FIG. 13A. (A) shows an example of a conventional counter program, (b) shows an example of a counter program according to the same embodiment, and (c) shows a program example when the counter program shown in (b) is made into a general-purpose module. Shown, (d) is a diagram showing an example of a program when calling the general-purpose modularized program shown in (c). (A) shows a program example of the table address of the subroutine that can be called by the CALL_S instruction, (b) shows a program example showing a part of the initialization process of the main control, and (c) shows (b). A program example of the CTC setting table is shown, (d) shows a program example of the data set processing shown in (b), (e) shows a program example of the command transmission processing shown in (b), and (f) shows a program example of the command transmission processing shown in (b). It is a figure which shows the program example of the main loop processing of a main control. (A) is a timing chart diagram showing the case where the number of start-holding balls is subtracted from 1 to 0, and the case where the customer waiting demo command is not missing, (b) is the start-holding number of balls of 1. A timing chart diagram showing a case where the number is subtracted from 0 and the customer waiting demo command is missing, and (c) is a timing chart diagram showing a lamp effect different from the lamp effect shown in (b). be. (A) is a timing chart diagram showing the case where the number of start-holding balls is subtracted from 1 to 0 and the symbol stop command is not missing, and (b) is the start-holding number of balls from 1. A timing chart diagram showing a case where the number is subtracted to 0 and a case where the symbol stop command is missing, (c) is a timing chart diagram showing a lamp effect different from the lamp effect shown in (b). (A-1) to (a-2) show screen examples of stopping from a state in which the special symbol fluctuates at high speed in a state where three start-holding balls are held, and (a-3) shows a start-holding. An example of a screen in which an animation of subtracting the number of balls from 3 to 2 is executed is shown, and (a-4) is a screen in which a special symbol fluctuates at high speed while the number of balls held for starting is 2 An example is shown, (a-5) shows a screen example when the start hold subtraction command for subtracting the number of start hold balls from 3 to 2 is missing, and (b-1) to (b-2) are start. A screen example is shown in which the special symbol stops from a state where the special symbol fluctuates at high speed in a state where the start hold subtraction command for subtracting the number of reserved balls from 3 to 2 is missing. An example of a screen in which an animation of subtracting one from one is executed is shown, (b-4) shows an example of a screen in which one starting reserved ball is held, and (c-1) to (c-2). ) Shows an example of a screen in which the number of start-holding balls is subtracted from 3 to 2, and the special symbol is stopped from a state where the special symbol is fluctuating at high speed in a state where the start-holding subtraction command is missing. An example of a screen in which two numbers are held is shown, (c-4) shows an example of a screen in which an animation in which the number of balls held for starting is subtracted from two is executed, and (c-5) shows a screen example in which starting is held. It is a figure which shows the screen example which one sphere is held. (A) is an explanatory diagram showing the data arrangement of the game ROM according to the same embodiment, and (b) is an explanatory diagram showing the data arrangement of the game ROM data arrangement different from the data arrangement shown in (a). (A) shows the data arrangement of the conventional game ROM, and (b) is explanatory drawing which shows the case where the use area of the CG data storage area is reduced in the data arrangement of the game ROM shown in (a). It is explanatory drawing when the sound data stored in the sound data storage area of the game ROM which concerns on this embodiment is transferred to a sound RAM. (A) shows the data arrangement when the control program storage area is added to the game ROM according to the same embodiment in addition to the data arrangement shown in FIG. 20 (a), and (a) shows the data arrangement in the same embodiment. It is explanatory drawing which shows the data arrangement when the control program storage area is added in addition to the data arrangement shown in FIG. 20B to the game ROM. It is a flowchart explaining the main process of the main control which concerns on this embodiment. It is a flowchart explaining the continuation of the main process of the main control shown in FIG. It is a flowchart explaining the setting switching process shown in FIG. 24. It is a flowchart explaining the power source abnormality check process. 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 ordinary symbol processing shown in FIG. 28. It is a flowchart explaining the special symbol processing shown in FIG. 28. It is a flowchart explaining the start opening check process 1 (2) shown in FIG. It is a flowchart explaining the special symbol variation start processing shown in FIG. It is a flowchart explaining the hit determination process shown in FIG. 32. It is a figure which shows the program example of the hit determination table. It is a figure which shows the program example of the hit determination table when there is only one set value. It is a flowchart explaining the process during special symbol change shown in FIG. It is a flowchart explaining the process during the special symbol confirmation time shown in FIG. It is a flowchart explaining the LED management process shown in FIG. 28. It is a figure which shows the program example of the LED common output selection table. It is a flowchart explaining the process outside the use area shown in FIG. 28. It is a flowchart explaining the LED update process outside the use area shown in FIG. 40. It is a figure which shows the example of the program when the common data is output from different ports. (A) shows a normal symbol hit determination table used when executing a winning / failing lottery of ordinary symbols, and (b) shows a special symbol jackpot determination table used when executing a winning / failing lottery of special symbols. (C) is a figure which shows the special symbol small hit determination table used when executing the winning or failing lottery of a special symbol. It is a flowchart which shows the main process of the sub control which concerns on the same embodiment. It is a flowchart which shows the data analysis process shown in FIG. 44. It is a flowchart which shows the command reception process of the sub-control which concerns on the same embodiment. It is a flowchart which shows the timer interrupt processing of the sub control which concerns on the same embodiment. (A) is a flowchart for explaining an initial command list for moving images, (b) is a flowchart for explaining a stationary command list for moving images, and (c) is a flowchart for explaining a command list for still images. .. FIG. 3 is a flowchart illustrating a main control main process different from the main control main process shown in FIG. 24. It is a flowchart explaining the continuation of the main process of the main control shown in FIG. 49. FIG. 5 is a flowchart illustrating a main control timer interrupt process different from the main control timer interrupt process shown in FIG. 28. It is a flowchart explaining the LED management process shown in FIG. 51. (A) shows a program example of the LED common output selection table 0, and (a) is a figure which shows the program example of the LED common output selection table 1.

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 6.

<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 in 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, so that 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. 7) 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. 7), that is, the number of first start hold balls is displayed on the liquid crystal display device 41. .. When a game ball wins a special symbol 1 starting port 44 and is detected by the special symbol 1 starting port switch 44a (see FIG. 7), the number of balls on hold for the first start is incremented by 1 (+1). 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. 7) 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. 7), 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. 7). 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. 7). 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. 7), 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 (see FIG. 7) 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. 7), 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. 7) 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. An upper right general winning opening switch 48a1 (see FIG. 7) for detecting the passage of the game ball is provided inside the upper right general winning opening 48a, and an 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. 7) is provided, and a middle left general winning opening switch 48c1 (see FIG. 7) for detecting the passage of a game ball is provided inside the middle left general winning opening 48c. Inside the mouth 48d, a lower left general winning opening switch 48d1 (see FIG. 7) 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. 7) 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. 7). Therefore, the out port switch 49a (see FIG. 7) 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 the special symbol display device 50, and the other 7-segment display devices. 52a displays the special symbol 1, the special symbol 2, the number of reserved balls for starting the normal symbol, and the game state. 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 one special symbol 1 display device 50a is on the left side of the special symbol 1 display device 50a. A normal symbol display device 51 composed of LEDs is provided, and a round lamp 52b for notifying the number of rounds of the jackpot game and a right-handed notification lamp 52c for notifying right-handed hitting are further provided.

Further, an identification lamp device 50A showing identification information corresponding to the special symbol 1 and the special symbol 2 is provided on the upper end side of the left decoration 43b.

In this identification lamp device 50A, the first and second identification lamps 50Aa and 50Ab for notifying the player of information on the special symbol 1 and the special symbol 2 being changed or the hit loss of the special symbol 1 and the special symbol 2 being lost. have. The first identification lamp 50Aa corresponds to the special symbol 1, and the second identification lamp 50Ab corresponds to the special symbol 2. Then, when the special symbol 1 is changing, the first identification lamp 50Aa blinks, when the special symbol 1 hits, the first identification lamp 50Aa lights up, and when the special symbol 1 is lost, the first identification lamp 50Aa Turns off. Further, when the special symbol 2 is changing, the second identification lamp 50Ab blinks, when the special symbol 2 is a hit, the second identification lamp 50Ab is lit, and when the special symbol 2 is lost, the second identification lamp is a second identification lamp. 50Ab is turned off.

Although not shown, a plurality of game nails are arranged in the game area 40 of the game board 4, and a windmill 53 as a falling direction changing member of the game ball is arranged.

By the way, in the above description, when the launch handle 16 detects the same number of game balls as the game balls fired in the game area 40, the out port switch 49a (see FIG. 7) determines the total number of outs discharged. An example of detection is shown, but the present invention is not limited to this, and as shown in FIG. 6, a game ball detection device UR1 provided with a game ball detection switch UR1a may be provided on the ball guidance rail UR. That is, as shown in FIG. 6, the game ball YK launched toward the game area 40 by the launch handle 16 moves in the arrow Y1 direction along the ball guidance rail UR. Then, when the game ball YK moved in the direction of the arrow Y1 comes into contact with the game ball detection switch UR1a, the game ball detection device UR1 detects the game ball launched by the launch handle 16. Even in this way, the same number of game balls as the number of game balls launched into the game area 40 can be detected by the launch handle 16.

By the way, in providing the game ball detection device UR1 provided with such a game ball detection switch UR1a, the game ball YK launched toward the game area 40 by the launch handle 16 moves to the tip portion URa of the ball guidance rail UR. However, if it reaches the game area 40, there is no problem, but the momentum of the game ball YK launched toward the game area 40 by the launch handle 16 is weak, and the game ball YK moves in the direction of the arrow Y2 shown in FIG. When it falls and enters the ball guidance rail UR, the game ball YK reaches the game area 40 while moving in the directions of arrow Y3 and arrow Y4 shown in FIG. At this time, when the game ball YK that has entered the ball guidance rail UR contacts (collides) with the game ball detection device UR1, the game ball detection device UR1 misunderstands that the game ball YK has contacted the game ball detection switch UR1a, which is an error. May be detected.

Therefore, in the present embodiment, the upper side (right side in the drawing) of the game ball detection device UR1, that is, the portion located in the ball guidance rail UR is provided so that the game ball YK does not come into contact (collision) with the game ball detection device UR1. A protective wall UR2 is provided so as to cover it. As a result, the game ball YK that has entered the ball guidance rail UR does not come into contact (collision) with the game ball detection device UR1 but comes into contact (collision) with the protective wall UR2, so that erroneous detection can be prevented. ..

On the other hand, as a method of preventing erroneous detection, it is also possible to deal with it by program processing without providing the protective wall UR2. That is, after the game ball detection device UR1 detects that the game ball YK has come into contact with the game ball detection switch UR1a, a detection invalid period may be provided for a certain period (for example, 400 ms). Even in this way, when the game ball YK that has entered the ball guidance rail UR comes into contact (collision) with the game ball detection device UR1, there is a high possibility that the game ball YK will come into contact (collision) within the above detection invalid period. , False detection can be prevented. It is preferable that this fixed period (for example, 400 ms) is shorter than the interval (for example, 600 ms) of being launched into the game area 40 by the launch handle 16. Further, when some trouble occurs in the game ball detection device UR1, for example, when the game ball detection device UR1 continues to detect that the game ball YK has come into contact with the game ball detection switch UR1a for a section of 1000 ms, the game ball detection device It is also possible to notify the error on the assumption that some trouble has occurred in the UR1.

<Explanation of the appearance configuration on the back of the pachinko machine>
Thus, as shown in FIG. 4, a frame-shaped back mechanism plate 54 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 55 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 54, and further. A tank rail 56 for leading out a ball from the game ball storage tank 55 is provided.

A payout device 57 and a payout passage 58 are attached to the lower end of the inclination of the tank rail 56, 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 55 are paid out by the payout device 57 via the tank rail 56, and the game balls are paid out through the payout passage 58 to the upper tray 9 (not shown). (See Fig. 1).

Further, a transparent back cover 59 (see also FIG. 3) that is detachably attached to the back side of the game board YB is mounted substantially in the center of the back mechanism plate 54, and a sub is mounted in the back cover 59. A transparent sub-control board case 80a containing the control board 80 is detachably provided. A transparent main control board case 60a containing the main control board 60 is detachably provided below the sub control board case 80a, and a payout control board 70 is provided 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. 7. As shown in FIG. 7, 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.

<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. Display (performance display) of the contents related to the computer 600 and 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 generate a special gaming state advantageous to the player. It is mainly equipped with a measurement / setting display device 610 including a 7-segment display of probability setting contents, a RAM clear switch 620, and a setting key switch 630.

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. , The normal symbol display device 51, the 7-segment display device 52a, the round lamp 52b, and the right-handed notification lamp 52c 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 sub control board 80. 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 determined 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 ordinary 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, based on the measured number of prize balls and the total number of discharged game balls, describes the content (performance display) regarding the ratio of how many prize balls were awarded at the time of low accuracy. Output to the measurement / setting display device 610. As a result, the content (performance display) relating to the ratio of how many prize balls were awarded at the time of low accuracy is displayed on the measurement / setting display device 610.

Further, the measurement / setting display device 610 can display, for example, the setting contents of the probability of generating a special gaming state advantageous to the player in six stages of "1" to "6". .. Therefore, when changing such a setting content, when a dedicated key is inserted into the setting key switch 630 and turned on, the probability that the RAM clear switch 620 will generate a special gaming state advantageous to the player. The setting contents can be changed in 6 steps of, for example, "1" to "6" (for example, the setting "6" has the highest probability of generating a special gaming state advantageous to the player. , Setting "1" has the lowest probability of generating a special gaming state in favor of the player). Then, the setting change content is displayed on the measurement / setting display device 610, and when the setting change content is confirmed, the dot on the lower right side of the 7 segment lights up to indicate that the setting content has been confirmed. It has become.

To explain the measurement / setting display device 610 in more detail, the signals output from the LED drivers 611a to 611c are connected to the measurement / setting display device 610 as shown in FIG. The LED drivers 611a to 611c include a special symbol display device 50 (see FIG. 5), a normal symbol display device 51 (see FIG. 5), a 7-segment display device 52a, a round lamp 52b, a right-handed notification lamp 52c, and four 7-segments. Which of the measurement / setting display devices 610 composed of the above is selected to be turned on, and a signal is output. More specifically, the LED driver 611a receives the 8-bit data signal output from the one-chip microcomputer 600 shown in FIG. 7 as the 8-bit data signal 611a1 and receives the 4-bit first LED dynamic lighting common data signal 611a2. , Special symbol display device 50 (see FIG. 5), or ordinary symbol display device 51 (see FIG. 5), or 7-segment display device 52a (see FIG. 5), or round lamp 52b (see FIG. 5), or. , The right-handed notification lamp 52c (see FIG. 5) is output, and the 4-bit second LED dynamic lighting common data signal 611a3 is output to the measurement / setting display device 610. That is, the first LED dynamic lighting common data signal 611a2 output from the LED driver 611a is common data for selecting an LED that receives the first LED dynamic lighting data signal 611b2 output from the LED driver 611b described later. The 4-bit first LED dynamic lighting common data signal 611a2 includes a 1-bit first LED dynamic lighting common data first signal 611a2a, a 1-bit first LED dynamic lighting common data second signal 611a2b, and a 1-bit first LED dynamic. It is composed of a lighting common data third signal 611a2c and a 1-bit first LED dynamic lighting common data fourth signal 611a2d.

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

On the other hand, the LED driver 611b receives the 8-bit data signal output from the one-chip microcomputer 600 shown in FIG. 7 as the 8-bit data signal 611b1, and receives the first LED dynamic lighting data signal 611b2 as the special symbol display device 50 ( (See FIG. 5), or ordinary symbol display device 51 (see FIG. 5), 7-segment display device 52a (see FIG. 5), round lamp 52b (see FIG. 5), or right-handed notification lamp 52c (see FIG. 5). It is output to FIG. 5). As a result, the lottery result is displayed on the special symbol display device 50, the lottery result is displayed on the normal symbol display device 51, or the special symbol 1, the special symbol 2, or the normal symbol 2 is displayed on the 7-segment display device 52a. The number of balls on hold for starting the symbol and the game status are displayed, the number of rounds of the jackpot game is displayed on the round lamp 52b, or the right-handed notification is displayed on the right-handed notification lamp 52c. .. As shown in FIG. 8, damping resistors R53 to R46 are connected to the first LED dynamic lighting data signal 611b2, and a system generated by the system reset generation unit 1320 (see FIG. 7) is connected to the LED driver 611b. The reset signal RST is input. Further, a capacitor C40 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 output from the one-chip microcomputer 600 shown in FIG. 7 as the 8-bit data signal 611c1, and measures and sets the 8-bit second LED dynamic lighting data signal 611c2. It is output to the display device 610. As a result, when displaying the content (performance display) related to the ratio of how many prize balls were awarded at the time of low accuracy, the first measurement / setting display device 610A, the second measurement / setting display device 610B, and the third The contents will be displayed on all of the measurement / setting display device 610C and the fourth measurement / setting display device 610D. On the other hand, when the setting content of the probability of generating a special gaming state advantageous to the player is displayed, the setting content is displayed only on the first measurement / setting display device 610A. As shown in FIG. 8, damping resistors R3 to R10 are connected to the second LED dynamic lighting data signal 611c2, and the LED driver 611c is connected to the system generated by the system reset generation unit 1320 (see FIG. 7). The reset signal RST is input. Further, a capacitor C2 is provided between the wiring pattern of the voltage input to the LED driver 611c and the wiring pattern of the ground.

Thus, in this way, the measurement / setting display device 610 displays the content (performance display) relating to the ratio of how many prize balls were awarded at the time of low accuracy, and the probability of generating a special gaming state advantageous to the player. It will also be used to display the setting contents of.

On the other hand, the RAM clear switch 620 clears all the memory area of the main control RAM 600c (see FIG. 7) when the RAM clear switch 620 is pressed except when the dedicated key is inserted into the setting key switch 630 and turned on. Instead, only a part of the memory area is cleared. That is, as shown in FIG. 9A, in the main control RAM 600c, of the memory space addresses 0000H to 0200H, the memory space addresses 0000H to 0100H are work areas and the like during game processing such as lottery processing. The memory space addresses 0100H to 0110H in the normal RAM area 600ca used as the above, and the memory space addresses 0110H to 0130H in the unused area 600cc are usually used during game processing such as lottery processing. For stack area 600cc, memory space addresses 0130H to 0150H are unused areas 600cd, and memory space addresses 0150H to 0190H are the prize balls measured by the main control board 60, that is, the main control CPU 600. In the measurement RAM area 600ce that stores the total number of game balls fired in the game area 40 including the number and the number of non-winnings, the memory space addresses 0190H to 01E0H are unused areas 600cf and the memory space address 01E0H. Addresses 0200H are composed of 600 cg of a measurement stack area used when measuring 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.

Thus, in the main control RAM 600c configured in this way, when the RAM clear switch 620 is pressed, the measurement RAM area 600ce and the measurement stack area 600cg of the main control RAM 600c are not cleared, and the normal RAM area 600ca, normal The stack area 600cc is cleared. 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. In the present embodiment, when the RAM clear switch 620 is pressed, the normal RAM area 600ca and the normal stack area 600cc are cleared, but the present invention is not limited to this, and the unused areas 600cc and 600cd are used. Including, the memory space addresses 0000H to 0150H may be cleared.

Further, each area of the normal RAM area 600ca, the normal stack area 600cc, the measurement RAM area 600ce, and the measurement stack area 600cc is started from the address where the last digit starts from 0, and the normal RAM area 600ca and the normal stack are started. An unused area 600cc is provided between the area 600cc, an unused area 600cd is provided between the normal stack area 600cc and the measurement RAM area 600ce, and the measurement RAM area 600ce and the measurement stack area 600cc are further provided. By providing an unused area 600 cf between the and, the area is distinguished from each other. As a result, when the program goes out of control, other areas can be prevented from being affected.

On the other hand, as shown in FIG. 9B, in the main control ROM 600b, among the memory space addresses 8000H to A800H, the memory space addresses 8000H to 8B90H are programs used during game processing such as lottery processing. In the normal program area 600ba where is stored, the memory space addresses 8B90H to 9000H are used, and in the unused area 600bb, the memory space addresses 9000H to 9000H are used during game processing such as lottery processing. In the normal data area 600bc where data is stored, the memory space addresses 9A00H to 9C00H are in the unused area 600bd, and the memory space addresses 9C00H to A010H include the number of prize balls and the number of non-winners. In the measurement program area 600be in which the program used for measuring the total number of game balls fired in the game area 40 is stored, the memory space addresses A010H to A200H are in the unused area 600bf. The measurement data area in which the memory space addresses A200H to A320H store data used for measuring 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. At 600 bg, the memory space addresses A320H to A780H are unused areas 600 bh, and the memory space addresses A780H to A800H are composed of the vector table area 600bi. The vector table area 600bi stores the table address of the subroutine that can be called by the CALL_S instruction among the plurality of call instructions described later.

The main control RAM 600c configured in this way has the last digit of each area of the normal program area 600ba, the normal data area 600bc, the measurement program area 600be, the measurement data area 600bg, and the vector table area 600bi. Starting from an address starting from 0, an unused area 600bb is provided between the normal program area 600ba and the normal data area 600bc, and an unused area is provided between the normal data area 600bc and the measurement program area 600be. An unused area 600bf is provided between the measurement program area 600be and the measurement data area 600bg, and an unused area 600bh is further provided between the measurement data area 600bg and the vector table area 600bi. By providing it, it is possible to distinguish each area. As a result, when the program goes out of control, other areas can be prevented from being affected.

<Explanation of payout control board>
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 sub-control board>
The sub-control board 80 receives the effect control command DI_CMD from the main control board 60 (main control CPU 600a) to execute and control various effects, and also controls the display image displayed on the liquid crystal display device 41 with the sub-control CPU 800a. , A sub-one-chip microcomputer composed of a sub-control ROM 800b in which a control program describing a production control procedure and a production scenario table PR_TBL shown in FIG. 10 are stored, and a sub-control RAM 800c that functions as a work area, a buffer memory, or the like. It is equipped with 800. The sub-control CPU 800a is provided with a DMA controller 800a1 that transfers sound data stored in the game ROM 805, which will be described later, to the sound RAM 802.

Furthermore, the sub control board 80 is displayed on the liquid crystal display device 41 based on the instructions of the sound LSI 801 that generates a desired BGM and sound effect, the sound RAM 802 that functions as a work area, a buffer memory, and the like, and the sub one-chip microcomputer 800. DDR2 SDRAM 804 composed of VDP803 for generating the image data to be generated, a work area for decompressing the moving image compressed data, and a frame buffer area for temporarily storing the image data displayed on the liquid crystal display device 41, and still image compression. A game ROM 805 in which CG data of data and moving image compression data and sound data such as BGM and sound effects are stored in advance is installed. The still image is a so-called sprite image, and indicates a single image such as text data such as characters, a background image, or a special pattern. Further, the moving image means a set of a plurality of still images (for a plurality of frames) that change continuously, and the liquid crystal display device 41 continuously draws the plurality of still images for smooth operation. Is reproduced.

A decorative lamp board 90 on which a decorative lamp such as an LED lamp that exhibits a lamp effect is mounted is connected to the sub-control board 80 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 sub-control board 80, and the special symbol 1 and the special symbol 2 are changing, or the special symbol 1 and the special symbol 1 and the special symbol 1 are changed. The identification lamp device 50A for notifying the player of the hit loss information of 2 is connected, the setting button 15 capable of various settings is connected, and the liquid crystal display device 41 is connected. Needless to say, the decorative lamp substrate 90 is also equipped with decorative lamps arranged on the upper, left, right, and upper left movable accessories 43a to 43d.

Thus, the sub-control board 80 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 start. The sub-control CPU 800a receives the effect control command DI_CMD containing the basic information required for the number of reserved balls, the decorative pattern to be stopped based on the lottery result, and the like. Then, the sub-control CPU 800a 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 sub-control ROM 800b, and executes the determined effect pattern. The instruction control signal is temporarily stored in the sub control RAM 800c.

The sub-control CPU 800a transmits a control signal related to sound among the control signals for instructing execution of the effect pattern stored in the sub-control RAM 800c to the sound LSI 801. In response to this, the sound LSI 801 reads the sound data corresponding to the control signal from the game ROM 805 or the sound RAM 802, and outputs the sound data 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 sub-control CPU 800a transmits a control signal related to light among the control signals for instructing the execution of the effect pattern stored in the sub-control RAM 800c to the decorative lamp substrate 90. As a result, the decorative lamp substrate 90 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. ..

Then, the sub-control CPU 800a transmits a command list related to the image to the VDP 803 among the control signals for instructing the execution of the effect pattern stored in the sub-control RAM 800c. As a result, the VDP 803 generates image data so as to display an image based on the command list, and transmits the generated image data to the liquid crystal display device 41 to obtain an image corresponding to the above-determined effect pattern. It will be displayed on the liquid crystal display device 41.

Further, the sub-control CPU 800a transmits a control signal related to the movable accessory among the control signals for instructing the execution of the effect pattern stored in the sub-control RAM 800c to the movable accessory device 43. As a result, the movable accessory device 43 is movable in accordance with the above-determined effect pattern.

<Explanation of production scenario table>
Here, the effect scenario table PR_TBL stored in the sub-control ROM 800b will be described in detail with reference to FIG. As shown in FIG. 10A, the effect scenario table PR_TBL stores a plurality of effect scenario data PS_DATA corresponding to the effect patterns determined by the sub-control CPU 800a. In this effect scenario data PS_DATA, a plurality of 1-layer data PS_DATA1 which are data for each layer used when drawing image data to be displayed on the liquid crystal display device 41 are stored. As shown in FIG. 10B, the one-layer data PS_DATA1 shows the frame data PS_DATA10 for drawing 1 frame to 10 frames, the control code data PS_DATA11, and the position when the liquid crystal display device 41 displays the data. Coordinate data PS_DATA12, pixel calculation data PS_DATA13 such as image deformation, enlargement, reduction, and transparency, and enlargement / reduction data PS_DATA14 indicating image enlargement / reduction are stored. Furthermore, the sound data PS_DATA15 indicating the sound emitted from the speaker 17, the movable accessory data PS_DATA16 for moving the movable accessory device 43, and the decorative lamp such as the LED lamp that exhibits the lamp effect are turned on or turned on. The lamp data PS_DATA17 for turning off the lamp is stored.

Further, the control code data PS_DATA11 stores the address address of the sub-control ROM 800b in which the control table CH_TBL shown in FIG. 10C is stored, and the data of the contents shown in the address address is referred to. .. That is, as shown in FIG. 10C, the control table CH_TBL stores a plurality of character data CH_DATA, and the character data CH_DATA includes data PS_DATA110 indicating whether it is a still image or a moving image, and game ROM 805. The address data PS_DATA111 indicating the address address, the image size data PS_DATA112 indicating the image size, the button data PS_DATA113 indicating the validity / invalidity of the continuous hitting effect of the setting button 15 or the pressing effect of the effect button device 13, and the movable accessory device 43. The movable accessory timing data PS_DATA114, which indicates the timing at which the movement of the moving object is started, is stored. As a result, the control code data PS_DATA11 refers to one character data CH_DATA from the plurality of character data CH_DATA stored in the control table CH_TBL shown in FIG. 10 (c). The one-layer data PS_DATA1 stored in the production scenario data PS_DATA is stored in order from the one with the lowest priority, and a moving image is displayed at a position having the lowest priority from the control table CH_TBL shown in FIG. 10 (c). Control code data PS_DATA11 such that the indicated data PS_DATA110 is referred to is stored, and control code data such that the data PS_DATA110 indicating a still image is referred to from the control table CH_TBL shown in FIG. 10C at a position having a high priority. PS_DATA11 is stored.

<Explanation of VDP>
On the other hand, the VDP 803 that generates the image data to be displayed on the liquid crystal display device 41 is configured as shown in FIG.

As shown in FIG. 11, the VDP 803 includes an interface circuit (I / F) 8030 for the DDR2 SDRAM 804, an interface circuit (I / F) 8031 for the game ROM 805, and an interface circuit (I / F) for the sub-one-chip microcomputer 800. ) 8032 and is built-in. Further, the VDP 803 includes a system control register 8033 accessed from the sub one-chip microcomputer 800 (sub control CPU 800a) via the interface circuit (I / F) 8032, a command memory 8034 for storing the command list, and a command list. A command parser 8035 to analyze, a CG memory controller 8036 to control reading of data in the game ROM 805, a still image decoder 8037 to decode still image compressed data, a moving image decoder 8038 to decode moving image compressed data, and a still image decoder. The image decoded (expanded) by the 8037 and the video decoder 8038 is displayed on the geometry engine 8039, the built-in VRAM 8040, and the liquid crystal display device 41, which perform affine conversion and projection conversion such as enlargement / reduction / rotation / movement. Image data generated by the rendering engine 8041 to the rendering engine 8041 that generates the image data, the DDR2 SDRAM controller 8042 that controls the reading of the data in the DDR2 SDRAM 804 and the writing of the data into the DDR2 SDRAM 804, and the liquid crystal display device 41. It is composed of a display controller 8043 that controls the timing of displaying the data, and an LVDS transmission unit 8044 that transmits image data to the liquid crystal display device 41 in an LVDS (Low Voltage Differential Signaling) format.

The system control register 8033 is a register group in which the sub-one-chip microcomputer 800 (sub-control CPU 800a) writes instruction data for the VDP 803 and a register in which the sub-one-chip microcomputer 800 (sub-control CPU 800a) reads information indicating the operating state of the VDP 803. It is roughly divided into groups. As a result, the sub-one-chip microcomputer 800 (sub-control CPU 800a) operates the VDP 803 appropriately by writing the required set value to the predetermined input register, and operates the VDP 803 by referring to the value of the required output register. It becomes possible to grasp the state.

On the other hand, the command memory 8034 stores a command list, and this command list is transmitted from the sub-one chip microcomputer 800 (sub-control CPU 800a) via the interface circuit (I / F) 8032. .. More specifically, the sub-one-chip microcomputer 800 (sub-control CPU 800a) stores in advance an effect pattern corresponding to the effect control command DI_CMD received by the main control board 60 (main control CPU 600a) in the sub-control ROM 800b. It is determined by lottery from a large number of produced effect patterns, a command list is created based on the determined effect pattern, and the command list is transmitted to the command memory 8034 via the interface circuit (I / F) 8032. In response to this, the command memory 8034 stores the command list.

On the other hand, the command parser 8035 analyzes the command list stored in the command memory 8034, and the command list analysis executes the drawing operation every frame. That is, the still image decoder 8037 is stationary from the address address of the game ROM 805 shown in the address data PS_DATA111 (see FIG. 10C) by using the CG memory controller 8036 based on the analysis result of the command list by the command parser 8035. The image compressed data is read, and the read still image compressed data is decoded (decompressed). Then, the decoded still image data is temporarily stored in the built-in VRAM8040.

On the other hand, the video decoder 8038 uses the CG memory controller 8036 to compress the video from the address address of the game ROM 805 shown in the address data PS_DATA111 (see FIG. 10C) based on the analysis result of the command list by the command parser 8035. The data is read, and the read video compressed data is decoded (decompressed). Then, the decoded moving image data is temporarily stored in the DDR2 SDRAM 804.

The still images and moving images (moving images for one frame) decoded in this way are the analysis results of the command list by the command parser 8035, that is, various data (frame data PS_DATA10, shown in FIG. 10B). Based on the coordinate data PS_DATA12, pixel calculation data PS_DATA13, scaling data PS_DATA14), the geometry engine 8039 performs processing such as affine conversion such as enlargement / reduction / rotation / movement and projection conversion, and the processing is performed at rest. The image data is stored in the built-in VRAM8040, and the moving image data is stored in the DDR2 SDRAM 804.

Then, after that, the rendering engine 8041 functions, the moving image data stored in the DDR2 SDRAM 804 is read by the DDR2 SDRAM controller 8042, and the moving image data is drawn by the rendering engine 8041. Next, the still image data is read from the built-in VRAM 8040, and the still image data is drawn. As a result, the still image data is overwritten and drawn on the moving image data, so that the image data displayed on the liquid crystal display device 41 is generated. The generated image data is written in the frame buffer area in the DDR2 SDRAM 804 by the DDR2 SDRAM controller 8042.

Thus, the image data written in the frame buffer area is read from the DDR2 SDRAM controller 8042 by the display controller 8043 and transmitted to the liquid crystal display device 41 by the LVDS transmission unit 8044. As a result, the image data generated by the rendering engine 8041 is displayed on the liquid crystal display device 41.

By the way, the image data displayed on the liquid crystal display device 41 is updated every frame, but the figure is made so that the sub-one-chip microcomputer 800 (sub-control CPU 800a) can grasp that the display operation of this one frame is completed. 7. The VSYNC (vertical synchronization signal) shown in FIG. 11 is transmitted from the VDP 803 to the sub-control CPU 800a as an interrupt signal. As a result, the sub-control CPU 800a can grasp that the image data for one frame is displayed on the liquid crystal display device 41. The VSYNC interrupt signal is generated every 33 ms, for example.

<Explanation of power supply board>
By the way, the power supply to each of the above-described boards is supplied from the power supply board 130 shown in FIG. 7. 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 RST when the power is turned on, and the generated system reset signal RST is output to each board.

<Explanation of data layout of main control ROM>
Here, among the main control ROM 600b described above, the data arrangement stored in the normal data area 600bc and the measurement data area 600bg will be described with reference to FIG.

Conventionally, since the data arrangement of the main control ROM 600b is configured in 1-byte units, the data arrangement includes unused bits among the 8 bits constituting 1 byte depending on the type of data. .. In this regard, the data arrangement of the fluctuation time data of the special symbol shown in FIG. 12A will be specifically described as an example.

It is assumed that the first fluctuation time of 10 seconds, the second fluctuation time of 30 seconds, the third fluctuation time of 50 seconds, and the fourth fluctuation time of 120 seconds exist as the fluctuation time data of the special symbol. At this time, 10 seconds is 10000 milliseconds, and as will be described later, if a timer interrupt occurs periodically every 4 ms, it will be counted as 1, so 10000/4 = 2500. If this is converted into a hexadecimal number, 09C4H It becomes. Then, when calculated in this way, 30 seconds is 1D4CH, 50 seconds is 30D4H, and 120 seconds is 7530H.

Thus, the first variation time data corresponding to 10 seconds is 09C4H, which is "0000 1001 1100 0100" in binary, and as shown in FIG. 12A, the normal data area of the main control ROM 600b. In the conventional data arrangement of the variable time data at 600 bc, the lower 8 bits "1100 0100" are arranged at the memory space address 9000H, and the upper 8 bits "0000 1001" are arranged at the next memory space address 9001H. Will be placed.

Next, the second fluctuation time data corresponding to 30 seconds is 1D4CH, which is "0001 1101 0100 1100" in binary, and as shown in FIG. 12A, the normal data area of the main control ROM 600b. In the conventional data arrangement of the variable time data at 600 bc, the lower 8 bits "0100 1100" are arranged at the memory space address 9002H, and the upper 8 bits "0001 1101" are arranged at the next memory space address 9003H. Will be placed.

Next, the third variation time data corresponding to 50 seconds is 30D4H, and when converted into a binary number, it becomes "00110000 1101 0100", and as shown in FIG. 12A, the normal data area of the main control ROM 600b. In the conventional data arrangement of the variable time data at 600 bc, the lower 8 bits "110100" are arranged at the memory space address 9004H, and the upper 8 bits "00110000" are arranged at the next memory space address 9005H. Will be placed.

Next, the fourth variation time data corresponding to 120 seconds is 7530H, which is "0111 0101 00110000" in binary, and as shown in FIG. 12A, the normal data area of the main control ROM 600b. In the conventional data arrangement of the variable time data at 600 bc, the lower 8 bits "00110000" are arranged at the memory space address 9006H, and the upper 8 bits "0111 0101" are arranged at the next memory space address 9007H. Will be placed.

Thus, in the conventional data arrangement of the variable time data, the data is arranged for each memory space address address.

However, in such a data arrangement, the first fluctuation time of 10 seconds, the second fluctuation time of 30 seconds, the third fluctuation time of 50 seconds, and the fourth fluctuation time of 120 seconds are all in the most significant bit. Since a certain 16th bit is "0", a useless 1 bit is stored in the memory as shown in FIG. 12 (a) even though only 15 bits are normally required as the fluctuation time data. It is arranged at the 8th bit of the space address 9001H, the 8th bit of the memory space address 9003H, the 8th bit of the memory space address 9005H, and the 8th bit of the memory space address 9007H. Therefore, in the conventional data arrangement, there is a problem that the data arrangement of the main control ROM 600b cannot be performed efficiently, and therefore the data capacity of the main control ROM 600b cannot be reduced.

Therefore, in the present embodiment, in order to efficiently arrange the data of the main control ROM 600b, the data stored in the normal data area 600bc is arranged as shown in FIG. 12B.

That is, the first fluctuation time data corresponding to 10 seconds is 09C4H, and when the data for 15 bits to be used is represented by a binary number, it becomes "000 1001 1100 0100", as shown in FIG. 12 (b). , The lower 8 bits "1100 0100" are arranged at the memory space address 9000H, and the upper 7 bits "000 1001" are arranged at the next memory space address 9001H.

Next, the second fluctuation time data corresponding to 30 seconds is 1D4CH, and when the data for 15 bits to be used is represented by a binary number, it becomes "001 1101 0100 1100", as shown in FIG. 12 (b). , The lowest bit "0" of the lower 8 bits is arranged at the 8th bit of the memory space address 9001H, and the remaining 7 bits of the lower 8 bits "0100" are placed at the next memory space address 9002H. 110 ”is placed, the lowest bit“ 1 ”of the upper 7 bits is placed at the 8th bit of the memory space address 9002H, and the remaining of the upper 7 bits is placed at the next memory space address 9003H. The 6-bit "001 110" will be arranged.

Next, the third variation time data corresponding to 50 seconds is 30D4H, and when the data for 15 bits to be used is expressed in binary, it becomes "011 0000 1101 0100", as shown in FIG. 12 (b). , The lower 2 bits of the lower 8 bits "00" are arranged at the 8th and 7th bits of the memory space address 9003H, and the remaining 6 bits of the lower 8 bits are arranged at the next memory space address 9004H. "110101" is placed, and "00", which is the lower 2 bits of the upper 7 bits, is placed in the 8th and 7th bits of the memory space address 9004H, and the next memory space address 9005H is placed. The remaining 5 bits of the upper 7 bits, "01100", are arranged therein.

Next, the fourth variation time data corresponding to 120 seconds is 7530H, and when the data for 15 bits to be used is expressed in binary, it becomes "111 0101 00110000", as shown in FIG. 12 (b). , The lower 3 bits of the lower 8 bits "000" are arranged at the 8th to 6th bits of the memory space address 9005H, and the remaining 5 bits of the lower 8 bits are arranged at the next memory space address 9006H. "00110" is arranged, and "101" which is the lower 3 bits of the upper 7 bits is arranged in the 8th to 6th bits of the memory space address 9006H, and the next memory space address 9007H is arranged. The remaining 4 bits of the upper 7 bits, "1110", are arranged therein.

Thus, if the data is arranged across consecutive address addresses and the data is packed and arranged in this way, the 8th to 5th bits of the memory space address 9007H are free areas. Therefore, it is possible to reduce the data capacity.

By the way, in arranging the data as shown in FIG. 12 (b), for example, a program as shown in FIG. 13 (a) is used. This program will be described below. This program is stored in the normal program area 600ba of the main control ROM 600b shown in FIG. 9B.

As shown in FIG. 13A, first, the memory space address address 9000H at the beginning of the normal data area 600bc (see FIG. 9B) for arranging data is defined (ORG 9000H), and the defined label is defined. Let it be D_HEDOUTIME.

Next, the storage size is declared to be 15 bits (START EQU SIZE {15}), data 09C4H corresponding to the first fluctuation time of 10 seconds, data 1D4CH corresponding to the second fluctuation time of 30 seconds, 50 seconds. The data 30D4H corresponding to the third fluctuation time of the above and the data 7530H corresponding to the fourth fluctuation time of 120 seconds are described, and it is declared that the data to be stored is 15 bits up to this point (END EQU SIZE). .. As a result, when the program is assembled and ROM data is created, the data described in the above program is stored in the normal data area 600 bc (see FIG. 9 (b)) as shown in FIG. 12 (b). I will go.

Thus, by arranging the data in which the size to be stored in the program is specified in this way, the data arrangement as shown in FIG. 12B is achieved. Although the data of 09C4H, 1D4CH, 30D4H, and 7530H are described in 16-bit format, since the storage size is declared to be 15 bits, when the program is assembled and the ROM data is created. , As shown in FIG. 12B, 15 bits of data are stored starting from address 9000H.

On the other hand, in acquiring the data stored in the normal data area 600bc (see FIG. 9B) of the main control ROM 600b, for example, a program as shown in FIG. 13B is used. This program will be described below. This program is stored in the normal program area 600ba of the main control ROM 600b shown in FIG. 9B.

First, as a process before the process of this program is started, a lottery for a special symbol variation pattern (special symbol variation time) is performed by the main control CPU 600a, and as a result of this lottery, a fourth variation time of 120 seconds is obtained. It is assumed that the variation pattern is selected and "04H" indicating the number of the selected variation pattern is stored in W_HENDOUNo shown in FIG. 13 (b).

As shown in FIG. 13B, first, the selected variation pattern number (“04H”) is acquired from W_HENDOUNo in which the selected variation pattern number (“04H”) is stored (LD A, (W_HENDOUNo) -1).

Next, the offset value is calculated by multiplying the decremented (-1) number (“03H”) from the acquired fluctuation pattern number by 15. (MUL A, 15).

Then, the offset value calculated above is incremented (+1) (INC A) in order to match the bit position to be called.

Next, 15 bits of data are set in the HL register from the address obtained by adding the offset value calculated above to the first address address (D_HENDOUTIME (9000H) shown in FIG. 13A) in which the fluctuation time is stored. (LD (15) HL, D_HENDOUTIME, A). As a result, the main control CPU 600a has 15 bits of data from the 46th bit of the offset value from the memory space address 9000H shown in FIG. 12B, that is, the memory space from the 6th bit of the memory space address 9005H. The data (111 0101 0011 0000) stored up to the 4th bit of the address 9007H will be set in the HL register. Thus, in this way, the fourth variation time data corresponding to 120 seconds is acquired from the normal data area 600bc (see FIG. 9B) of the main control ROM 600b. The internal registers (A register, HL register, etc.) of the main control CPU 600a are configured in 1-byte units. Therefore, since the main control CPU 600a performs processing in 1-byte units according to the internal registers (A register, HL register, etc.) of the main control CPU 600a in the program, 15-bit data (111 0101 0011) is stored in the 2-byte HL register. When setting 0000), 0 is added to the most significant bit, and 16-bit data (0111 0101 0011 0000) is set in the 2-byte HL register. Therefore, the program can perform processing without worrying that the read data size is 15 bits.

By the way, in the present embodiment, only the normal data area 600 bc has been described as an example, but of course, the same data arrangement is possible even in the measurement data area 600 bb. Further, the normal data area 600 bc and the measurement data area 600 bg may be composed of only the data arrangement area described above, or may be divided into the data arrangement area described above and the conventional data arrangement area. It may be configured. In this way, it is possible to create a program according to the situation, and thus the optimum program processing becomes possible.

Further, in the present embodiment, the data arrangement of the fluctuation time data of the special symbol has been described as an example, but the present invention is not limited to this, and the distribution value of the fluctuation pattern, the distribution table data of the number of the selected fluctuation pattern, and the jackpot It can be applied to any data such as the distribution value of the type lottery, the distribution table data, and other set value data related to jackpot control.

On the other hand, in the present embodiment, an example of defining a 15-bit data size, that is, defining one data size is shown, but it is also possible to define different bit sizes for a plurality of data. .. In this regard, a program for defining the determination value of the variation pattern random number and the number data of the variation pattern selected at that time will be specifically described with reference to FIG.

As shown in FIG. 14, the memory space address address 9100H at the beginning of the normal data area 600bc (see FIG. 9B) where the data is arranged is defined (ORG 9100H), and the defined label is designated as D_HENDOUHANTEI.

Next, a declaration (START EQU SIZE {14,4}) is made to set the storage size to 14 bits and 4 bits. Then, when the fluctuation pattern random number is 0 to 255 (= 0100H-1), "0100H, 01H" indicating that the fluctuation pattern number 01H is selected is described, and the fluctuation pattern random number is 256 to 511 (= 0200H-1). ), “0200H, 02H” indicating that the fluctuation pattern number 02H is selected is described, and when the fluctuation pattern random number is 521-4999 (= 1388H-1), the fluctuation pattern number 04H is selected. "1388H, 04H" to be shown is described, and when the fluctuation pattern random number is 5000 to 10000 (= 2710H-1), "2710H, 08H" to indicate that the fluctuation pattern number 08H is selected is described, and the size to be stored is described. Declare that there is so much data to make 14 bits and 4 bits (END EQU SIZE). As a result, the main control CPU 600a stores 14-bit and 4-bit data in order from the memory space address address 9100H of the normal data area 600bc (see FIG. 9B). Although the data of 0100H, 0200H, 1388H, and 2710H are described in the 16-bit format, and the data of 01H, 02H, 04H, and 08H are described in the 8-bit format, the stored size is 14 bits and 4 bits. Since the declaration is made, the main control CPU 600a stores data for 14 bits and 4 bits starting from address 9100H.

Thus, different bit sizes can be defined for each of the plurality of data in this way.

<Explanation of counter update process>
Next, the update processing of random numbers such as ordinary symbols and special symbols used for the winning / failing lottery, which will be described later, and the update processing of counters such as common counters will be described with reference to FIG.

Conventionally, when updating a counter that circulates in a predetermined range in a program, it has been necessary to create a processing program that returns the counter to 0 when the predetermined range is exceeded. In this regard, a counter program for updating in the range of 0 to 99 shown in FIG. 15A will be specifically described as an example.

As shown in FIG. 15A, in the counter program of label M_INCEX, first, the counter is updated based on the specified upper limit value, that is, the value of the work of W_COUNTER is set in the A register (LD A, (LD A,). W_COUNTER)).

Then, the value of the A register is incremented (+1) (INC A).

Then, it is compared with 100 (CP 100), and if it exceeds 100, the A register is set to 0 (XOR A).

On the other hand, it is compared with 100 (CP 100), and if it does not exceed 100, it jumps to the label XXX (JRC, XXX). Then, in this label XXX, the updated count value is stored in the work of W_COUNTER (LD (W_COUNTER), A).

Thus, by repeating the above program, the count value is updated in the range of 0 to 99.

As described above, conventionally, when updating the counter that circulates from 0 to 99 in the program, it is necessary to set up a program for processing that returns to 0 when it exceeds 99 as described above.

However, in a program as described above, branch processing must always be performed using a comparison instruction, and there is a problem that the processing load of the program cannot be reduced and the program capacity cannot be reduced.

Therefore, in the present embodiment, a counter program that can update the counter that circulates in a predetermined range is assembled without branching by using the comparison instruction. In this regard, a counter program for updating in the range of 0 to 63 shown in FIG. 15B will be specifically described as an example. This counter program is stored in the normal program area 600ba and the measurement program area 600be of the main control ROM 600b shown in FIG. 9B.

As shown in FIG. 15B, in the counter program of label M_INCEX, first, the counter is updated based on the specified upper limit value, that is, the value of the work of W_COUNTER is set in the A register (LD A, (LD A,). W_COUNTER)).

Next, the value of the A register is incremented (+1), and the lower 6 bits are masked with "0011 1111" (AND A +, 0011 1111B).

Next, the updated count value is stored in the work of W_COUNTER (LD (W_COUNTER), A).

Thus, by repeating the above program, the count value is updated in the range of 0 to 63.

Therefore, if a program as described above is used, even if the count value is incremented (+1) from 63 (= 0011 1111) and becomes 64 (= 0100 0000), the value after addition is "0011 1111". By masking with "(AND A +, 0011 1111B), the count value becomes 0 (= 0000 0000). Therefore, not only when the value changes from 63 to 64 as in the program described above, but by always masking with "00111111", the branch processing using the comparison instruction in the program can be performed as in the conventional case. It is possible to update the counter that circulates in a predetermined range without providing it. As a result, the processing load of the program can be reduced and the program capacity can be reduced.

In the present embodiment, a count value having a total number of 64, that is, a total number of powers of 2, has been described as an example, but the above program can be applied to any count value. be. However, it is preferable to use it in a counter program that updates a count value in which the total number is composed of powers of 2. This is because mask processing is easy.

By the way, the counter program described above can also be used as a general-purpose module. This point will be specifically described with reference to FIGS. 15 (c) to 15 (d).

As shown in FIG. 15 (c), in the counter program of label M_INCEX, first, the counter is updated based on the specified upper limit value, that is, the value of the HL register is set in the A register (LD A, (HL). )).

Next, the value of the A register is incremented (+1) and masked with the value of the B register (AND A +, B).

Next, the updated count value is stored in the HL register (LD (HL), A).

Thus, the counter program of the label M_INCEX modularized as described above sets the value of the work of W_COUNTER in the HL register (LD HL, W_COUNTER) as shown in FIG. 15 (d), and "0011 1111". It can be used by reading the counter program of the label M_INCEX (CALL M_INCEX) after setting the value of to the B register.

Thus, by using the counter program described above as a general-purpose module, it is possible to use it when updating a plurality of count values.

<Explanation of call instructions>
Next, a call instruction relating to the table address of the subroutine that can be called by the CALL_S instruction stored in the vector table area 600bi of the main control ROM 600b shown in FIG. 9B will be described with reference to FIG. do.

In the present embodiment, a plurality of call instructions such as a CALL_S instruction, a CALL_M instruction, a CALL_L instruction, and a CALL instruction are provided as call instructions that can be executed by the main control CPU 600a. This CALL_S instruction is the smallest amount of program code data (for example, 1 byte) among a plurality of call instructions. Then, the subroutine called by the CALL_S instruction is called by using the storage number of the address data table stored in the vector table area 600bi of the main control ROM 600b shown in FIG. 9B. As shown in FIG. 16A, the address data table stores the start address data of the subroutine called by the CALL_S instruction such as data set processing (DW M_DTSET) and command transmission processing (DW M_CMDOUT) in 2 bytes. ing. It should be noted that this stored order becomes the storage number when it is called by the CALL_S instruction as it is. As a result, the program can use the name of the subroutine declared in this address data table without being aware of the storage number.

Then, as shown in FIG. 16B, the CALL_S instruction is used to call the process stored in such an address data table. More specifically, the program shown in FIG. 16B shows a part of the initialization process described later, and has a function of creating a pulse output having a fixed cycle provided inside the main control CPU 600a. The CTC (Counter Timer Circuit) setting table (D_CTCSET) having a time measurement function is set in the HL register (LD HL, D_CTCSET), and the data set processing (M_DTSET) is called by the CALL_S instruction. There is (CALL_S M_DTSET).

By the way, the CTC setting table stores the contents as shown in FIG. 16 (c). That is, the normal RAM area 600ca of the main control RAM 600c shown in FIG. 9A in which the first half portion (LOW W_CTC1 to 3) is set is shown, and the latter half portion (001H, 010H, 080H) is set in the normal RAM area 600ca. The end code indicating the end of the data set is stored, and finally, the end code indicating the end of the data set is stored (DB 0FFH).

On the other hand, in the data set processing, the processing as shown in FIG. 16D is performed. Specifically, first, after shifting the inside of the HL register to the A register, the HL register is incremented (+1) (LD A, (HL +)).

The A register is then compared to 0FFH to check if the dataset is finished (CP 0FFH).

Next, the upper address of the normal RAM area 600ca is set in the D register (LD D, 00H).

Next, the lower address of the normal RAM area 600ca read by the CTC setting table (D_CTCSET shown in FIG. 16C) is set in the E register (LDE, A).

Next, the value of the data to be set from the CTC setting table (D_CTCSET shown in FIG. 16C) is read into the A register (LDA, (HL +)).

Then, data is set in the work address set in the DE register (LD (DE), A), and the process returns to the first process of the data set process (JRM_DTSET).

Thus, in this way, the data set processing called by the CALL_S instruction is executed.

On the other hand, the program showing a part of the initialization process described later shown in FIG. 16B calls the data set process (M_DTSET) with the CALL_S command, and then displays the standby screen on the liquid crystal display device 41 (see FIG. 5). Set the standby screen display command (0BA01H) to be set in the DE register (LD DE, 0BA01H).

Next, the command transmission process (M_CMDOUT) is called by the CALL_S instruction (CALL_S M_CMDOUT). This command transmission process is performed as shown in FIG. 16 (e).

In particular,
LD A, D
OUT (CMDPORT), A
And output the high-order byte data of the command from the command port.

Then
LD B, 1000
WAIT:
DJNZ WAIT
And wait for a while until the sub-control CPU 800a receives the command data.

Then
LD A, E
OUT (CMDPORT), A
And output the low-order byte data of the command from the command port.

Thus, in this way, the command transmission process called by the CALL_S instruction is executed.

Then, in this way, the CALL_S instruction is used in the initialization process.

However, since the above program is just an example, the CALL_S instruction is used not only in the initialization process but also in the timer interrupt described later. That is, the command transmission process is not limited to the initialization process, and the command transmission is performed in various situations such as when the number of start holding balls executed by the timer interrupt process increases, when the special symbol changes, when the jackpot starts, and when an error occurs. Will be executed. Therefore, the CALL_S instruction is also used in the timer interrupt.

Therefore, as described in the above program, by making the highly versatile process a subroutine corresponding to the CALL_S instruction, it is possible to suppress an increase in the amount of data in the program. Therefore, the processing load of the program can be reduced and the program capacity can be reduced.

In addition, the command transmission process is executed in various situations such as when the number of start hold balls executed by the timer interrupt process increases, when the special symbol changes start, when the jackpot starts, and when an error occurs. , The rate at which the CALL_S instruction is used is higher in the rate used in the timer interrupt process than in the rate used from the initialization process to the main loop process in which the timer interrupt process is called. Therefore, it is possible to further reduce the processing load of the program and reduce the program capacity.

By the way, among the plurality of call instructions, the CALL_M instruction is used when calling a subroutine within a predetermined address address range. Specifically, it is used when calling each subroutine such as special symbol processing, normal symbol processing, and timer management processing executed by timer interrupt processing described later. Since the CALL_S instruction is used when calling a highly versatile subroutine, the CALL_M instruction is used for each subroutine executed in the timer interrupt process that is called only once. The amount of data in the program code of the CALL_M instruction differs depending on the address address of the subroutine to be called (for example, 2 bytes to 3 bytes).

On the other hand, among the plurality of call instructions, the CALL_L instruction sets the program counter (address of the program being executed) to the normal stack area 600cc of the main control RAM 600c shown in FIG. 9A for measurement when calling the subroutine. Not only is the value of the flag register saved in the stack area 600 cc, but also the value of the flag register is saved in the normal stack area 600 cc and the measurement stack area 600 cc of the main control RAM 600 c shown in FIG. 9 (a). Therefore, the CALL_L instruction is used when the value of the flag changes in the subroutine after holding the flag before calling the subroutine. The CALL_L instruction is composed of, for example, 2 bytes.

On the other hand, since the CALL instruction among the plurality of call instructions has no limitation on the address address of the subroutine to be called, it is mainly stored in the measurement program area 600be of the main control ROM 600b shown in FIG. 9B. It is used when calling a program used for measuring 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. That is, when calling the address address of the program used for measuring 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, it cannot be read by another call instruction. Since there is a possibility that a subroutine is placed at the address address, CALL is used when calling the program used to measure 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. The instruction is used. Note that the CALL_M command described above cannot call a program used to measure 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. Since the above-mentioned CALL_M instruction cannot be called by setting the address address of the subroutine in a 2-byte register such as the HL register, it is called by directly specifying the address address, but the value of the address address is limited. be. Therefore, since the CALL instruction has no limitation on the address address of the subroutine to be called, the CALL instruction calls the program used when measuring 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. be able to. The CALL instruction is composed of, for example, 4 bytes.

Here, an example of using the CALL_M instruction and the CALL instruction described above will be described by taking the program shown in FIG. 16F as an example. The program shown in FIG. 16F shows the main loop processing described later, and is stored in the measurement program area 600be of the main control ROM 600b shown in FIG. 9B after the interrupt prohibition processing (DI) is performed. Call the prize ball winning number management process 1 (M_SHOUKYU1) described later, which is a program used when measuring the total number of game balls fired in the game area 40 including the number of winning balls and the number of non-winning balls, with a CALL instruction. (CALL M_SHOUKYU1), various random number update processes (M_RANSU) described later, which are programs used during game processing such as lottery processing stored in the normal program area 600ba of the main control ROM 600b shown in FIG. 9B. The process of calling with the CALL_M instruction (CALL M_SHOUKYU1) and enabling interrupt (EI) is repeated.

Thus, the CALL_M and CALL instructions are used in this way.

As described above, the subroutine called by the CALL_M instruction and the subroutine called by the CALL_S instruction among the plurality of call instructions are stored in the normal program area 600ba of the main control ROM 600b shown in FIG. 9B. The subroutine called by the CALL instruction is stored in the measurement program area 600be of the main control ROM 600b shown in FIG. 9B. However, by using a plurality of call instructions properly according to the situation in this way, it is possible to reduce the processing load of the program and reduce the program capacity.

<Explanation of missing customer waiting demo command>
Next, when the sub-control CPU 800a cannot receive the effect control command DI_CMD, which is a customer waiting demo command transmitted from the main control board 60 (main control CPU 600a) (see FIG. 7), refer to FIG. I will explain it.

At the timing T1 shown in FIG. 17 (a), the start hold subtraction command (for example, B001H) in which the number of start hold balls is subtracted from 1 to 0 as the effect control command DI_CMD from the main control board 60 (main control CPU 600a). , The variation pattern command (for example, A001H) of the variation pattern (for example, loss pattern 1) of the decorative symbol (special symbol), and the symbol designation command (for example, BB01H) for designating the decoration symbol (special symbol) (for example, the loss pattern). ) Is transmitted to the sub-control CPU 800a. In response to this, the sub-control CPU 800a determines an 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 sub-control ROM 800b, and the determined effect. A control signal for instructing execution corresponding to a scenario in which an effect operation such as a pattern sound, light, or an image (video) is stored is temporarily stored in the sub-control RAM 800c.

Then, the sub-control CPU 800a relates to the sound among the control signals to be executed in response to the scenario in which the effect operation such as the sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. The control signal is transmitted to the sound LSI 801. In response to this, the sound LSI 801 reads the sound data corresponding to the control signal from the game ROM 805 or the sound RAM 802, and outputs the sound data to the speaker 17. As a result, the BGM corresponding to the above-determined effect pattern is emitted from the speaker 17. At this time, if the BGM has already been reproduced in the sound LSI 801 it will be reproduced as it is, and if the BGM has not been reproduced, it will be reproduced.

Further, the sub-control CPU 800a relates to light among the control signals to be executed in response to the scenario in which the effect operation such as the sound, light, and image (video) of the effect pattern stored in the sub-control RAM 800c is stored. A control signal is transmitted to the decorative lamp substrate 90. As a result, the decorative lamp substrate 90 controls to turn on or off the decorative lamp such as the LED lamp that produces the lamp effect effect, so that the variable lamp effect is executed.

Further, the sub-control CPU 800a is an image (of the control signals to be executed in response to a scenario in which the effect operation such as sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. The command list related to (video) is transmitted to VDP803. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41, so that the variable image is displayed on the liquid crystal. It will be displayed on the display device 41.

Next, at the timing T2 shown in FIG. 17A, a symbol stop command (for example, BF01H) for stopping the decorative symbol (special symbol) is sub-controlled by the main control board 60 (main control CPU 600a) as the effect control command DI_CMD. It is transmitted to the CPU 800a. In response to this, the sub-control CPU 800a temporarily stores in the sub-control RAM 800c a control signal instructing execution of the effect pattern for stopping the effect pattern determined at the timing T1 shown in FIG. 17 (a). As a result, the sub-control CPU 800a transmits a command list related to an image (video) to the VDP 803 among the control signals for instructing the execution of the effect pattern stored in the sub-control RAM 800c. In response to this, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41 to display a decorative pattern (decorative pattern (video). An image in which the fluctuation of the special symbol) has stopped is displayed on the liquid crystal display device 41. The BGM being reproduced by the sound LSI 801 is continuously reproduced as it is, and the variation lamp effect executed by the sub-control CPU 800a is continuously executed as it is.

Next, when the number of start-holding balls is 0 and the variation of the decorative symbol (special symbol) is in the standby state, the main control board 60 (main control CPU 600a) is at the timing T3 shown in FIG. 17 (a). ), A customer waiting demo command (for example, B401H) is transmitted to the sub-control CPU 800a as the effect control command DI_CMD. In response to this, the sub-control CPU 800a temporarily stores in the sub-control RAM 800c a control signal instructing execution of the effect pattern corresponding to the received effect control command DI_CMD (customer waiting demo command).

Then, the sub-control CPU 800a transmits a control signal related to sound among the control signals for instructing execution of the effect pattern stored in the sub-control RAM 800c to the sound LSI 801. In response to this, the sound LSI 801 fades out the volume of the BGM being reproduced and puts it in a mute state. As a result, BGM cannot be emitted from the speaker 17. The mute state means that the volume is "0" or the volume is difficult for the player to recognize.

Further, the sub-control CPU 800a transmits a control signal related to light among the control signals for instructing the execution of the effect pattern stored in the sub-control RAM 800c to the decorative lamp substrate 90. As a result, the decorative lamp substrate 90 controls to turn on or off the decorative lamp such as the LED lamp that produces the lamp effect effect, so that the customer waiting demonstration lamp effect is executed.

Further, the sub-control CPU 800a transmits a command list related to an image (video) to the VDP 803 among the control signals for instructing the execution of the effect pattern stored in the sub-control RAM 800c. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41 to generate a customer waiting demo movie. It will be displayed on the liquid crystal display device 41.

Thus, in this way, the game state shifts to the customer waiting demo state, triggered by the customer waiting demo command.

Of the three, 1) the volume of the BGM being played is faded out and muted, 2) the lamp effect for the customer waiting demo is executed, and 3) the customer waiting demo movie is displayed. At least one may be performed after a lapse of a predetermined time (for example, 60 seconds) after receiving the customer waiting demo command. In this way, the game ball wins a prize in the special symbol 1 starting port 44 (see FIG. 5) or the special symbol 2 starting port 45 (see FIG. 5) while the player is playing (special symbol 1 starting port). When the variable stop state continues for a long time without switching 44a (see FIG. 7) or the special symbol 2 start port switch 45a (see FIG. 7), at least one of the above 1) to 3) is rowed. If this is done, the player will be given the impression that the adjustment of the game nail (not shown) is bad, which will give the player an impression that it is disadvantageous for the game hall (hall) side. .. Therefore, as described above, by keeping a certain amount of time from the suspension of fluctuation, it is possible to prevent the player from giving a bad impression.

By the way, although the customer waiting demo command is transmitted from the main control board 60 (main control CPU 600a) as the effect control command DI_CMD, the customer waiting demo command cannot be received by the sub control CPU 800a due to the influence of noise or the like. That is, if it is missing, the game state cannot be changed to the customer waiting demo state. Therefore, conventionally, in order to notify that the gaming state cannot shift to the customer waiting demo state, an error display such as "command reception error" is displayed on the liquid crystal display device 41.

However, even if the customer waiting demo command cannot be received, if the subsequent command can be received, it can operate as a gaming machine, so if an error display such as "command reception error" is displayed, the player will be able to play the game. There was a problem that it became an obstacle and unnaturalness remained for the player.

Therefore, in the present embodiment, at the timing T3 shown in FIG. 17B, noise or the like is transmitted even though the customer waiting demo command is transmitted as the effect control command DI_CMD from the main control board 60 (main control CPU 600a). If the customer waiting demo command cannot be received by the sub-control CPU 800a, that is, if it is missing, the liquid crystal display device 41 is prevented from displaying a "command reception error". This makes it possible for the player not to feel unnatural.

However, that alone cannot notify the employees of the amusement park that an error has occurred. Therefore, in the present embodiment, instead of displaying a "command reception error" on the liquid crystal display device 41, the following processing is performed.

That is, assuming that the customer waiting demo command could not be received, the sound LSI 801 does not end the BGM reproduced from the beginning to the end as it is, but reproduces the BGM in a loop. Specifically, at the timing T1 shown in FIG. 17B, the number of start hold balls is subtracted from 1 to 0 as the effect control command DI_CMD from the main control board 60 (main control CPU 600a). A command (for example, B001H), a variation pattern of a decorative symbol (special symbol) (for example, a loss pattern 1), a variation pattern command (for example, A001H), and a symbol for designating a decorative symbol (special symbol) (for example, a loss pattern). A designated command (for example, BB01H) is transmitted to the sub-control CPU 800a. In response to this, the sub-control CPU 800a determines an 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 sub-control ROM 800b, and the determined effect. A control signal for instructing execution corresponding to a scenario in which an effect operation such as a pattern sound, light, or an image (video) is stored is temporarily stored in the sub-control RAM 800c. At this time, the sub-control CPU 800a is a sound among the control signals to be executed in response to the scenario in which the effect operation such as the sound, light, and image (video) of the effect pattern stored in the sub-control RAM 800c is stored. The control signal related to the above is transmitted to the sound LSI 801. In response to this, the sound LSI 801 loops the BGM regardless of the fluctuation time (for example, 120 seconds) of the decorative symbol (special symbol).

Further, at the timing T2 shown in FIG. 17B, a symbol stop command (for example, BF01H) for stopping the decorative symbol (special symbol) is subordinated as the effect control command DI_CMD from the main control board 60 (main control CPU 600a). It is transmitted to the control CPU 800a. In response to this, the sub-control CPU 800a temporarily stores in the sub-control RAM 800c a control signal instructing execution of the effect pattern for stopping the effect pattern determined at the timing T1 shown in FIG. 17 (b). At this time, the sound LSI 801 does not stop the BGM being loop-reproduced, but loop-reproduces the BGM as it is.

Thus, in this way, at the timing T3 shown in FIG. 17B, even if the customer waiting demo command cannot be received (missing), the BGM continues to be played back in a loop. Therefore, as the BGM continues to be played in a loop, even if the liquid crystal display device 41 does not display a "command reception error", a command reception error is sent to an employee of the amusement park who understands the error specifications. Can be notified that has occurred.

By the way, in a state where the customer waiting demo command cannot be received and the BGM continues to be played in a loop, a game ball wins a prize in the special symbol 1 starting port 44 (see FIG. 5) or the special symbol 2 starting port 45 (see FIG. 5). (Detected by the special symbol 1 start port switch 44a (see FIG. 7) or the special symbol 2 start port switch 45a (see FIG. 7)), the main control board 60 (main control) at the timing T4 shown in FIG. 17 (b). From the CPU 600a), as the effect control command DI_CMD, the variation pattern command (for example, A001H) of the variation pattern (for example, the loss pattern 1) of the decorative symbol (special symbol) and the designation (for example, the loss symbol) of the decoration symbol (special symbol) can be specified. The symbol designation command (for example, BB01H) to be executed is transmitted to the sub-control CPU 800a. In response to this, the sub-control CPU 800a determines an 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 sub-control ROM 800b, and the determined effect. A control signal for instructing execution corresponding to a scenario in which an effect operation such as a pattern sound, light, or an image (video) is stored is temporarily stored in the sub-control RAM 800c. At this time, the sub-control CPU 800a is a sound among the control signals to be executed in response to the scenario in which the effect operation such as the sound, light, and image (video) of the effect pattern stored in the sub-control RAM 800c is stored. The control signal related to the above is transmitted to the sound LSI 801. In response to this, the sound LSI 801 does not reproduce the new BGM, but reproduces the loop-reproduced BGM as it is. As a result, when shifting from the error state to the normal gaming state, the player can play the game without feeling uncomfortable.

On the other hand, at the timing T1 shown in FIG. 17B, a start hold subtraction command transmitted from the main control board 60 (main control CPU 600a) as an effect control command DI_CMD is used to subtract the number of start hold balls from 1 to 0. (For example, B001H), the variation pattern command (for example, A001H) of the variation pattern (for example, the loss pattern 1) of the decorative symbol (special symbol), and the symbol designation for specifying the decoration symbol (special symbol) (for example, the loss pattern). When a command (for example, BB01H) is received by the sub-control CPU 800a, it is executed in response to a scenario in which the effect operation such as sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. Among the control signals to be instructed, the control signal related to light is transmitted to the decorative lamp substrate 90. As a result, the decorative lamp substrate 90 controls to turn on or off the decorative lamp such as the LED lamp that produces the lamp effect, so that the decorative symbol (special symbol) is affected by the fluctuation time (for example, 120 seconds). Instead, the variable lamp effect will be executed in a loop.

Further, at the timing T2 shown in FIG. 17B, a symbol stop command (for example, BF01H) for stopping the decorative symbol (special symbol) transmitted as the effect control command DI_CMD from the main control board 60 (main control CPU 600a). Is received by the sub-control CPU 800a, among the control signals for instructing execution in response to a scenario in which the effect operation such as sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. , A control signal regarding light is transmitted to the decorative lamp substrate 90. As a result, the decorative lamp substrate 90 does not stop the variable lamp effect that is being executed in a loop, but is executed in a loop as it is.

Thus, in this way, even if the customer waiting demo command cannot be received (missing) at the timing T3 shown in FIG. 17B, the variable lamp effect continues to be executed in a loop. Therefore, by continuing to execute the variable lamp effect in a loop, employees of the amusement park who understand the error specifications without displaying a "command reception error" on the liquid crystal display device 41, etc. It is possible to notify that a command reception error has occurred. Furthermore, by continuing to play the BGM in a loop together, even if the employees of the amusement park do not notice that the BGM is in a loop state, the lamp for the customer waiting demonstration is not produced, and the lamp for fluctuation is used. By grasping that the production is executed in a loop by the employees of the game hall, it is possible to quickly find the game machine in the error state.

By the way, as the lamp effect, instead of executing the variable lamp effect as described above in a loop, as shown in FIG. 17 (c), the symbol stop lamp effect may be executed. That is, at the timing T2 shown in FIG. 17C, a symbol stop command (for example, BF01H) for stopping the decorative symbol (special symbol) transmitted as the effect control command DI_CMD from the main control board 60 (main control CPU 600a) is issued. When the sub-control CPU 800a receives the control signal, a control signal for instructing the execution of the effect pattern for stopping the effect pattern determined at the timing T1 shown in FIG. 17C is temporarily stored in the sub-control RAM 800c and sub-controlled. Among the control signals for instructing the execution of the effect pattern stored in the control RAM 800c, the control signal related to light is transmitted to the decorative lamp substrate 90. As a result, the decorative lamp substrate 90 executes the design stop lamp effect. This symbol stop lamp effect is a pattern in which the brightness of a decorative lamp such as an LED lamp that produces a lamp effect effect is lowered and looped is continued, or a pattern in which the decorative lamp is repeatedly turned on and off is continued. Is.

Even in this way, even if the customer waiting demo command cannot be received (missing) at the timing T3 shown in FIG. 17C, the symbol stop lamp effect will continue to be executed. Therefore, by continuing to execute the symbol stop lamp effect, even if the liquid crystal display device 41 does not display a "command reception error" or the like, it is possible to inform the employees of the amusement park who understand the error specifications. It is possible to notify that a command reception error has occurred. Furthermore, by continuing to play the BGM in a loop together, even if the employees of the amusement park do not notice that the BGM is in a loop state, it is not a lamp production for a customer waiting demonstration, and it is for stopping the design. By grasping that the lamp effect is being executed by the employees of the game hall, it is possible to quickly find the game machine in the error state.

By the way, in a state where the customer waiting demo command cannot be received and the variable lamp effect continues to be executed in a loop, the special symbol 1 start port 44 (see FIG. 5) or the special symbol 2 start port 45 (see FIG. 5). When the game ball wins a prize (detected by the special symbol 1 start port switch 44a (see FIG. 7) or the special symbol 2 start port switch 45a (see FIG. 7)), the main control is performed at the timing T4 shown in FIG. 17 (b). From the board 60 (main control CPU 600a), as the effect control command DI_CMD, the variation pattern command (for example, A001H) of the variation pattern (for example, loss pattern 1) of the decorative symbol (special symbol) and the decoration symbol (special symbol) are specified (for example). , A symbol designation command (for example, BB01H) for performing a lost symbol) is transmitted to the sub-control CPU 800a. In response to this, the sub-control CPU 800a determines an 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 sub-control ROM 800b, and the determined effect. A control signal for instructing execution corresponding to a scenario in which an effect operation such as a pattern sound, light, or an image (video) is stored is temporarily stored in the sub-control RAM 800c. At this time, the sub-control CPU 800a is an optical control signal among the control signals that are instructed to be executed in response to the scenario in which the effect operation such as the sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. A control signal relating to the above is transmitted to the decorative lamp substrate 90. In response to this, the decorative lamp substrate 90 does not stop the variable lamp effect that is being executed in a loop, but is executed in a loop as it is. As a result, when shifting from the error state to the normal gaming state, the player can play the game without feeling uncomfortable.

On the other hand, at the timing T1 shown in FIG. 17B, a start hold subtraction command transmitted from the main control board 60 (main control CPU 600a) as an effect control command DI_CMD is used to subtract the number of start hold balls from 1 to 0. (For example, B001H), the variation pattern command (for example, A001H) of the variation pattern (for example, the loss pattern 1) of the decorative symbol (special symbol), and the symbol designation for specifying the decoration symbol (special symbol) (for example, the loss pattern). When a command (for example, BB01H) is received by the sub-control CPU 800a, it is executed in response to a scenario in which an effect operation such as a sound, light, or an image (video) of an effect pattern stored in the sub-control RAM 800c is stored. Among the control signals to be instructed, a command list related to an image (video) is transmitted to the VDP 803. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41, so that the variable image is displayed on the liquid crystal. It will be displayed on the display device 41.

Further, at the timing T2 shown in FIG. 17B, a symbol stop command (for example, BF01H) for stopping the decorative symbol (special symbol) is subordinated as the effect control command DI_CMD from the main control board 60 (main control CPU 600a). It is transmitted to the control CPU 800a. In response to this, the sub-control CPU 800a temporarily stores in the sub-control RAM 800c a control signal instructing execution of the effect pattern for stopping the effect pattern determined at the timing T1 shown in FIG. 17 (b). At this time, the sub-control CPU 800a transmits a command list related to an image (video) to the VDP 803 among the control signals for instructing the execution of the effect pattern stored in the sub-control RAM 800c. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41 to obtain a decorative symbol (special symbol). The image in which the fluctuation of) has stopped is displayed on the liquid crystal display device 41. The image in which the variation of the decorative symbol (special symbol) has stopped is continuously displayed on the liquid crystal display device 41.

Thus, in this way, at the timing T3 shown in FIG. 17 (b), even if the customer waiting demo command cannot be received (missing), the image in which the variation of the decorative symbol (special symbol) has stopped is displayed on the liquid crystal display. It will continue to be displayed on the device 41. Therefore, by continuing to display the image in which the fluctuation of the decorative symbol (special symbol) has stopped, the game understands the error specifications without displaying a "command reception error" on the liquid crystal display device 41. It is possible to notify the employees of the field that a command reception error has occurred. Furthermore, by continuing the loop playback of both the BGM and / or the lamp effect, even if the employees of the amusement park do not notice that the BGM and / or the lamp effect is in the loop state, the customer waiting demo movie can be displayed. By grasping that the video that is not displayed and the fluctuation of the decorative symbol (special symbol) has stopped is continuously displayed, the employees of the amusement park can quickly find the gaming machine in the error state. ..

By the way, the special symbol 1 start port 44 (see FIG. 5) or the special symbol 2 start port 45 is displayed in a state where the customer waiting demo command cannot be received and the image in which the variation of the decorative symbol (special symbol) is stopped is continuously displayed. When the game ball wins a prize (detected by the special symbol 1 start port switch 44a (see FIG. 7) or the special symbol 2 start port switch 45a (see FIG. 7)), the timing shown in FIG. 17 (b) is shown. At T4, as the effect control command DI_CMD from the main control board 60 (main control CPU 600a), the variation pattern command (for example, A001H) of the variation pattern (for example, loss pattern 1) of the decorative symbol (special symbol) and the decorative symbol (special symbol) ) (For example, a lost symbol) is specified (for example, BB01H) is transmitted to the sub-control CPU 800a. In response to this, the sub-control CPU 800a determines an 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 sub-control ROM 800b, and the determined effect. A control signal for instructing execution corresponding to a scenario in which an effect operation such as a pattern sound, light, or an image (video) is stored is temporarily stored in the sub-control RAM 800c. At this time, the sub-control CPU 800a is an image of the control signals that are instructed to be executed in response to the scenario in which the effect operation such as the sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. A command list related to (video) is transmitted to VDP803. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41 to display a decorative symbol (special symbol). The variation image in which the variation of the decorative symbol (special symbol) is started from the image in which the variation of) is stopped is displayed on the liquid crystal display device 41. As a result, when shifting from the error state to the normal gaming state, the player can play the game without feeling uncomfortable.

<Explanation of missing symbol stop command>
Next, in the case where the customer waiting demo command as described above is not provided and the game state shifts to the customer waiting demo state triggered by the symbol stop command, the main control board 60 (main control CPU 600a) (FIG. A case where the effect control command DI_CMD, which is a symbol stop command transmitted from 7), cannot be received by the sub-control CPU 800a will be described with reference to FIG.

At the timing T10 shown in FIG. 18A, the start hold subtraction command (for example, B001H) in which the number of start hold balls is subtracted from 1 to 0 as the effect control command DI_CMD from the main control board 60 (main control CPU 600a). , The variation pattern command (for example, A001H) of the variation pattern (for example, loss pattern 1) of the decorative symbol (special symbol), and the symbol designation command (for example, BB01H) for designating the decoration symbol (special symbol) (for example, the loss pattern). ) Is transmitted to the sub-control CPU 800a. In response to this, the sub-control CPU 800a determines an 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 sub-control ROM 800b, and the determined effect. A control signal for instructing execution corresponding to a scenario in which an effect operation such as a pattern sound, light, or an image (video) is stored is temporarily stored in the sub-control RAM 800c.

Then, the sub-control CPU 800a relates to the sound among the control signals to be executed in response to the scenario in which the effect operation such as the sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. The control signal is transmitted to the sound LSI 801. In response to this, the sound LSI 801 reads the sound data corresponding to the control signal from the game ROM 805 or the sound RAM 802, and outputs the sound data to the speaker 17. As a result, the BGM corresponding to the above-determined effect pattern is emitted from the speaker 17. At this time, if the BGM has already been reproduced in the sound LSI 801 it will be reproduced as it is, and if the BGM has not been reproduced, it will be reproduced.

Further, the sub-control CPU 800a relates to light among the control signals to be executed in response to the scenario in which the effect operation such as the sound, light, and image (video) of the effect pattern stored in the sub-control RAM 800c is stored. A control signal is transmitted to the decorative lamp substrate 90. As a result, the decorative lamp substrate 90 controls to turn on or off the decorative lamp such as the LED lamp that produces the lamp effect effect, so that the variable lamp effect is executed.

Further, the sub-control CPU 800a is an image (of the control signals to be executed in response to a scenario in which the effect operation such as sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. The command list related to (video) is transmitted to VDP803. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41, so that the variable image is displayed on the liquid crystal. It will be displayed on the display device 41.

Next, at the timing T11 shown in FIG. 18A, a symbol stop command (for example, BF01H) for stopping the decorative symbol (special symbol) is sub-controlled by the main control board 60 (main control CPU 600a) as the effect control command DI_CMD. It is transmitted to the CPU 800a. In response to this, the sub-control CPU 800a temporarily stores in the sub-control RAM 800c a control signal instructing execution of the effect pattern for stopping the effect pattern determined at the timing T10 shown in FIG. 18A. As a result, the sub-control CPU 800a transmits a command list related to an image (video) to the VDP 803 among the control signals for instructing the execution of the effect pattern stored in the sub-control RAM 800c. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41 to obtain a decorative symbol (special symbol). The image in which the fluctuation of) has stopped is displayed on the liquid crystal display device 41. Further, the sub-control CPU 800a activates a timer for counting a predetermined time (for example, 30 seconds) by receiving a symbol stop command (for example, BF01H) for stopping the decorative symbol (special symbol). The BGM being reproduced by the sound LSI 801 is continuously reproduced as it is, and the variation lamp effect executed by the sub-control CPU 800a is continuously executed as it is.

Next, when the activated timer counts a predetermined time (for example, 30 seconds) (see timing T12 shown in FIG. 18A), a control signal instructing execution of an effect pattern for shifting the gaming state to the customer waiting demo state. Is temporarily stored in the sub-control RAM 800c.

Then, the sub-control CPU 800a transmits a control signal related to sound among the control signals for instructing execution of the effect pattern stored in the sub-control RAM 800c to the sound LSI 801. In response to this, the sound LSI 801 fades out the volume of the BGM being reproduced and puts it in a mute state. As a result, BGM cannot be emitted from the speaker 17. The mute state means that the volume is "0" or the volume is difficult for the player to recognize.

Further, the sub-control CPU 800a transmits a control signal related to light among the control signals for instructing the execution of the effect pattern stored in the sub-control RAM 800c to the decorative lamp substrate 90. As a result, the decorative lamp substrate 90 controls to turn on or off the decorative lamp such as the LED lamp that produces the lamp effect effect, so that the customer waiting demonstration lamp effect is executed.

Further, the sub-control CPU 800a transmits a command list related to an image (video) to the VDP 803 among the control signals for instructing the execution of the effect pattern stored in the sub-control RAM 800c. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41 to generate a customer waiting demo movie. It will be displayed on the liquid crystal display device 41.

Thus, when the timer is activated and the predetermined time is counted with the symbol stop command as a trigger, the game state shifts to the customer waiting demo state. After this timer is activated, the effect control command DI_CMD from the main control board 60 (main control CPU 600a) is a variation pattern command (for example, A001H) of the variation pattern (for example, loss pattern 1) of the decorative symbol (special symbol). However, when it is transmitted to the sub-control CPU 800a, this timer is initialized.

However, although the symbol stop command is transmitted from the main control board 60 (main control CPU 600a) as the effect control command DI_CMD, the sub control CPU 800a cannot receive the symbol stop command due to the influence of noise or the like, that is, If it is missing, the counter that counts a predetermined time (for example, 30 seconds) is not activated, so that the game state cannot be changed to the customer waiting demo state. Therefore, conventionally, in order to notify that the gaming state cannot shift to the customer waiting demo state, an error display such as "command reception error" is displayed on the liquid crystal display device 41.

However, even if the symbol stop command cannot be received, if the subsequent command can be received, the gaming machine can operate. Therefore, if an error display such as "command reception error" is displayed, the player is hindered from playing the game. Therefore, there was a problem that unnaturalness remained for the player.

Therefore, in the present embodiment, at the timing T11 shown in FIG. 18B, although the symbol stop command is transmitted as the effect control command DI_CMD from the main control board 60 (main control CPU 600a), noise or the like is generated. Due to the influence, when the symbol stop command cannot be received by the sub-control CPU 800a, that is, when it is missing, the liquid crystal display device 41 is prevented from displaying a "command reception error". This makes it possible for the player not to feel unnatural.

However, that alone cannot notify the employees of the amusement park that an error has occurred. Therefore, in the present embodiment, instead of displaying a "command reception error" on the liquid crystal display device 41, the following processing is performed. As shown in FIGS. 18 (b) and 18 (c), the loop playback of the BGM and the lamp effect is the same as the process when the above-mentioned customer waiting demo command cannot be received (missing). Will be omitted.

At the timing T10 shown in FIG. 18B, a start hold subtraction command (for example, a start hold subtraction command) transmitted from the main control board 60 (main control CPU 600a) as an effect control command DI_CMD to subtract the number of start hold balls from 1 to 0 (for example). , B001H), a variation pattern command (for example, A001H) of a variation pattern (for example, a loss pattern 1) of a decorative symbol (special symbol), and a symbol designation command (for example, a loss pattern) for designating a decorative symbol (special symbol). For example, when the sub-control CPU 800a receives the BB01H), the sub-control CPU 800a gives an execution instruction corresponding to a scenario in which the effect operation such as the sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. Among the control signals, a command list related to an image (video) is transmitted to the VDP 803. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41, so that the variable image is displayed on the liquid crystal. It will be displayed on the display device 41.

In this variation image, the variation of the decorative symbol (special symbol) is displayed, but since the variation time (for example, 120 seconds) of the decorative symbol (special symbol) is fixed, the determined variation time (for example, 120 seconds) is determined. , 120 seconds, etc.), the fluctuation of the decorative symbol (special symbol) will be swaying.

The fluctuation of the decorative symbol (special symbol) is stopped when the sub-control CPU 800a receives the symbol stop command (for example, BF01H). However, assuming that the symbol stop command (for example, BF01H) could not be received by the sub-control CPU 800a, the fluctuation of the decorative symbol (special symbol) is displayed on the liquid crystal display device 41 in a loop state. It becomes.

Thus, in this way, even if the symbol stop command cannot be received (missing) at the timing T11 shown in FIG. 18B, the image in which the decorative symbol (special symbol) is swaying and fluctuating is displayed on the liquid crystal display. It will be displayed on the device 41 in a loop state. Therefore, by continuing to display the image in which the decorative design (special design) is swaying and fluctuating in a loop state, the error specifications can be understood without displaying a "command reception error" on the liquid crystal display device 41. It is possible to notify the employees of the amusement park, etc., that a command reception error has occurred. Furthermore, by continuing the loop playback of both the BGM and / or the lamp effect, even if the employees of the amusement park do not notice that the BGM and / or the lamp effect is in the loop state, the customer waiting demo movie can be displayed. By grasping that the video that is not displayed and the decorative design (special design) is shaking and fluctuating continues to be displayed in a loop state, the game machine in the error state is quickly discovered. can do.

By the way, the special symbol 1 start port 44 (see FIG. 5) or the special symbol is displayed in a loop state in which the symbol stop demo command cannot be received and the image in which the decorative symbol (special symbol) is swaying and fluctuating is continuously displayed. 2 When the game ball wins a prize in the starting port 45 (see FIG. 5) (detected by the special symbol 1 starting port switch 44a (see FIG. 7) or the special symbol 2 starting port switch 45a (see FIG. 7)), FIG. 18 (b). At 13 o'clock of the timing shown in A symbol designation command (for example, BB01H) for designating a symbol (special symbol) (for example, a lost symbol) is transmitted to the sub-control CPU 800a. In response to this, the sub-control CPU 800a determines an 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 sub-control ROM 800b, and the determined effect. A control signal for instructing execution corresponding to a scenario in which an effect operation such as a pattern sound, light, or an image (video) is stored is temporarily stored in the sub-control RAM 800c. At this time, the sub-control CPU 800a is an image of the control signals that are instructed to be executed in response to the scenario in which the effect operation such as the sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. A command list related to (video) is transmitted to VDP803. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41, so that the variable image is displayed on the liquid crystal. It will be displayed on the display device 41. Therefore, although the image in which the decorative symbol (special symbol) is swaying and fluctuating continues to be displayed in a loop state, the fluctuation image is displayed on the liquid crystal display device 41 when the game ball wins a prize. As a result, when shifting from the error state to the normal gaming state, the player can play the game without a sense of discomfort.

Instead of displaying the image in which the decorative symbol (special symbol) is swaying and fluctuating on the liquid crystal display device 41 in a loop state, when the predetermined fluctuation time (for example, 120 seconds) is reached, the decorative symbol (special symbol) is displayed. The fluctuation of the symbol) may be stopped, and the identification lamp device 50A (see FIG. 5) may be blinked and displayed. Even in this way, even if the liquid crystal display device 41 does not display something like "command reception error", the employee of the amusement park who understands the error specifications is notified that the command reception error has occurred. It becomes possible. In this case, the liquid crystal display device 41 will continue to display the image of the stopped decorative symbol (special symbol).

By the way, in the present embodiment, the case where the BGM continues to play in a loop due to the inability to receive (miss) the customer waiting demo command or the symbol stop command is illustrated. If it is delayed to discover that the BGM is in the loop state, the BGM will continue to be looped for a long time. In this case, the player next to the gaming machine in the error state may feel this state unpleasant. Therefore, as a scenario of the variation pattern of the decorative symbol (special symbol), a process of stopping the BGM after the lapse of a predetermined time after the variation time ends may be added. Further, when the customer waiting demo command is transmitted after the symbol stop command, a process may be added to stop the BGM after a predetermined time has elapsed when the effect pattern corresponding to the symbol stop command is executed. Regarding the predetermined time, the time longer than the time from the end of the variable time to the transition from the symbol stop state to the customer waiting demo state (for example, 180 seconds), or after a certain time has elapsed from the reception of the customer waiting demo command. (For example, after 60 seconds), when the volume of the BGM being played is faded out and put into a mute state, an employee of the amusement park or the like may have a longer time (for example, 300 seconds) until the mute state is set. It is best to set the time sufficient for discovery and not to make the player next to the game machine in the error state feel uncomfortable. Further, as a scenario of the variation pattern of the decorative symbol (special symbol), when the BGM is stopped, the liquid crystal display device 41 may display "Mute". As a result, the player can be made to appear as if the player is simply informed that the sound is muted, and the employees of the game hall can be made to discover that the sound is muted due to an error. ..

<Explanation of missing start hold subtraction command>
Next, when the effect control command DI_CMD, which is a start hold subtraction command transmitted from the main control board 60 (main control CPU 600a) (see FIG. 7), cannot be received by the sub control CPU 800a, refer to FIG. I will explain it.

As shown in FIG. 19 (a-1), the liquid crystal display device 41 wins a prize in the special symbol 1 starting port 44 (see FIG. 5) or the special symbol 2 starting port 45 (see FIG. 5) (special symbol 1 starting port switch). A state in which three game balls held by 44a (see FIG. 7) or the special symbol 2 start port switch 45a (detected by the start port switch 45a (see FIG. 7)) are held as start hold balls is displayed (see image P1), and left and middle. , The decorative symbol (special symbol) displayed in the order on the right is displayed in a state of high-speed fluctuation (see image P2). Then, as shown in FIG. 17 (a-2), the fluctuation of the decorative symbol (special symbol) that fluctuates at high speed shown in the image P2 of FIG. 17 (a-1) is stopped (in the figure, the combination symbol is Stop in the state of losing "123") (see image P3). After that, as the effect control command DI_CMD from the main control board 60 (main control CPU 600a), the start hold subtraction command (for example, B003H) in which the number of start hold balls is subtracted from 3 to 2, and the decorative symbol (special symbol) A fluctuation pattern command (for example, A001H) for a fluctuation pattern (for example, a loss pattern 1) and a symbol designation command (for example, BB01H) for designating a decorative symbol (special symbol) (for example, a loss symbol) are transmitted to the sub-control CPU 800a. Will be done. In response to this, the sub-control CPU 800a determines an 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 sub-control ROM 800b, and the determined effect. A control signal for instructing execution corresponding to a scenario in which an effect operation such as a pattern sound, light, or an image (video) is stored is temporarily stored in the sub-control RAM 800c.

Then, the sub-control CPU 800a is an image (of the control signals to be executed in response to a scenario in which the effect operation such as sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. The command list related to (video) is transmitted to VDP803. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41, thereby causing the liquid crystal display device 41 to display the image (video) data. As shown in FIG. 19 (a-3), a decorative symbol (special symbol) fluctuating at high speed is displayed (see image P4), and the number of start-holding balls is erased from 3 to 1. An animation is displayed in which the number of start-holding balls is subtracted (see image P5), and as shown in FIG. 19 (a-4), a state in which two start-holding balls are held is displayed (image). (Refer to P6).

However, despite the fact that the main control board 60 (main control CPU 600a) has transmitted the start hold subtraction command (for example, B003H) as the effect control command DI_CMD, which reduces the number of start hold balls from 3 to 2. When the start hold subtraction command cannot be received by the sub control CPU 800a due to the influence of noise or the like, that is, when the sub control CPU 800a is missing, it is unknown that the number of start hold balls has been reduced from 3 to 2 in the sub control CPU 800a. As shown in FIG. 19 (a-5), a decorative symbol (special symbol) fluctuating at high speed is displayed (see image P4), and the state in which three start-holding balls are held is displayed as it is (see image P1). ) Will be done. That is, the number of start-holding balls actually held and the displayed number of start-holding balls do not match.

Then, as shown in FIG. 19 (b-1), the state in which three start-holding balls are held is continuously displayed (see image P1), and the decorative symbol (special symbol) fluctuating at high speed is changed. However, as shown in FIG. 19 (b-2), the pattern is stopped (in the figure, the combination symbol is stopped in a lost state of "123") (see image P7). After that, as the effect control command DI_CMD from the main control board 60 (main control CPU 600a), the start hold subtraction command (for example, B002H) in which the number of start hold balls is subtracted from two to one, and the decorative symbol (special symbol) A fluctuation pattern command (for example, A001H) for a fluctuation pattern (for example, a loss pattern 1) and a symbol designation command (for example, BB01H) for designating a decorative symbol (special symbol) (for example, a loss symbol) are transmitted to the sub-control CPU 800a. Will be done. In response to this, the sub-control CPU 800a determines an 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 sub-control ROM 800b, and the determined effect. A control signal for instructing execution corresponding to a scenario in which an effect operation such as a pattern sound, light, or an image (video) is stored is temporarily stored in the sub-control RAM 800c.

Then, the sub-control CPU 800a is an image (of the control signals to be executed in response to a scenario in which the effect operation such as sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. The command list related to (video) is transmitted to VDP803. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41, thereby causing the liquid crystal display device 41 to display the image (video) data. As shown in FIG. 19 (b-3), a decorative symbol (special symbol) fluctuating at high speed is displayed (see image P8), and the number of start-holding balls is erased from 3 to 2. An animation (see image P9) in which the number of start-holding balls to be reduced to one is subtracted is displayed. As a result, as shown in FIG. 19 (b-4), the liquid crystal display device 41 displays a state in which one of the start holding balls is held (see image P10). As a result, the number of start-holding balls actually held and the displayed number of start-holding balls match.

However, if the animation in which the number of start-holding balls is subtracted from 3 to 2 is erased to 1 in this way, the player feels very uncomfortable. Therefore, there was a problem that the game was continued while feeling unnatural. Further, there is a problem that it is necessary to separately prepare an animation in which the number of start-holding balls is subtracted so that the number of start-holding balls is erased from three to one.

Therefore, in the present embodiment, the following processing is performed in order to solve such a problem. That is, as shown in FIG. 19 (c-1), the state in which three start holding balls are held is continuously displayed (see image P1), and the decorative symbol (special symbol) fluctuating at high speed changes. , As shown in FIG. 19 (c-2), the stop (in the figure, the combination symbol is stopped in a lost state of "123") (see image P7). After that, as an effect control command DI_CMD from the main control board 60 (main control CPU 600a), a start hold subtraction command (for example, B002H) in which the number of start hold balls is subtracted from two to one, and a decorative symbol (of a special symbol). A fluctuation pattern command (for example, A001H) for a fluctuation pattern (for example, a loss pattern 1) and a symbol designation command (for example, BB01H) for designating a decorative symbol (special symbol) (for example, a loss symbol) are transmitted to the sub-control CPU 800a. Will be done. In response to this, the sub-control CPU 800a determines an 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 sub-control ROM 800b, and the determined effect. A control signal for instructing execution corresponding to a scenario in which an effect operation such as a pattern sound, light, or an image (video) is stored is temporarily stored in the sub-control RAM 800c.

Then, the sub-control CPU 800a is an image (of the control signals to be executed in response to a scenario in which the effect operation such as sound, light, or image (video) of the effect pattern stored in the sub-control RAM 800c is stored. The command list related to (video) is transmitted to VDP803. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41, thereby causing the liquid crystal display device 41 to display the image (video) data. As shown in FIG. 19 (c-3), a decorative symbol (special symbol) fluctuating at high speed is displayed (see image P8). Further, the liquid crystal display device 41 instantly displays a state in which two balls are held as the number of start-holding balls (see image P11). At this time, instead of displaying an animation on the liquid crystal display device 41 in which the number of start-holding balls is subtracted from three to one, and the number of start-holding balls is subtracted, three are held as start-holding balls. The display will be instantly switched from the state in which the display is on to the state in which two are held.

Then, from this state, an animation in which the number of start-holding balls is subtracted from two to one is erased to one, and as shown in FIG. 19 (c-4), the liquid crystal is displayed. The display device 41 displays an animation (see image P12) in which the number of start-holding balls is subtracted so that the number of start-holding balls is erased from two to one (see image P12). ), The state in which one ball is held as the number of balls held for starting is displayed (see image P13).

By doing so, the player is accustomed to instantly switching the display from the state in which the number of start-holding balls is held to 3 to the state in which 2 are held, and the number is subtracted from 2 to 1. Since the animation is displayed, it is possible to return to the start hold display in which the normal number of start hold balls is displayed without giving the player a great sense of discomfort. As a result, the player can continue the game without feeling unnatural. Further, it is not necessary to separately prepare an animation in which the number of start-holding balls is subtracted from the number of start-holding balls of 3 to 1 by erasing 2 pieces.

In the present embodiment, an example of transmitting a start hold subtraction command in which the number of start hold balls is subtracted from 3 to 2 or 2 to 1 is shown, but the present invention is not limited to this, and the start hold is simply held. A start hold command indicating the number of balls may be used (for example, B003H is used both when the number of start hold balls decreases from 3 to 2 and when the start hold ball number increases from 1 to 2. It can be a start hold command to be executed). That is, when the sub-control CPU 800a receives such a start hold command, the sub-control CPU 800a stores the number of start hold balls in the sub-control RAM 800c. As a result, for example, if a start hold command in which the number of start hold balls stored in the sub control RAM 800c is 3 and the number of start hold balls is 2 is received, the sub control CPU 800a has 1 start hold ball. It can be seen that the number has been subtracted. Therefore, the start hold command of 3 start hold balls and 2 start hold balls stored in the sub-control RAM 800c cannot be received, and the start hold command of 1 start hold ball is received. Even if it is done, since it is known that the subtraction has been made, the liquid crystal display device 41 will display the display as shown in FIGS. 19 (c-3) to (c-5).

On the other hand, although the start hold subtraction command (for example, B003H) for subtracting the number of start hold balls from 3 is transmitted, the start hold subtraction command is issued by the effect control CPU 900 due to the influence of noise and the like. It is also conceivable that a game ball enters (wins) the special symbol 1 starting port 44 or the special symbol 2 starting port 45 in a state where reception is not possible, that is, in a missing state. At this time, even if the start hold increase command (for example, B103H) in which the number of start hold balls is subtracted from 2 to 3 is transmitted, the displayed number of start hold balls does not change. Therefore, at this time, it is not necessary to perform the animation in which the number of reserved balls for starting is increased from two to three.

However, if the animation in which the number of reserved balls for starting is increased is not executed even though the game balls have entered (winned) in the special symbol 1 starting port 44 or the special symbol 2 starting port 45, the player is disadvantaged. You may feel that you have suffered. Therefore, in order to reduce such a situation, the display is instantly switched from the state in which 3 start-holding balls are held to the state in which 2 start-holding balls are held, and the number of start-holding balls increases from 2 to 3. You may want to display a familiar animation that is played.

<Explanation of game ROM>
Next, the game ROM 805 will be specifically described with reference to FIGS. 20 to 23.

As shown in FIG. 20A, when the game ROM 805 has, for example, a memory area of 10 Gbit, the memory areas include a CG data storage area 805a, a free area 805b, and a sound data storage area 805c. It is composed of. In the CG data storage area 805a, the CG data of the still image compressed data and the moving image compressed data are arranged and stored from the start address. Then, in the sound data storage area 805c, sound data such as BGM and sound effects are arranged and stored from an address address starting from a predetermined address address (in the figure, an address address of 6 Gbit).

Then, in the game ROM 805 in which the data is arranged in this way, the CG data (still image compressed data or the moving image compressed data) is read out by accessing the CG data storage area 805a in the VDP 803, and the sound is heard. By accessing the sound data storage area 805c in the LSI801, sound data such as BGM and sound effects can be read out.

By the way, when accessing the sound data storage area 805c, the sound LSI 801 accesses the address pointer by adding a predetermined address address (in the figure, an address address of 6 Gbit) as an offset value. Specifically, when reading the sound data "A" stored in the address address of 8 Gbit shown in FIG. 20 (a), the sound LSI 801 uses the address pointer as a predetermined address address (in the figure, the address address of 6 Gbit). Is added as an offset value, and the sound data "A" stored in the address address of 8 Gbit is read out. The predetermined address address (in the figure, the address address of 6 Gbit) is stored in the control program that describes the effect control procedure stored in the sub control ROM 800b or the control data referred to by the control program.

By the way, the reason why the free area 805b is provided between the CG data storage area 805a and the sound data storage area 805c is as follows.

That is, conventionally, like the game ROM 805 shown in the present embodiment, CG data of still image compressed data and moving image compressed data, and sound data such as BGM and sound effects are stored in advance in FIG. 21. The game ROM 8050 shown in the above is known. As shown in FIG. 21A, when the game ROM 8050 includes, for example, a memory area of 10 Gbit, the memory areas include a CG data storage area 8050a, a sound data storage area 8050b, and a free area 8050c. It is composed of ,. In the CG data storage area 8050a, the CG data of the still image compressed data and the moving image compressed data are arranged and stored from the start address. Then, in the sound data storage area 8050b, sound data such as BGM and sound effects are arranged and stored from an address address starting from a predetermined address address (in the figure, a 4 Gbit address address).

Here, during development, as shown in FIG. 21B, when the CG data storage area 8050a is changed from 4 Gbit to 3 Gbit, the start address address of the sound data storage area 8050b is changed from 4 Gbit to 3 Gbit. Will be done. Then, the address address of the sound data "A" stored in the 6 Gbit address address shown in FIG. 21 (a) is changed to the 5 Gbit address address as shown in FIG. 21 (b). It becomes. As a result, it is necessary to modify the program so that it matches this address address, and therefore, it is necessary to modify the program each time the used capacity of the CG data storage area 8050a is changed, which improves the efficiency of development. There was a problem that it would decrease.

Therefore, in the present embodiment, assuming that the used capacity of the CG data storage area 8050a is changed, a free area 805b is provided between the CG data storage area 805a and the sound data storage area 805c. .. As a result, even if the used capacity of the CG data storage area 805a is increased or decreased (see arrow Y1 shown in FIG. 20A), the address address of the sound data storage area 805c is not changed. Therefore, it is not necessary to modify the program each time the used capacity of the CG data storage area 805a is changed, and thus the efficiency of development can be improved. When the free area 805b is provided between the CG data storage area 805a and the sound data storage area 805c in this way, as described above, the sound LSI 801 can access the sound data storage area 805c when accessing the sound data storage area 805c. Access is performed by adding a predetermined address address (in the figure, a 6 Gbit address address) as an offset value to the address pointer.

On the other hand, even if the free area 805b is not provided between the CG data storage area 805a and the sound data storage area 805c, as shown in FIG. The sound data storage area 805c is provided so that the data is arranged, and the CG data of the still image compressed data and the moving image compressed data are arranged from the address address starting from the predetermined address address (in the figure, the address address of 4 Gbit). As described above, the CG data storage area 805a may be provided and then the free area 805b may be provided. In this way, if the sound data storage area 805c is provided in front of the CG data storage area 805a whose used capacity may be changed, the used capacity of the CG data storage area 805a is increased or decreased (in FIG. 20B). Even if the arrow Y2 is shown), the address address of the sound data storage area 805c is not changed. Even in this way, it is not necessary to modify the program each time the used capacity of the CG data storage area 805a is changed, and thus the efficiency of development can be improved. When the sound data storage area 805c is provided in front of the CG data storage area 805a whose used capacity may be changed, dummy data (dummy data (dummy data) so that the start address address of the CG data storage area 805a does not change. It is necessary to fix the used capacity of the sound data storage area 805c (4 Gbit in this embodiment) by using 00H) or the like.

By the way, when the CG data of the still image compressed data and the moving image compressed data and the sound data such as BGM and sound effects are stored in the game ROM 805, the CG data and the sound data cannot be accessed at the same time. There was a problem that the processing became inefficient.

Therefore, in the present embodiment, as shown in FIG. 22, the sound data stored in the sound data storage area 805c of the game ROM 805 is stored in a predetermined storage of the sound RAM 802 by using the DMA controller 800a1 (see FIG. 7). The data is transferred to the area 802a. In this way, the sound LSI 801 is stored in the predetermined storage area 802a of the sound RAM 802 while the VDP 803 is accessing the CG data storage area 805a of the game ROM 805 in order to acquire the CG data. The transferred sound data can be read out. As a result, the processing efficiency can be improved. Further, since the sound data stored in the sound data storage area 805c of the game ROM 805 is transferred to the predetermined storage area 802a of the sound RAM 802 using the DMA controller 800a1 (see FIG. 7), the data is in the middle of development. Even if a change occurs, it will be possible to flexibly respond to the data change.

By the way, the transfer by the DMA controller 800a1 (see FIG. 7) is instructed by the sub-control CPU 800a to the DMA controller 800a1 in the initial process executed when the power is turned on, and based on this, the DMA controller 800a1 performs one process. Therefore, all the sound data stored in the sound data storage area 805c of the game ROM 805 is transferred to the predetermined storage area 802a of the sound RAM 802. The sub-control CPU 800a performs initial processing during data transfer by the DMA controller 800a1. That is, the initial processing by the sub-control CPU 800a and the data transfer by the DMA controller 800a1 are performed in parallel. As a result, the processing efficiency can be further improved.

On the other hand, the DMA controller 800a1 (see FIG. 7) transfers all the sound data stored in the sound data storage area 805c of the game ROM 805 to the predetermined storage area 802a of the sound RAM 802, and then executes the refreshing process at a predetermined timing. Will be done. By doing so, the sound data stored in the predetermined storage area 802a of the sound RAM 802 can be kept normal.

By the way, in the transfer by the DMA controller 800a1 (see FIG. 7), all the sound data stored in the sound data storage area 805c of the game ROM 805 is stored in the sound data storage area 805c of the game ROM 805 in a predetermined storage area of the sound RAM 802 in the initial process executed when the power is turned on. It will be transferred in one process in 802a. However, when executing the refresh process, the sound data to be transferred is divided into a plurality of pieces, and the data transferred at one time is made smaller than the data transferred in the initial process and transferred over a plurality of times. Become. In this way, for example, when a VSYNC (vertical synchronization signal) indicating that one frame of image data has been displayed on the liquid crystal display device 41 is received, the next one frame of image data is displayed on the liquid crystal display. Sound data can be transferred before being drawn on the device 41. As a result, the refresh process can be executed while the sound LSI 801 is not accessing the predetermined storage area 802a of the sound RAM 802, so that the sound LSI 801 is accessing the predetermined storage area 802a of the sound RAM 802. It is possible to reduce the situation where the refresh process is executed.

By the way, when the sound LSI 801 mistakenly accesses the CG data storage area 805a when accessing the sound data storage area 805c, or when the VDP 803 mistakenly accesses the CG data storage area 805a, the sound data storage is mistakenly performed. When the area 805c is accessed, the sub-control CPU 800a can access the address address for error processing predetermined by the decoding error. At this time, the sub-control CPU 800a may execute error processing or infinite loop processing, and reset by a watchdog timer (WDT) (not shown). In this way, it is possible to prevent the image or sound effect from becoming abnormal by accessing unexpected data and reading incorrect data in advance.

In the present embodiment, an example of transferring the sound data stored in the sound data storage area 805c of the game ROM 805 to a predetermined storage area 802a of the sound RAM 802 using the DMA controller 800a1 has been shown. Not limited to this, the CG data stored in the CG data storage area 805a of the game ROM 805 may be transferred to a predetermined storage area of the DDR2 SDRAM 804 using the DMA controller 800a1.

Further, in the present embodiment, an example in which CG data of still image compressed data and moving image compressed data and sound data such as BGM and sound effects are stored in advance in the game ROM 805 is shown, but the present invention is not limited to this. , The control program describing the effect control procedure stored in the sub-control ROM 800b shown in FIG. 7 can also be stored in the control program storage area 805d as shown in FIG. 23. That is, as shown in FIGS. 23A and 23B, a control program storage area 805d is provided after the sound data storage area 805c so as to correspond to the change in the used capacity of the CG data storage area 805a described above, and the control program is provided. Should be memorized. At this time, the control program stored in the control program storage area 805d may be transferred to the sub-control RAM 800c by using the DMA controller 800a1 in the initial process executed when the power is turned on. In this case, it is preferable that the DMA controller 800a1 does not execute the refresh process. This is because the sub-control CPU 800a frequently accesses the sub-control RAM 800c, and there is not much period of non-access.

Further, in the present embodiment, one of the CG data of the still image compressed data and the moving image compressed data and the sound data such as BGM and sound effect is arranged from the start address address, but the present invention is not limited to the address 10 and the like. It may be arranged from a specific address. This is because there is a possibility that data different from CG data or sound data, such as ROM version information, may be placed at the start address.

<Main control: Program description>
Here, the program used during game processing such as lottery processing, which is stored in the normal program area 600ba of the main control ROM 600b shown in FIG. 9B described above, is stored in the measurement program area 600be of the main control ROM 600b. An outline of a program used for measuring 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 has been described with reference to FIGS. 24 to 43.

<Main control: 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. 7) is turned on to each control board is sent. In response to the signal, the main control CPU 600a (see FIG. 7) reads out the program stored in the normal program area 600ba of the main control ROM 600b shown in FIG. 9B, and the main control main process shown in FIG. 24. I do. At this time, the main control CPU 600a first sets itself in the interrupt disabled state (step S1).

Next, the main control CPU 600a performs a stack pointer setting process for setting the value of the stack pointer inside the main control CPU 600a corresponding to the final address of the normal stack area 600cc (see FIG. 9A) (step S2). ).

Next, the main control CPU 600a clears the watchdog timer (WDT) (not shown) built in the main control CPU 600a (step S3), and clears the output port that outputs the firing control signal (step S4).

Subsequently, the main control CPU 600a sets the startup waiting time of the sub control board 80 (step S5), decrements the set waiting time (-1) (step S6), and clears the watchdog timer (WDT) (not shown). (Step S7).

Next, the main control CPU 600a confirms whether or not the set waiting time has become "0" (step S8), and if it has not become "0" (step S8: ≠ 0), returns to the process of step S7. , If it is "0" (step S8: = 0), the process proceeds to step S9.

Next, the main control CPU 600a acquires the voltage abnormality signal ALARM (see FIG. 7) output from the power supply board 130 (voltage monitoring unit 1310) (see FIG. 7) 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 S9). Then, if the level of the voltage abnormality signal ALARM is "L" level (step S10: YES), the process returns to step S9, and if the level of the voltage abnormality signal ALARM is "H" level (step S10: NO), The process proceeds to step S11. 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 S9 to S10). By acquiring the voltage abnormality signal ALARM twice in this way, an accurate signal can be read.

Next, the main control CPU 600a permits data writing to the main control RAM 600c (step S11), and initially sets the work area of the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c (step S12). ). Specifically, 00H is set in the power supply abnormality confirmation counter, and 01H is set in the system operation status.

Next, the main control CPU 600a transmits a processing command (effect control command DI_CMD) that causes the liquid crystal display device 41 to display the standby screen on the sub control board 80 (step S13).

The setting process for transmitting the standby screen display command sets the standby screen display command (0BA01H) for displaying the standby screen on the liquid crystal display device 41 (see FIG. 5) shown in FIG. 16B in the DE register (see FIG. 5). LD DE, 0BA01H), the command transmission process (M_CMDOUT) is processed by a program called (CALL_S M_CMDOUT) with a CALL_S instruction.

Next, the main control CPU 600a clears the watchdog timer (WDT) (not shown) (step S14), 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 S14). Step S15). If the power-on signal has not arrived (step S15: OFF), the process returns to step S14, and if the power-on signal has arrived (step S15: ON), the process proceeds to step S16.

Next, the main control CPU 600a acquires the level data of the RAM clear switch 620 and the setting key switch 630, and saves the level data in the work area of the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c (step S16). ..

Next, as shown in FIG. 2, the main control CPU 600a includes a door opening signal indicating whether the upper opening / closing door 7 and the lower opening door 8 are open, and a normal RAM area 600ca of the main control RAM 600c (FIG. 9 (FIG. 9). The signal of the RAM clear switch 620 saved in the work area of (see a)) and the signal of the setting key switch 630 are acquired (step S17), and it is confirmed whether or not all of them are turned on (step S18). If all are ON (step S18: YES), the main control CPU 600a performs the setting switching process (step S19).

<Main control: Main processing: Explanation of setting switching processing>
Here, this setting switching process will be specifically described with reference to FIG.

First, the main control CPU 600a transmits a setting switching start command (effect control command DI_CMD) indicating that the setting is being changed to the sub control board 80 (step S50). The setting switching start command (effect control command DI_CMD) transmission process indicating that the setting is being changed is called by the CALL_S command and processed.

Next, the main control CPU 600a clears the backup flag (step S51). The backup flag 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 power supply abnormality check process shown in FIG. 27. Further, this backup flag is cleared in order to detect in step S21 shown in FIG. 25, which will be described later, when the main control RAM 600c is not backed up normally due to power failure due to some reason during the setting switching process. Is.

Next, the main control CPU 600a sets 02H to the system operation status (step S52), and sets a set value of the probability of generating a special gaming state advantageous to the player stored in the main control RAM 600c (see FIG. 7). Acquire and set in the W register (step S53). Specifically, when the set values are, for example, "1" to "6", in the program, the set values "1" to "6" are made to correspond to the values of "00H" to "05H". It will be set in the W register.

Next, the main control CPU 600a compares the value set in the W register with the set maximum value of the probability of generating a special gaming state advantageous to the player (for example, "05H" corresponding to "6") (step S54). .. Then, if the value set in the W register of the main control CPU 600a is larger than the maximum set value of the probability of generating a special gaming state advantageous to the player (for example, "05H" corresponding to "6") (step S55). : YES), it is determined that the value is abnormal, and 00H is set in the W register (step S56).

On the other hand, if the value set in the W register is smaller than the set maximum value of the probability of generating a special gaming state advantageous to the player (for example, "05H" corresponding to "6") (step S55: NO), it is a normal value. Is determined, and the process proceeds to step S57.

Next, the main control CPU 600a sets the security signal output to the hall computer (not shown) used for managing the game islands of the amusement park to ON via an external terminal (not shown), and displays the security signal. Output to a hall computer (not shown) via an external terminal (step S57).

Next, the main control CPU 600a sets 00H to the LED common port (step S58). As a result, "0" is output from the first LED dynamic lighting common data signal 611a2 and the second LED dynamic lighting common data signal 611a3 shown in FIG.

Next, the main control CPU 600a outputs the value set in the W register to the LED data port (step S59). As a result, the set value set in the W register is output from the second LED dynamic lighting data signal 611c2 shown in FIG. Actually, in order to display the set value corresponding to the value set in the W register on the first measurement / setting display device 610A of the measurement / setting display device 610 shown in FIG. Data will be output by the LED of. For example, when "00H" is set in the W register, LED data such that "0" is displayed on the first measurement / setting display device 610A of the measurement / setting display device 610 is output. Become.

Next, the main control CPU 600a sets the LED common port for displaying the set value to ON (step S60). As a result, "1" is output from the second LED dynamic lighting common data first signal 611a3a.

Thus, through such processing, the set value is displayed on the first measurement / setting display device 610A of the measurement / setting display device 610 shown in FIG. In this way, the capacity of the program can be reduced.

That is, when changing the setting before the timer interrupt processing described later, a program for creating a cycle for switching the common port is required. However, as described above, only the first measurement / setting display device 610A of the measurement / setting display device 610 is actually used, so that the LED data according to the set value can be displayed without switching the common port. I am trying to output. As a result, the capacity of the program can be reduced.

Next, the main control CPU 600a sets a predetermined value in the register in the main control CPU 600a so that a wait of 4 ms is applied, and performs a process of counting down (step S61). In this process, when confirming the change in the level data of the RAM clear switch 620 (see FIG. 7) and the setting key switch 630 (see FIG. 7), it is necessary to wait at least 4 ms from the acquisition of the previous switch level. This is a process for confirming that the level data is not changed due to irregularities such as noise. Furthermore, when checking the change in the voltage abnormality signal in the subsequent power supply abnormality check process and counting the power supply abnormality confirmation counter, the "L" level of the voltage abnormality signal becomes noise by waiting for 4 ms. It is also a process for confirming that the level data is not irregular.

Next, the main control CPU 600a performs a power supply abnormality check process (step S62). This power supply abnormality check process will be specifically described with reference to FIG. 27.

<Main control: Main processing: Explanation of power supply abnormality check processing>
As shown in FIG. 27, the main control CPU 600a acquires the voltage abnormality signal ALARM (see FIG. 7) output from the power supply board 130 (voltage monitoring unit 1310) (see FIG. 7) twice (step S80). It is confirmed whether or not the levels of the voltage abnormality signals ALARM acquired twice are the same (step S81). If they match (step S81: YES), the main control CPU 600a confirms the level of the voltage abnormality signal ALARM (step S82), and if they do not match (step S81: NO), the process returns to the process of step S80.

Next, if the level of the voltage abnormality signal ALARM is "H" level (step S82: OFF), the main control CPU 600a clears the power supply abnormality confirmation counter (step S83), and ends the power supply abnormality check process.

On the other hand, if the level of the voltage abnormality signal ALARM is "L" level (step S82: ON), the main control CPU 600a increments (+1) the power supply abnormality confirmation counter (step S84) and sets the value of the power supply abnormality confirmation counter. Confirm (step S85). If the value of the power supply abnormality confirmation counter is not 2 or more (step S85: NO), the power supply abnormality check process ends.

On the other hand, if the value of the power supply abnormality confirmation counter is 2 or more (step S85: YES), the main control CPU 600a transmits a power interruption command (effect control command DI_CMD) indicating that the power supply has been cut off to the sub control board 80. (Step S86). The power failure command (effect control command DI_CMD) transmission process indicating that the power supply has been cut off is called by the CALL_S command and processed.

Next, the main control CPU 600a confirms the value of the system operation status (step S87). If the value of the system operation status is 02H, it is determined that the setting change process is in progress (step S87: YES), the backup flag is not set to ON, and the process proceeds to step S89. In this way, it is possible to detect in step S21 shown in FIG. 25, which will be described later, when the main control RAM 600c is not normally backed up due to power failure due to some factor during the setting switching process.

On the other hand, if the value of the system operation status is not 02H, it is determined that the setting change process is not in progress (step S87: NO), and the backup flag is set to ON (step S88).

Next, the main control CPU 600a sets the data writing to the main control RAM 600c to the prohibited state (step S89), and clears the output data of all the output ports (step S90). Then, the timer interrupt is disabled (step S91), the infinite loop process is repeated, and the process of waiting for the voltage to drop is performed.

<Main control: Main processing: Explanation of setting switching processing>
Thus, when the power supply abnormality check process (step S62) is completed through the above processes, the main control CPU 600a is charged with the level data of the RAM clear switch 620 of the previous time and the present time, and the level data of the setting key switch 630. The switch edge data of the RAM clear switch 620 signal and the switch edge data of the setting key switch 630 signal are created (step S63). The main control CPU 600a stores the created edge data in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c.

Next, the main control CPU 600a confirms the edge data stored in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c, and if the setting key switch 630 is ON (step S64: NO). , Step S65, and if the setting key switch 630 is OFF (step S64: YES), the process proceeds to step S67.

Next, if the RAM clear switch 620 is ON (step S65: NO), the main control CPU 600a increments (+1) the value of the W register (step S66), and returns to the process of step S54.

On the other hand, if the RAM clear switch 620 is OFF (step S65: NO), the process returns to step S57.

Thus, the above process is repeated until the setting key switch 630 is turned off, and when the setting key switch 630 is turned off, the main control CPU 600a stores the value of the W register in the main control RAM 600c (see FIG. 7). It overwrites and stores the set value of the probability of generating a special gaming state advantageous to the player (for example, the set value of "00H" to "05H" corresponding to "1" to "6") (step). S67).

Next, the main control CPU 600a outputs a setting confirmation display to the LED data port (step S68). As a result, a value indicating the setting confirmation display is output from the second LED dynamic lighting data signal 611c2 shown in FIG. 8, and thus, the first measurement / setting display device 610A of the measurement / setting display device 610 shown in FIG. The dot on the lower right side of the 7-segment lights up, and it is displayed that the setting contents have been confirmed.

Next, the main control CPU 600a transmits a setting switching end command (effect control command DI_CMD) reflecting the set value to the sub control board 80 (step S69). The setting switching end command (effect control command DI_CMD) transmission process that reflects this set value is called by the CALL_S command and processed.

<Main control: Explanation of main processing>
Thus, when the setting switching process (step S19) shown in FIG. 24 is completed through the above processes, the main control CPU 600a proceeds to the process of step S26 shown in FIG. 25.

On the other hand, the main control CPU 600a confirms whether the signal of the RAM clear switch 620 and the signal of the setting key switch 630 are all ON (step S18), and if they are not all ON (step S18). : NO), the main control CPU 600a performs the process of step S20 shown in FIG.

That is, the main control CPU 600a corresponds to the set value (for example, "00H" corresponding to "1" to "6" of the probability of generating a special gaming state advantageous to the player stored in the main control RAM 600c (see FIG. 7). (The set value of "05H") is acquired, and it is confirmed whether or not it is equal to or less than the set maximum value (for example, "05H" corresponding to "6") (step S20). If it is equal to or less than the set maximum value (step S20: YES), it is confirmed whether or not the backup flag is set to ON (step S21).

<Main control: Main processing: Explanation of RAM error processing>
If it is not less than or equal to the set maximum value (step S20: NO), or if the backup flag is not set to ON (step S21: NO), the main control CPU 600a indicates to the sub control board 80 that a RAM error has occurred. An error command (effect control command DI_CMD) is transmitted (step S22). The RAM error command (effect control command DI_CMD) transmission processing indicating that this is a RAM error is called by the CALL_S instruction and processed.

Next, the main control CPU 600a outputs an error display to the LED data port (step S23). As a result, from the second LED dynamic lighting data signal 611c2 shown in FIG. 8, a value indicating an error (for example, LED data for displaying "E" on the first measurement / setting display device 610A of the measurement / setting display device 610). ) Is output, and a value (for example, “E”) indicating an error is displayed on the first measurement / setting display device 610A of the measurement / setting display device 610 shown in FIG.

Next, the main control CPU 600a performs a power supply abnormality check process (step S24), returns to the process of step S23, and repeats the process. The power supply abnormality check process is the same as the power supply abnormality check process shown in FIG. 27.

<Main control: Explanation of main processing>
On the other hand, if the backup flag is set to ON (step S21: YES), the signal of the RAM clear switch 620 is confirmed (step S25).

<Main control: Main processing: Explanation of RAM clear processing>
When the signal of the RAM clear switch 620 is ON (step S25: YES) or the setting switching process (step S19) shown in FIG. 24 is performed, the main control CPU 600a is the measurement RAM area 600ce of the main control RAM 600c (FIG. 9). (See (a)), the measurement stack area 600 cc (see FIG. 9 (a)) is not cleared, and the normal RAM area 600 ca of the main control RAM 600 c (see FIG. 9 (a)) and the normal stack area 600 cc (see FIG. 9). (See (a)) is cleared (step S26).

Next, the main control CPU 600a sets the RAM clear notification timer to 30 seconds (30s) (step S27), and a hall computer (not shown) used for managing the game islands of the game field via an external terminal (not shown). The timer for outputting the security signal output to is set to 30 seconds (30 s) (step S28).

Next, the main control CPU 600a sets initial values in a part of the main control RAM 600c (step S29), and proceeds to the process of step S41.

<Main control: Explanation of main processing>
On the other hand, if the signal of the RAM clear switch 620 is OFF (step S25: NO), the main control CPU 600a has the upper opening / closing door 7, the door opening signal indicating whether or not the lower opening door 8 is open, and the setting key. The signal of the switch 630 is acquired (step S30), and it is confirmed whether or not all the signals are turned on (step S31). If all are not turned on (step S31: NO), the process proceeds to step S40.

<Main control: Main processing: Explanation of setting confirmation processing>
On the other hand, if all are ON (step S31: YES), the main control CPU 600a transmits a set value command (effect control command DI_CMD) reflecting the set value to the sub control board 80 (step S32). The setting value command (effect control command DI_CMD) transmission process that reflects this set value is called by the CALL_S command and processed.

Next, the main control CPU 600a sets a timer for 30 seconds (30 s) to output a security signal output to a hall computer (not shown) used for managing the game islands of the game field via an external terminal (not shown). (Step S33).

Next, the main control CPU 600a sets the security signal output to the hall computer (not shown) used for managing the game islands of the amusement park to ON via an external terminal (not shown), and sets the security signal to ON via an external terminal (not shown). Then, a security signal is output to the hall computer (not shown) for 30 seconds (30 s) set by the timer (step S34).

Next, the main control CPU 600a outputs the set value to the LED data port (step S35). As a result, the set value is output from the second LED dynamic lighting data signal 611c2 shown in FIG. 8, and the set value is displayed on the first measurement / setting display device 610A of the measurement / setting display device 610 shown in FIG. Will be done.

Next, the main control CPU 600a sets a predetermined value in the register in the main control CPU 600a so that a wait of 4 ms is applied, and performs a process of counting down (step S36).

Next, the main control CPU 600a performs a power supply abnormality check process (step S37). The power supply abnormality check process is the same as the power supply abnormality check process shown in FIG. 27.

Next, the main control CPU 600a creates switch edge data of the setting key switch 630 signal from the level data of the setting key switch 630 of the previous time and the present time (step S38). The main control CPU 600a stores the created edge data in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c.

Next, the main control CPU 600a confirms the edge data stored in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c (step S39), and if the setting key switch 630 is ON (step). S39: NO), the process returns to step S34.

<Main control: Explanation of main processing>
On the other hand, if the setting key switch 630 is OFF (step S39: YES), initial values such as a backup flag and an error detection timer are set in a part of the main control RAM 600c (step S40).

Next, the main control CPU 600a transmits a command (effect control command DI_CMD) indicating whether to recover from the power failure by clearing the RAM or recovering from the power failure by backing up to the sub control board 80 (step S41). It should be noted that this command (effect control command DI_CMD) transmission process is processed by being called by the CALL_S command.

Next, the main control CPU 600a performs a game state notification information update process for updating the game state notification information (step S42).

Next, the main control CPU 600a sets the internal function register (step S43). Specifically, the launch control signal is set to ON and transmitted to the payout control board 70. As a result, the payout control board 70 controls to start the operation of the launch control board 71. In addition, a CTC (Counter Timer Circuit) having a function of creating a pulse output having a constant cycle, a function of measuring time, and the like provided inside the main control CPU 600a is set. 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.

The CTC setting process sets the CTC setting table (D_CTCSET) shown in FIG. 16B in the HL register (LD HL, D_CTCSET), and calls the data set process (M_DTSET) with the CALL_S instruction. It is processed by the program that is set to.

Next, the main control CPU 600a reads the program stored in the measurement program area 600be of the main control ROM 600b shown in FIG. 9B in a state (step S44) in which the interrupt to itself is set to the disabled state, and receives the prize. The process of the prize ball winning number management process 1 for calculating the performance such as the total number of game balls fired in the game area 40 including the number of balls and the number of non-winning balls is performed (step S45). Then, the main control CPU 600a performs various random number counter update processes based on the program stored in the normal program area 600ba of the main control ROM 600b shown in FIG. 9B, and then interrupts (step S46). After returning to the permitted state (step S47), the process returns to step S44, and a loop process is performed in which the processes of steps S44 to S47 are repeated.

It should be noted that the processes of steps S44 to S47 call the prize ball winning number management process 1 (M_SHOUKYU1) with the CALL instruction after performing the interrupt prohibition process (DI) shown in FIG. , Various random number update processes (M_RANSU) are called by the CALL_M instruction (CALL M_SHOUKYU1), and interrupt enable (EI) is repeatedly performed by the program.

Therefore, according to the present embodiment, when the power is turned on again after the power is cut off for some reason during the setting change, if the setting switching process (step S19) shown in FIG. 24 is not performed, steps S22 to S22 to step are performed. As shown in the process of S24, the RAM is abnormal, and only when the setting switching process (step S19) shown in FIG. 24 is performed, the game state is shifted to the normal game state. Further, as shown in step S57 shown in FIG. 26, a security signal is output from the external terminal during the setting change without monitoring the time during the setting change, and is shown in FIG. 25 after the setting change. As shown in steps S33 and S34, a security signal is output from the external terminal for a predetermined time by time monitoring. The reason why the time is not monitored during the setting change is that the time required for the setting change operation is indefinite depending on the operator. Therefore, if the time is monitored, the output of the security signal may stop even during the operation. This is because the processing load increases when a process is added to extend the monitoring time during operation.

Thus, in the past, when an abnormality occurs in the RAM value due to a power failure, there is a possibility that the setting value or the like may be affected by the game and the setting may be restarted from the changed state. However, if the processing as in the present embodiment is performed, the possibility that the game is restarted can be reduced while the possibility of affecting the game remains.

Further, in the process of the present embodiment, if the setting switching process (step S19) shown in FIG. 24 is not performed when the power is turned on again after the power is cut off for some reason during the setting change, steps S22 to step S In the power supply abnormality check process, the main control CPU 600a clears the output data of the output port, but does not set the backup flag to ON so that the RAM becomes abnormal as shown in the process of S24. When clearing the output data of the output port, the main control CPU 600a clears the output data of the output port (for example, LED data port or LED common port) used when changing the setting, and is also used when changing the setting. The output data of the output port that does not exist is also cleared.

In the present embodiment, the setting value of the probability of generating a special gaming state advantageous to the player (for example, the setting value of "00H" to "05H" corresponding to "1" to "6") is set in 6 steps. An example that can be changed is shown, but even if there is only one step of the set value (for example, the set value of "00H" corresponding to "1"), the setting change function as described above is provided for standardization of members and programs. You may do it. At this time, in the setting switching process shown in FIG. 26, even if the set value stored in the W register is incremented by 1 in step S66, the maximum set value becomes "00H" corresponding to "1", and the figure is always shown. In step S56 shown in 26, the process of setting the value of the W register to "00H" is performed. As a result, the setting change process can be executed by the same program as the program when there are a plurality of setting values. By doing so, even if the main control CPU 600a overwrites the set value stored in the main control RAM 600c (see FIG. 7) in step S67 shown in FIG. 26, the value becomes constant and fluctuates. There is nothing to do. This makes it possible to standardize members and programs.

<Main control: Explanation of timer interrupt processing>
Next, with reference to FIG. 28, a timer interrupt program that interrupts the above-mentioned main processing and is started every 4 ms will be described. This program reads and executes the program stored in the normal program area 600ba of the main control ROM 600b shown in FIG. 9B.

When this timer interrupt occurs, a save process is executed to save the contents of the register group in the main control CPU 600a to the normal stack area 600 cc (see FIG. 9A) of the main control RAM 600c (step S100), and then the voltage. The abnormality check process is executed (step S101). This voltage abnormality check process is the same process as the power supply abnormality check process shown in FIG. 27.

Next, the main control CPU 600a includes a special symbol 1 start port switch 44a (see FIG. 7), a special symbol 2 start port switch 45a (see FIG. 7), a normal symbol start port switch 47a (see FIG. 7), and a general upper right corner. Winning opening switch 48a1 (see Fig. 7), upper left general winning opening switch 48b1 (see Fig. 7), left middle general winning opening switch 48c1 (see Fig. 7), lower left general winning opening switch 48d1 (see Fig. 7), and out opening ON / OFF signals of various switches including the switch 49a (see FIG. 7) and the large winning opening switch 46c (see FIG. 7) are input, and the ON / OFF signal level and its rise are input to the work area in the main control RAM 600c. The state is stored (step S102).

Next, the main control CPU 600a performs timer subtraction processing of various timers (ordinary symbol variation timer, ordinary symbol accessory timer, etc.) that manage the time of each game operation (step S103).

Next, the main control CPU 600a performs a random number management process (step S104). Specifically, the process of updating random numbers such as ordinary symbols and special symbols used in the winning / failing lottery is performed. At this time, the counter program as shown in FIGS. 15 (b) to 15 (d) described above is executed.

Next, the main control CPU 600a performs an error management process (step S105). 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. 7), the special symbol 2 start port switch 45a (see FIG. 7), and the like. Normal symbol start port switch 47a (see FIG. 7), upper right general winning opening switch 48a1 (see FIG. 7), upper left general winning opening switch 48b1 (see FIG. 7), left middle general winning opening switch 48c1 (see FIG. 7), lower left It determines whether there is any abnormality inside the device such as disconnection of the general winning opening switch 48d1 (see FIG. 7), the out opening switch 49a (see FIG. 7), and the large winning opening switch 46c (see FIG. 7). be. When an error occurs, a command (effect control command DI_CMD) corresponding to the error is transmitted to the sub control board 80, and this command (effect control command DI_CMD) transmission process is called by the CALL_S command. Will be processed.

Next, the main control CPU 600a executes the prize ball management process (step S106). In this prize ball management process, the payout control command PAY_CMD for causing the payout control board 70 (see FIG. 7) to perform the payout operation is output.

Next, the main control CPU 600a executes the normal symbol processing (step S107). 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. The details of this process will be described later.

Next, the main control CPU 600a executes the normal electric accessory management process (step S108). In this ordinary electric accessory management process, a signal related to the control of the ordinary electric accessory solenoid 45c (see FIG. 7) required for generating the ordinary electric accessory opening game is generated based on the lottery result of the ordinary symbol processing (step S107). It is a thing.

Next, the main control CPU 600a executes a special symbol processing (step S109). 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. The details of this process will be described later.

Next, the main control CPU 600a executes the special electric accessory management process (step S110). 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. 7) is also generated. If the big hit lottery result is "big hit" or "small hit", a command related to it (effect control command DI_CMD) is transmitted to the sub control board 80. It should be noted that this command (effect control command DI_CMD) transmission process is processed by being called by the CALL_S command.

Next, the main control CPU 600a performs a right-handed notification information management process (step S111). In this right-handed notification information management process, right-handed situations are advantageous, such as when the opening / closing member 45b is opened a predetermined number of times for a predetermined time, or when the opening / closing door 46a is opened and the large winning opening (not shown) is opened. In, the process for displaying the "launch position guidance effect (right-handed notification effect)" that gives the right-handed instruction notification is performed. When the right-handed notification effect is performed, a command related to the right-handed notification effect (effect control command DI_CMD) is transmitted to the sub-control board 80 in this right-handed notification information management process. It should be noted that this command (effect control command DI_CMD) transmission process is processed by being called by the CALL_S command.

Next, the main control CPU 600a executes the LED management process (step S112). The details of this process will be described later.

Next, the main control CPU 600a executes the external terminal management process (step S113). In this external terminal management process, the hall computer (not shown) used for managing the game islands of the amusement park is provided with the number of hits during the game, the number of changes in the special symbol, the winning ball detection information to the winning opening, and so on. Predetermined game information such as security information is output from an external terminal (not shown).

Next, the main control CPU 600a performs a solenoid management process (step S114). At this time, the main control CPU 600a confirms the signal related to the control of the ordinary electric accessory solenoid 45c (see FIG. 7) generated in the ordinary electric accessory management process (step S108), and also confirms the special electric accessory management process (step S108). The signal related to the control of the special electric accessory solenoid 46b (see FIG. 7) generated in step S110) 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 performs out-of-use processing (step S115). The details of this process will be described later.

Next, the main control CPU 600a clears the watchdog timer (WDT) (not shown) (step S116), returns to the interrupt enabled state (step S117), and returns to the interrupt enabled state (step S117), and the normal stack area 600cc of the main control RAM 600c (see FIG. 9A). The contents of the register saved in are restored to end the timer interrupt (step S118). As a result, the interrupt processing routine returns to the main processing (see FIG. 24).

The voltage abnormality check process (step S101) to the out-of-use area process (step S115) executed by the timer interrupt process are called and processed by the CALL_M instruction.

<Main control: Explanation of normal symbol processing>
Next, with reference to FIG. 29, the above-mentioned ordinary symbol processing will be described in detail.

As shown in FIG. 29, in the normal symbol processing, first, it is confirmed whether or not the passage of the game ball is detected at the normal symbol start port 47 (see FIG. 5) composed of the gate, that is, the normal symbol start port 47 of the normal symbol start port 47. The signal level of the normal symbol start port switch 47a (see FIG. 7) is confirmed (step S150). When the passage of the game ball is detected (step S150: YES), the main control CPU 600a stores the number of start-holding balls of the normal symbol in order to determine whether or not the number of start-holding balls of the normal symbol is, for example, 4 or more. The normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c is confirmed (step S151). At that time, if the number of start-holding balls of the normal symbol is less than 4 (step S151: ≠ MAX), the number of start-holding balls of the normal symbol is added by 1 (step S152). After that, the main control CPU 600a uses the normal symbol hit determination random value used for the winning / failing lottery of the normal symbol as the normal RAM area 600ca of the main control RAM 600c in which the number of start-holding balls of the normal symbol is stored (FIG. 9A). After storing in (see) (see step S153), the process proceeds to step S154.

On the other hand, when the passage of the game ball is not detected in step S150 (step S150: NO), when it is determined in step S151 that the number of start-holding balls of the normal symbol is 4 or more (step S151: = In MAX), the processing of steps S152 to S153 is not performed, and the process proceeds to step S154.

When the main control CPU 600a proceeds to the process of step S154, it confirms whether the normal symbol per operation flag is set to ON, that is, whether 5AH is set to the normal symbol per operation flag (step S154). If 5AH is set in the normal symbol hit operation flag (step S154: ON), it is determined that the normal symbol is hit, and after updating the display data of the normal symbol (step S163), the normal symbol processing is performed. To finish.

On the other hand, if 5AH is not set in the normal symbol operation flag (step S154: OFF), the processing state indicating the behavior of the normal symbol, that is, the value of the normal symbol operation status flag is confirmed (step S155). Then, if the normal symbol operation status flag is 00H, the main control CPU 600a determines that the state is before the start of the fluctuation of the normal symbol, proceeds to step S156, and determines whether or not the number of reserved balls for starting the normal symbol is 0. Confirm (step S156).

When the main control CPU 600a confirms the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c in which the number of start-holding balls of the normal symbol is stored, and then determines that the value is 0 (step S156). : = 0), after updating the display data of the normal symbol (step S163), the normal symbol processing is completed. On the other hand, when it is determined that it is not 0 (step S156: ≠ 0), the number of start-holding balls of the normal symbol is subtracted by 1 (step S157).

After that, the main control CPU 600a uses the normal symbol hit detection table NPP_TBL shown in FIG. 43A to suspend the start of the normal symbol stored in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c. The hit judgment of the random value corresponding to the number of balls is performed. That is, if the normal symbol probability variation flag indicating the game state is OFF, the main control CPU 600a has the random number value as the lower limit value of the normal symbol hit detection table NPP_TBL (normal state) shown in FIG. 43 (a). If it is 249) or more and is not more than the upper limit value (250 in the figure), it is judged, and if it is more than the lower limit value and less than or equal to the upper limit value, 5AH is set in the normal symbol collision detection flag and turned ON. In other cases, the normal symbol collision detection flag is turned off.

On the other hand, if the normal symbol probability change flag indicating the game state is ON, the random value is the upper limit at the lower limit value (4 in the figure) or more of the normal symbol hit detection table NPP_TBL (probability change state) shown in FIG. 43 (a). It is determined whether or not it is a value (250 in the figure) or less, and if it is equal to or more than the lower limit value and less than or equal to the upper limit value, 5AH is set in the normal symbol collision detection flag and turned ON. In other cases, the process of setting the normal symbol hit detection flag to OFF is performed (step S158).

Then, the main control CPU 600a determines the stop symbol (normal symbol stop symbol) based on the lottery result determined in the random number lottery process (step S159).

Next, the main control CPU 600a confirms whether the normal symbol time reduction flag for shortening the fluctuation time of the normal symbol is set to ON, and if it is set to ON, sets the fluctuation time corresponding to the normal symbol fluctuation timer. If it is set to OFF, the process of setting the normal fluctuation time in the normal symbol fluctuation timer is performed (step S160).

Next, the main control CPU 600a has a normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c in which a random number value used for a winning / failing lottery of the normal symbol corresponding to the number of start-holding balls of the normal symbol is stored. The storage area is shifted (step S161). That is, assuming that the maximum number of start-holding balls of the normal symbol can be held at 4, the random number value used for the winning / failing lottery of the normal symbol corresponding to the start-holding number of 4 of the normal symbol is set to 3 of the start-holding balls of the normal symbol. The normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c in which the random number value used for the winning / failing lottery of the corresponding normal symbol is stored is shifted to the normal RAM area 600ca (see FIG. The random value used for the winning / failing lottery of the symbol is the normal RAM area 600ca of the main control RAM 600c in which the random number value used for the winning / failing lottery of the normal symbol corresponding to the number of start-holding balls 2 of the normal symbol is stored (FIG. 9 (a). ) Shifts to), and the random number value used for the winning / failing lottery of the normal symbol corresponding to the number of start-holding balls 2 of the normal symbol is the random number value used for the winning / failing lottery of the normal symbol corresponding to the starting-holding number of balls 1 of the normal symbol. Is shifted to the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c in which the is stored.

After this processing, the main control CPU 600a sets 01H to the normal symbol operation status flag used in step S155, and the random number value used for the winning / failing lottery of the normal symbol corresponding to the number of start-holding balls 4 of the normal symbol is set. A process of setting 00H in the normal RAM area 600ca (see FIG. 9A) of the stored main control RAM 600c is performed (step S162).

Then, after finishing the process of step S162, the main control CPU 600a updates the display data of the normal symbol (step S163), and finishes the normal symbol process.

On the other hand, if the main control CPU 600a is in the processing state indicating the behavior of the normal symbol in step S155, that is, if the value of the normal symbol operation status flag is 01H, the main control CPU 600a determines that the normal symbol is changing. The determination is made, the process proceeds to step S164, and it is confirmed whether or not the normal symbol variation timer is 0 (step S164). If the normal symbol fluctuation timer is not 0 (step S164: ≠ 0), the display data of the normal symbol is updated (step S163), and the normal symbol processing is completed. Then, if the normal symbol fluctuation timer is 0 (step S164: = 0), the main control CPU 600a sets 02H to the normal symbol operation status flag used in step S155, and keeps the result of the normal symbol winning / failing lottery constant. In order to maintain the time, for example, a time of about 600 ms is set in the normal symbol variation timer (step S165).

After finishing the process of step S165, the main control CPU 600a updates the display data of the normal symbol (step S163), and finishes the normal symbol process.

On the other hand, if the main control CPU 600a is in the processing state indicating the behavior of the normal symbol in step S155, that is, if the value of the normal symbol operation status flag is 02H, the main control CPU 600a has the normal symbol during the confirmation time (normal). It is determined that the symbol variation has ended and is stopped), the process proceeds to step S166, and it is confirmed whether or not the normal symbol variation timer is 0 (step S166). If the normal symbol fluctuation timer is not 0 (step S166: ≠ 0), the display data of the normal symbol is updated (step S163), and the normal symbol processing is completed. Then, if the normal symbol fluctuation timer is 0 (step S166: = 0), the main control CPU 600a sets 00H to the normal symbol operation status flag used in step S155 (step S167), and determines whether the normal symbol hits. It is confirmed whether the flag is set to ON (5AH is set) (step S168).

As a result, if the normal symbol hit detection flag is set to OFF (5AH is not set) (step S168: OFF), the main control CPU 600a updates the display data of the normal symbol (step S163). Normal design processing is completed. Then, if the normal symbol hit determination flag is set to ON (5AH is set) (step S168: ON), the main control CPU 600a turns on the normal symbol hit operation flag used in step S154 (5AH is set). After setting to (step S169), the normal symbol processing is finished.

<Main control: Explanation of special symbol processing>
Next, the special symbol processing will be described in detail with reference to FIGS. 30 to 37.

As shown in FIG. 30, in the special symbol processing, first, the special symbol 1 start port switch 44a (see FIG. 7) of the special symbol 1 start port 44 (see FIG. 5) is used to insert a game ball (winning ball). It is confirmed whether or not it has been detected (step S200), and further, at the special symbol 2 start port switch 45a (see FIG. 7) of the special symbol 2 start port 45 (see FIG. 5), the winning ball (winning ball) of the game ball is inserted. It is confirmed whether or not it has been detected (step S201).

<Main control: Special symbol processing: Explanation of starting port check processing>
Explaining this process in detail with reference to FIG. 31, the main control CPU 600a confirms whether or not a game ball has entered (winned) in the special symbol 1 starting port 44 or the special symbol 2 starting port 45, that is, special. The level of the special symbol 1 starting port switch 44a of the symbol 1 starting port 44 or the special symbol 2 starting port switch 45a of the special symbol 2 starting port 45 is confirmed (step S250). As a result, if the winning ball (winning) of the game ball is not detected (step S250: NO), the special symbol processing is completed.

On the other hand, if the winning ball (winning) of the game ball is detected (step S250: YES), the main control CPU 600a has a predetermined number of start-holding balls that triggers a change in the special symbol, and the normal RAM area 600ca of the main control RAM 600c. It is confirmed whether or not it is stored in (see FIG. 9A) (step S251). If the number of start-holding balls is less than 4 (step S251: ≠ MAX), the number of start-holding balls is added by 1 (+1) (step S252).

Next, the main control CPU 600a normally stores the random number value used when the special symbol is stopped, the random value for the fluctuation pattern, and the random value for the jackpot determination, and the number of start-holding balls that triggers the fluctuation of the special symbol. It is stored in the RAM area 600ca (see FIG. 9A) (step 253).

Next, the main control CPU 600a confirms the current gaming state (whether or not the special symbol jackpot determination flag is set to ON, etc.) and determines whether or not it is in the look-ahead prohibition state (step S254). If the read-ahead prohibition state is not set (step S254: NO), the main control CPU 600a draws a lottery for winning or losing a special symbol stored in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c in step S253. The jackpot determination random number value used in the above is acquired (step S255), and further, a start opening winning random number determination table (not shown) is acquired (step S256).

Next, the main control CPU 600a performs a jackpot lottery using the jackpot determination random number value acquired in step S255 and the start opening winning random number determination table (not shown) acquired in step S256, and further, the above In step S253, the type of jackpot (per rank-up bonus, normal jackpot, etc.) is determined using the random number value for the special symbol stored in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c. , The fluctuation pattern is determined using the random number value for the fluctuation pattern, and a special symbol start opening winning command corresponding to the fluctuation pattern is generated (step S257). When generating this special symbol start opening winning command, a program for acquiring the fluctuation time as shown in FIG. 13B is executed.

Next, the main control CPU 600a generates a start hold addition command of the lower byte corresponding to the generated special symbol start opening winning command (step S258).

On the other hand, the main control CPU 600a finishes the process of step S258, or in step S251 the number of start-holding balls of special symbol 1 or 2 is 4 or more (step S251: = MAX), or pre-reading. If it is in the prohibited state (step S254: YES), the start hold addition command of the upper byte corresponding to the increased number of start hold balls is generated (step S259).

Next, the main control CPU 600a combines the start hold addition command of the lower byte generated in step S258 and the start hold addition command of the upper byte generated in step S259, and then the start hold addition command (effect). As the control command DI_CMD), a process of transmitting to the sub-control board 80 is performed (step S260). This start hold addition command (effect control command DI_CMD) transmission process is called by the CALL_S command and processed.

<Main control: Explanation of special symbol processing>
Thus, when the processes of steps S200 and S201 shown in FIG. 30 are completed, the main control CPU 600a has the special symbol small hit operation flag set to ON, that is, the special symbol small hit operation flag is set to 5AH. (Step S202). If 5AH is set in the special symbol small hit operation flag (step S202: ON), it is determined that the special symbol is in the small hit, and after updating the display data of the special symbol (step S208), the special symbol is special. Finish the design processing.

On the other hand, if 5AH is not set in the special symbol small hit operation flag (step S202: OFF), is the special symbol big hit operation flag set to ON, that is, is 5AH set in the special symbol big hit operation flag? Is confirmed (step S203). If 5AH is set in the special symbol jackpot operation flag (step S203: ON), it is determined that the special symbol is in the jackpot, and after updating the display data of the special symbol (step S208), the special symbol processing To finish.

On the other hand, if 5AH is not set in the special symbol jackpot operation flag (step S203: OFF), the processing state indicating the behavior of the special symbol, that is, the value of the special symbol operation status flag is confirmed (step S204). More specifically, if the value of the special symbol operation status flag is 00H or 01H, the main control CPU 600a is waiting for the special symbol change (in the standby state for the next change because the special symbol is not changed). It is determined that there is (indicating that there is), and the special symbol change start processing is performed (step S205).

<Main control: Special symbol processing: Explanation of special symbol fluctuation start processing>
Explaining this process in detail with reference to FIG. 32, the main control CPU 600a confirms whether or not the number of start-holding balls that triggers the fluctuation of the special symbol is 0 (step S300). That is, when the main control CPU 600a confirms whether or not it is stored in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c and determines that the number of start-holding balls is 0 (step S300). : = 0), it is confirmed whether or not the value of the special symbol operation status flag is 00H (step S301). If the value of the special symbol operation status flag is 00H (step S301: YES), the special symbol change start process is terminated.

On the other hand, if the value of the special symbol operation status flag is not 00H (step S301: NO), the main control CPU 600a transmits the customer waiting demo command as the effect control command DI_CMD to the sub control board 80 (see FIG. 7) (step). S302). In response to this, the sub-control board 80 (sub-control CPU 800a) shifts to the customer waiting demo state when a predetermined time elapses from the timing T3 shown in FIG. 17A. The customer waiting demo command (effect control command DI_CMD) transmission process is called by the CALL_S command and processed.

Next, the main control CPU 600a sets the special symbol operation status flag to 00H (step S303), and ends the special symbol variation start process.

On the other hand, when the main control CPU 600a determines that the number of start holding balls is not 0 (step S300: ≠ 0), the start hold subtraction number is subtracted by 1 (-1) (step S304), and the start hold subtraction command is produced and controlled. The command DI_CMD is transmitted to the sub control board 80 (sub control CPU 800a) (step S305). In response to this, the sub-control CPU 800a transmits a command list related to the image (video) to the VDP 803. As a result, the VDP 803 generates image (video) data so as to display an image based on the command list, and transmits the generated image (video) data to the liquid crystal display device 41, thereby causing the liquid crystal display device 41 to display the image (video) data. Is a screen as shown in FIG. 19 (a-3), and a state in which three or two balls are held as start hold balls is displayed (see image P5). On the other hand, when the sub-control board 80 (sub-control CPU 800a) cannot receive the start hold subtraction command, the liquid crystal display is in a state where three start hold balls are held as shown in FIG. 19 (a-4). It will be displayed on the display device 41 (see image P1). As a result, the number of start-holding balls actually stored in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c and the displayed number of start-holding balls do not match. The start hold subtraction command (effect control command DI_CMD) transmission process is called by the CALL_S command and processed.

Next, the main control CPU 600a stores the normal RAM area 600ca of the main control RAM 600c in which the random value used when the special symbol is stopped, the random value for the fluctuation pattern, and the random value for jackpot determination (see step S253 in FIG. 31) are stored. The storage area in (see FIG. 9A) is shifted (step S306), and the normal RAM area 600ca of the main control RAM 600c in which the random number value used for the winning / failing lottery of the special symbol corresponding to the start hold 4 is stored is stored. 0 is set in the area (see FIG. 9A) (step S307).

Next, the main control CPU 600a performs a hit determination process (step S308).

<Main control: Special symbol processing: Explanation of collision detection processing>
This process will be described in detail with reference to FIG. 33. The main control CPU 600a has a normal RAM area 600ca (FIG. 9 (a)) of the main control RAM 600c in which a random value for jackpot determination (see step S253 in FIG. 31) is stored. ) To obtain a random value for jackpot determination (step S350).

Next, the main control CPU 600a acquires the address address of the hit determination table according to the fluctuating special figure. Here, the address address of the hit determination table D_RNDJDG shown in FIG. 34 corresponding to the fluctuating special figure 1 is acquired. The hit determination table data corresponding to the special symbol big hit determination table SDH_TBL shown in FIG. 43 (b) and the special symbol small hit determination table SDP_TBL shown in FIG. 43 (c) are shown in FIG. 34. The hit determination table will be described with reference to FIG. 34. In the hit determination table, information on whether the determination values are different for each set value (in the present embodiment, the set values 1 to 6 are exemplified) and information on whether the determination values are different. , The determination value, and the value of the special symbol big hit determination flag and the special symbol small hit determination flag are stored.

Specifically, as can be easily understood by referring to the special symbol jackpot determination table SDH_TBL shown in FIG. 43 (b), the game state is a normal state (low probability state) and a probability change state (win lottery probability is higher than usual). (Probability fluctuation state, which is a high probability state) Since there is no difference between the lower limit values for each set value and it is "10001",
DB 000H
DW 10000
DB 000H, 000H, 000H
Is programmed.

On the other hand, as can be easily understood by referring to the special symbol jackpot determination table SDH_TBL shown in FIG. 43 (b), the upper limit of the normal state (low probability state) of the game state is different for each set value. ,
DB 001H
DW 10164
DW 10180
DW 10185
DW 10190
DW 10195
DW 10200
DB 05AH, 05AH, 000H
Is programmed.

On the other hand, as can be easily understood by referring to the special symbol jackpot determination table SDH_TBL shown in FIG. For,
DB 001H
DW 11640
DW 11800
DW 11850
DW 11900
DW 11950
DW 12000
DB 000H, 05AH, 000H
Is programmed.

On the other hand, as can be easily understood by referring to the special symbol small hit determination table SDP_TBL shown in FIG. 43 (c), the lower limit value of either the normal state (low probability state) or the probability variation state (high probability state) of the game state There is no difference for each set value, and it is "20001", so
DB 000H
DW 20000
DB 000H, 000H, 000H
Is programmed.

Further, as can be easily understood by referring to the special symbol small hit determination table SDP_TBL shown in FIG. 43 (c), the upper limit value of either the normal state (low probability state) or the probability variation state (high probability state) of the game state. There is no difference for each set value, and it is "20164".
DB 000H
DW 20164
DB 000H, 000H, 05AH
Is programmed.

On the other hand, in this hit determination table, as shown in FIG. 34, the upper limit value (65535) of the jackpot determination random number value is programmed as follows.
DB 000H
DW 65535
DB 000H, 000H, 000H

Thus, the main control CPU 600a acquires the address address of the hit determination table as described above (step S351).

Next, the main control CPU 600a changes the acquired address address to the address address in which the determination value shown in FIG. 34 is stored (step S352).

Next, the main control CPU 600a acquires information on whether the determination value is different for each set value shown in FIG. 34 (step S353), and confirms the value of the acquired information (step S354). If the acquired value is "0" (step S354: = 0), the process proceeds to step S357, and if the acquired value is not "0" (step S354: ≠ 0), the main control CPU 600a is the main control. A set value of the probability of generating a special gaming state advantageous to the player stored in the RAM 600c (see FIG. 7) (for example, a set value of "00H" to "05H" corresponding to "1" to "6"). (Step S355).

Next, the main control CPU 600a changes to the address address in which the determination value corresponding to the acquired set value is stored (step S356). For example, when acquiring the judgment value of the upper limit value of the normal state (low probability state) of the game state, if the acquired setting value is "1", the address where the judgment value "10164" of the setting value 1 is stored. If the address is changed to the address and the set value is "6", the address address that refers to the data in the determination table is changed to the address address in which the determination value "10200" of the set value 6 is stored.

Next, the main control CPU 600a acquires the determination value shown in FIG. 34 from the current address address. For example, if it is related to a big hit and the information on whether the judgment value is different for each set value is "000H", the judgment value of "10000" is acquired and the information on whether the judgment value is different for each set value is " If it is "001H" and the set value is "1", the determination value of "10164" is acquired (step S357).

Next, the main control CPU 600a changes the address address to the first address address in which the next determination value is stored (step S358), and compares the acquired jackpot determination random number value with the acquired determination value (step S359).

Next, if the acquired jackpot determination random value is not smaller than the acquired determination value (step S360: NO), the main control CPU 600a returns to the process of step S353, and the acquired jackpot determination random value is based on the acquired determination value. The processing of steps S353 to S360 is repeated until the value becomes smaller (step S360: YES).

Next, when the acquired jackpot determination random value becomes smaller than the acquired determination value (step S360: YES), the main control CPU 600a has a special symbol jackpot determination flag and a special symbol small hit according to the game state, as shown in FIG. 34. The determination flag is acquired (step S361), and the hit determination process is completed.

By the way, even when the set value (for example, the set value of "1") has only one step, the programs shown in steps S350 to S361 can be used as they are (program standardization). The data in the hit determination table shown in FIG. 35 is changed to the data shown in FIG.

That is, to explain only the differences from FIG. 34, since the set value has only one step, the upper limit of the game state in the normal state (low probability state) does not differ for each set value, but for the purpose of standardizing the program. , Program as "DB 001H". Further, since the set value has only one step, the upper limit value of the game state in the probability change state (high probability state) is programmed as "DB 001H" for the purpose of standardizing the program, although there is no difference for each set value. Further, in order to make the data size the same as the data size of the hit determination table shown in FIG. 34, dummy data "DW 0000H" is added.

By doing so, even if the set value has only one step, the determined value is acquired by referring to the set value. Therefore, the processes of steps S354 to 356 are always executed to generate an unused program. Programs can be standardized without making them. This is because if there is an unused program, it will be non-conforming in the certification test, so it is necessary to use all the programs.

<Main control: Special symbol processing: Explanation of special symbol fluctuation start processing>
Thus, after completing the hit determination process (step S308) as described above, the main control CPU 600a is stored in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c in step S253 of FIG. A stop symbol of the special symbol is generated using the random value used when the special symbol is stopped (step S309).

Next, the main control CPU 600a prepares to shift to any of the game states of the normal state, the time saving state, the latent probability change state, and the probability change state (step S310).

Next, the main control CPU 600a generates a variation pattern of the special symbol using the variation pattern random value stored in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c in step S253 of FIG. Then, the variation pattern command of the variation pattern of the generated special symbol is transmitted to the sub control board 80 (sub control CPU 800a) as the effect control command DI_CMD (step S311). At this time, a program for acquiring the fluctuation time as shown in FIG. 13B is executed, and the fluctuation time is set in the special symbol fluctuation timer. The variation pattern command (effect control command DI_CMD) transmission process is called by the CALL_S command and processed.

Next, the main control CPU 600a sets the special symbol changing flag to 5AH and puts it in the ON state (step S312).

Next, the main control CPU 600a generates a symbol designation command for designating a special symbol displayed on the liquid crystal display device 41 (step S313), and uses the generated symbol designation command as the effect control command DI_CMD for the sub control board 80 (sub). A process of transmitting to the control CPU 800a) is performed (step S314). The symbol designation command (effect control command DI_CMD) transmission process is called by the CALL_S command and processed.

Next, the main control CPU 600a sets 02H in the special symbol operation status flag (step S315), and ends the special symbol variation start process.

<Main control: Explanation of special symbol processing>
On the other hand, as shown in FIG. 30, when the value of the special symbol operation status flag is 02H, the main control CPU 600a determines that the special symbol is changing (indicating that the special symbol is currently changing), and is special. Processing during symbol change is performed (step S206).

<Main control: Special symbol processing: Explanation of processing during special symbol change>
Explaining this process in detail with reference to FIG. 36, first, the main control CPU 600a has passed the fluctuation time set in the special symbol fluctuation timer in step S311 of FIG. 32, that is, whether or not it has become 0. Is confirmed (step S400). If the special symbol variation timer is not 0 (step S400: NO), the main control CPU 600a ends the process during special symbol variation.

On the other hand, if the special symbol variation timer is 0 (step S400: YES), the main control CPU 600a transmits the symbol stop command as the effect control command DI_CMD to the sub control board 80 (sub control CPU 800a) (step S401). The symbol stop command (effect control command DI_CMD) transmission process is called by the CALL_S command and processed.

Next, the main control CPU 600a sets 03H in the special symbol operation status flag and 00H in the special symbol changing flag. Further, the main control CPU 600a sets, for example, a time of about 500 ms in the special symbol variation timer in order to maintain the winning / failing lottery result of the special symbol for a certain period of time (step S402). After that, the main control CPU 600a ends the processing during the special symbol change.

<Main control: Explanation of special symbol processing>
On the other hand, as shown in FIG. 30, when the value of the special symbol operation status flag is 03H, the main control CPU 600a indicates that the special symbol is being confirmed (indicating that the change of the special symbol is completed and stopped). Judgment is performed, and processing is performed during the special symbol confirmation time (step S207).

<Main control: Special symbol processing: Explanation of processing during special symbol confirmation>
Explaining this process in detail with reference to FIG. 37, first, the main control CPU 600a has passed the fluctuation time set in the special symbol fluctuation timer in step S311 of FIG. 32, that is, whether or not it has become 0. Is confirmed (step S450). If the special symbol variation timer is not 0 (step S450 ≠ 0), the main control CPU 600a ends the process during the special symbol confirmation time.

On the other hand, if the special symbol fluctuation timer is 0 (step S450 = 0), the main control CPU 600a sets the special symbol operation status flag to 01H (step S451), and is the special symbol jackpot determination flag set to ON? Check (whether 5AH is set) (step S452). If the special symbol jackpot determination flag is set to ON (if 5AH is set) (step S452: YES), the special symbol jackpot determination flag is set to 00H, and the special symbol jackpot operation flag is set to 5AH. , And set 00H to the normal symbol time reduction flag, set 00H to the normal symbol probability change flag, set 00H to the special symbol time reduction flag, set 00H to the special symbol probability change flag, and set the special symbol time reduction number to be described later. A process of setting 00H to the counter and the special symbol probability variation counter is performed (step S453). After that, the main control CPU 600a ends the process during the special symbol confirmation time.

On the other hand, if the special symbol jackpot determination flag is not set to ON (if 5AH is not set) (step S452: NO), is the main control CPU 600a set the special symbol small hit determination flag to ON (step S452: NO)? (Whether 5AH is set) is confirmed (step S454). If the special symbol small hit determination flag is set to ON (if 5AH is set) (step S454: YES), 00H is set for the special symbol small hit determination flag, and 5AH is set for the special symbol small hit operation flag. Is set (step S455).

After finishing the process of step S455, or if the special symbol small hit determination flag is not set to ON (if 5AH is not set) (step S454: NO), the main control CPU 600a shortens the special symbol time. It is confirmed whether or not the value of the count counter is 0 (step S456).

If the value of the special symbol time reduction counter is not 0 (step S456: NO), the value of the special symbol time reduction counter is subtracted by 1 (-1) (step S457), and the main control CPU 600a again performs the special symbol time reduction counter. It is confirmed whether or not the value of the counter is 0 (step S458). If the value of the special symbol time reduction counter is 0 (step S458: YES), 00H is set in the normal symbol time reduction flag, 00H is set in the normal symbol probability change flag, and 00H is set in the normal symbol time reduction flag. Is set (step S459).

After the processing of step S459 is completed, or if the value of the special symbol time reduction counter is 0 (step S456: YES) or the value of the special symbol time reduction counter is not 0 (step S458: NO), the main The control CPU 600a confirms whether or not the value of the special symbol probability variation counter is 0 (step S460). If the value of the special symbol probability variation counter is 0 (step S460: YES), the main control CPU 600a ends the process during the special symbol confirmation time.

On the other hand, if the value of the special symbol probability variation counter is not 0 (step S460: NO), the main control CPU 600a subtracts 1 from the value of the special symbol probability variation counter (-1) (step S461), and again the special symbol. It is confirmed whether or not the value of the probability variation counter is 0 (step S462). If the value of the special symbol probability variation counter is not 0 (step S462: NO), the main control CPU 600a ends the process during the special symbol confirmation time.

On the other hand, if the value of the special symbol probability variation counter is 0 (step S462: YES), the main control CPU 600a sets the normal symbol time reduction flag to 00H, sets the normal symbol probability variation flag to 00H, and sets the special symbol time reduction flag. Is set to 00H, a process of setting 00H to the special symbol probability change flag is performed (step S463), and the process is completed during the special symbol confirmation time.

<Main control: Explanation of special symbol processing>
Thus, when any of the processes of step S205, step S206, and step S207 shown in FIG. 30 is completed, the main control CPU 600a ends the special symbol processing after updating the display data of the special symbol (step S208). ..

<Main control: Explanation of LED management process>
Next, the LED management process will be described in detail with reference to FIG. 38.

The main control CPU 600a clears the LED common port and the LED data port (step S500), and updates the LED output counter (step S501).

Next, the main control CPU 600a selects output data from the LED output counter and the selected LED common output selection table (step S502). This LED common output selection table is programmed as shown in FIG.

Specifically, the destination where the LED data is output is the special symbol 1 display device 50a (see FIG. 5), and the common data for outputting the LED data to the special symbol 1 display device 50a (see FIG. 5). And are programmed as follows.
DB 0001 0001B
DW D_MKLED0, D_MKLED0

Next, the destination where the LED data is output is the special symbol 2 display device 50b (see FIG. 5), and the common data for outputting the LED data to the special symbol 2 display device 50b (see FIG. 5). It is programmed as follows.
DB 0010 0010B
DW D_MKLED1, D_MKLED1

Next, the destination where the LED data is output is the 7-segment display device 52a (see FIG. 5), and the common data for outputting the LED data to the 7-segment display device 52a (see FIG. 5) are as follows. Is programmed to.
DB 0100 0100B
DW D_MKLED2A, D_MKLED2B

Next, the destination to which the LED data is output is the normal symbol display device 51 (see FIG. 5), the right-handed notification lamp 52c (see FIG. 5), the round lamp 52b (see FIG. 5), and the normal symbol display device. The common data for outputting LED data to the 51 (see FIG. 5), the right-handed notification lamp 52c (see FIG. 5), and the round lamp 52b (see FIG. 5) are programmed as follows.
DB 1000 1000B
DW D_MKLED3, D_MKLED3

By the way, as for the common data to be output, 4 bits in the first stage of the 8-bit signal are output from the first LED dynamic lighting common data signal 611a2 (see FIG. 8) (in FIG. 39, it is described as common 00 to 04), and the latter stage. 4 bits are output from the second LED dynamic lighting common data signal 611a3 (see FIG. 8) (in FIG. 39, it is described as commons 10 to 13). Therefore, in the present embodiment, the common data is output from the same port. This is because when trying to output different common data from the same port, the LED does not light normally unless one of the common data is reflected and output.

That is, in order to output "1" from the first LED dynamic lighting common data first signal 611a2a (see FIG. 8) of the first LED dynamic lighting common data signal 611a2, "0000 0001" is output from the port and then the second LED dynamic. When "0001 0000" is output from the port in order to output "1" from the second LED dynamic lighting common data first signal 611a3a (see FIG. 8) of the lighting common data signal 611a3, the first LED dynamic lighting common data signal 611a2 First LED dynamic lighting common data The data of the first signal 611a2a (see FIG. 8) is cleared. As a result, the LED does not light normally, so that data must be newly output to the first LED dynamic lighting common data first signal 611a2a (see FIG. 8) of the first LED dynamic lighting common data signal 611a2.

Therefore, in the present embodiment, the common data is output together in advance, and the LED data is later output to the measurement / setting display device 610 by the LED update process outside the used area (see FIG. 41) described later. I try to do it. Even in this way, the LED will light up without any problem in appearance.

Thus, the main control CPU 600a selects output data from the LED output counter and the selected LED common output selection table (step S502), and then outputs the data to the LED common port (step S503). For example, if it is selected in step S502 that the destination to which the LED data is output is the special symbol 1 display device 50a (see FIG. 5), "0001 0001" is output in step S503. Become. As a result, the first LED dynamic lighting common data first signal 611a2a (see FIG. 8) of the first LED dynamic lighting common data signal 611a2 and the second LED dynamic lighting common data second signal 611a3a of the second LED dynamic lighting common data signal 611a3 (see FIG. 8). (See FIG. 8), "1" will be output.

Next, the main control CPU 600a creates the output destination LED data of the selected LED common (step S504). For example, if it is selected in step S502 that the destination to which the LED data is output is the special symbol 1 display device 50a (see FIG. 5), the LED to be displayed on the special symbol 1 display device 50a (see FIG. 5) is displayed. Data will be created.

Next, the main control CPU 600a outputs the created LED data to the selected LED data port (step S505). As a result, the data created from the first LED dynamic lighting data signal 611b2 (see FIG. 8) is output. For example, in the case of LED data to be displayed on the special symbol 1 display device 50a (see FIG. 5), the data is output to the special symbol 1 display device 50a (see FIG. 5), and thus the special symbol 1 display device 50a (see FIG. 5) is output. The output data will be displayed in (see 5).

<Main control: Explanation of out-of-use processing>
Next, the out-of-use area processing will be described in detail with reference to FIG. 40. In this 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 stored in the measurement program area 600be (see FIG. 9B) of the main control ROM 600b is calculated. It is done using the program used for the measurement.

The main control CPU 600a saves all the registers to the measurement stack area 600 cg of the main control RAM 600c (see FIG. 9A) (step S550), and sets the stack pointer during normal processing to the measurement stack area of the main control RAM 600c. Evacuate to 600 cg (see FIG. 9A) (step S551).

Next, the main control CPU 600a sets the stack pointer address for the outside of the used area in the stack pointer inside the main control CPU 600a (step S552).

Next, the main control CPU 600a performs the prize ball winning number management process 2 (step S553). In this prize ball winning number management process 2, a process of displaying the performance display value calculated in the prize ball winning number management process 1 of step S45 shown in FIG. 25 on the measurement / setting display device 610 (see FIG. 8) is performed. ..

Next, the main control CPU 600a performs the LED update process outside the used area (step S554).

<Main control: Explanation of LED update processing outside the used area>
Explaining this process in detail with reference to FIG. 41, the main control CPU 600a first acquires the LED output counter value (step S600).

Next, the main control CPU 600a selects the LED data corresponding to the LED common from the acquired LED output counter value (step S601).

Next, the main control CPU 600a outputs LED data to the selected LED port (step S602). As a result, LED data is output from the second LED dynamic lighting data signal 611c2, and the measurement / setting display device 610 displays the content (performance display) related to the ratio of how many prize balls were awarded at the time of low accuracy. It becomes.

That is, since the data has already been output from the LED common port in step S503 of the LED management process of FIG. 38, it is sufficient to output the data to the LED data port.

When displaying data on each of the 7 segments of the measurement / setting display device 610, LED data is acquired from the table shown below in which the work addresses are arranged in order.

D_LEDDATA:
DW W_7SEG0 ← 1st digit data of 7-segment (1st measurement / setting display device 610A)
DW W_7SEG1 ← 2nd digit data of 7 segment (2nd measurement / setting display device 610B)
DW W_7SEG2 ← 3rd digit data of 7-segment (3rd measurement / setting display device 610C)
DW W_7SEG3 ← 4th digit data of 7-segment (4th measurement / setting display device 610D)

Here, since the LED output counter value directly corresponds to the common number, the LED data corresponding to the LED output counter value is acquired from the above table, and the acquired LED data is output from the LED data port. It will be. As a result, the measurement / setting display device 610 displays the content (performance display) relating to the ratio of how many prize balls were awarded at the time of low accuracy.

<Main control: Explanation of out-of-use processing>
Thus, when the main control CPU 600a finishes the out-of-use LED update process (step S554) through the above processes, the special symbol 1 start port switch 44a (see FIG. 7) and the special symbol 2 start port switch 45a (see FIG. 7). (See FIG. 7), normal symbol start port switch 47a (see FIG. 7), upper right general winning opening switch 48a1 (see FIG. 7), upper left general winning opening switch 48b1 (see FIG. 7), left middle general winning opening switch 48c1 (see FIG. 7). 7), lower left general winning opening switch 48d1 (see FIG. 7), out opening switch 49a (see FIG. 7), large winning opening switch 46c (see FIG. 7), game ball detection switch UR1a (see FIG. 6), etc. The out-of-area switch detection information is stored in the measurement RAM area 600ce (see FIG. 9A) of the main control RAM 600c (step S555).

Next, the main control CPU 600a performs a process of updating the test firing test signal used when outputting various signals related to the game to the testing machine in the certification test (test firing test) of the gaming machine (step S556), and the main control RAM 600c The stack pointer at the time of normal processing saved in the measurement stack area 600 cg (see FIG. 9A) is restored (step S557), and all the registers are restored (step S558).

Therefore, according to the present embodiment, the measurement / setting display device 610 displays the content (performance display) relating to the ratio of how many prize balls were awarded at the time of low probability, and displays a special gaming state advantageous to the player. It is also possible to display the setting contents of the probability of occurrence. Further, the measurement / setting display device 610 has four 7 segments (first measurement / setting display device 610A, second measurement / setting display device 610B, third measurement / setting display device 610C, fourth measurement). -Composed of a setting display device 610D), when the content (performance display) related to the ratio of how many prize balls were won at low probability is displayed, four 7 segments are used, which is a special advantage for the player. When the setting content of the probability of generating the game state is displayed, one 7-segment is used. As shown in the setting switching process shown in FIG. 26 and the LED update process outside the used area shown in FIG. 40, the lights are lit by the dynamic lighting method. When the content (performance display) related to the ratio of the taka is displayed, the common data is switched and four 7 segments (first measurement / setting display device 610A, second measurement / setting display device 610B, third). While the measurement / setting display device 610C and the fourth measurement / setting display device 610D) are lit, in the setting switching process shown in FIG. 26, one 7-segment display (first measurement / setting display device 610A) is turned on. ) Is used, so the 7-segment (first measurement / setting display device 610A) is turned on without switching the common data.

Furthermore, when changing the setting of the probability of generating a special gaming state advantageous to the player, it is used during game processing such as lottery processing stored in the normal program area 600ba of the main control ROM 600b shown in FIG. 9B. The program is used and data is output to the measurement / setting display device 610 (see the setting switching process shown in FIG. 26). On the other hand, when the content (performance display) relating to the ratio of how many prize balls were awarded at the time of low accuracy is displayed, the prize balls stored in the measurement program area 600be of the main control ROM 600b shown in FIG. 9B. The program used to measure the total number of game balls fired in the game area 40 including the number and the number of non-winning prizes is used, and the data is output to the measurement / setting display device 610 (Fig.). Refer to the LED update process outside the used area shown in 40).

Thus, in the past, in a situation where the program capacity was limited, the processing was complicated and there was a risk of squeezing the program capacity. However, if the processing as in the present embodiment is performed, the limited program capacity can be made efficient. Can be used as a program. When outputting the data, although the common data used for the special symbol 1 display device 50a and the like and the common data used for the measurement / setting display device 610 are different, they are output from one port. At this time, when the setting of the probability of generating a special gaming state advantageous to the player is changed, only the common data displayed on the measurement / setting display device 610 is output (see steps S58 to S60 shown in FIG. 26). At the time, the common data used for the special symbol 1 display device 50a and the like and the common data used for the measurement / setting display device 610 are output at the same timing (see FIG. 39). As a result, the limited program capacity can be used more efficiently.

By the way, in the present embodiment, the common data is output from one port, but it may be output from different ports. Even in this case, if the LED output counter described above is used in common, the program capacity can be reduced.

At this time, an LED driver different from the LED driver 611a shown in FIG. 8 is required separately. Further, when displaying the data on each of the 7 segments of the measurement / setting display device 610, the data is displayed using a program as shown in FIG. 42. That is, in the program shown in FIG. 42, common data for displaying data in each of the seven segments of the measurement / setting display device 610 and LED data to be output are stored.

Specifically, the destination where the LED data is output is the first digit data (first measurement / setting display device 610A) of the seven segments, and the first digit data (first measurement / setting). The common data for outputting the LED data to the display device 610A) is programmed as follows.
DB 0000 0001B
DW W_7SEG0

Next, the destination where the LED data is output is the second digit data of the 7 segment (second measurement / setting display device 610B), and the second digit data (second measurement / setting display device 610B). The common data for outputting the LED data to) is programmed as follows.
DB 0000 0010B
DW W_7SEG1

Next, the destination where the LED data is output is the third digit data (third measurement / setting display device 610C) of the seven segments, and the third digit data (third measurement / setting display device 610C). The common data for outputting the LED data to) is programmed as follows.
DB 0000 0100B
DW W_7SEG2

Next, the destination where the LED data is output is the 4th digit data (4th measurement / setting display device 610D) of the 7 segment, and the 4th digit data (4th measurement / setting display device 610D). The common data for outputting the LED data to) is programmed as follows.
DB 0000 1000B
DW W_7SEG3

Thus, by using such a program, it is possible to display the data on each of the seven segments of the measurement / setting display device 610 even if the common data is output from different ports.

<Processing content of sub-control board>
Next, the processing method of the effect shown in FIGS. 17 to 19 and 21 will be specifically described with reference to the processing content (outline of the program) of the sub-control board 80 shown in FIGS. 44 to 48.

First, when the power is turned on to the pachinko gaming machine 1, a power-on signal indicating that the power is turned on is sent from the power supply board 130 (see FIG. 7) to each control board. Then, in response to the signal, the sub-control CPU 800a performs the main process shown in FIG. 44.

<Sub control: Main processing>
As shown in FIG. 44, first, the sub-control CPU 800a initializes the registers provided inside and sets the input / output directions of the input / output ports. Further, the data transmitted from the output port set in the output direction is set to be serially transferred (step S1000). As shown in FIG. 22, when the sound data stored in the sound data storage area 805c of the game ROM 805 is transferred to the predetermined storage area 802a of the sound RAM 802 by using the DMA controller 800a1 (see FIG. 7). The sub-control CPU 800a instructs the DMA controller 800a1 (see FIG. 7) to transfer the sound data stored in the sound data storage area 805c of the game ROM 805 to a predetermined storage area 802a of the sound RAM 802. As a result, the DMA controller 800a1 transfers the sound data stored in the sound data storage area 805c of the game ROM 805 to the predetermined storage area 802a of the sound RAM 802. At this time, the sub-control CPU 800a continues the following processing regardless of the operation of the DMA controller 800a1.

Next, the sub-control CPU 800a initializes the memory area in the sub-control RAM 800c that stores the effect control command DI_CMD received from the main control board 60 (see FIG. 7) (step S1001). Then, the sub-control CPU 800a performs an interrupt permission setting process of the input port that receives the interrupt signal from the main control board 60 (step S1002).

Next, the sub-control CPU 800a initializes the memory area in the sub-control RAM 800c used as the work area and the stack area (step S1003), and issues an initialization command to the sound LSI 801 (see FIG. 7). As a result, the sound LSI 801 initializes the register provided inside the sound LSI 801 (step S1004).

Next, the sub-control CPU 800a determines whether or not an abnormality has occurred in the motors (not shown) that operate the upper, left, right, and upper left movable accessories 43a to 43d (see FIG. 5), and the motors (not shown). ) Is stored, and the memory area in the sub-control RAM 800c is confirmed. When the abnormality data is stored, the sub-control CPU 800a issues a command to return the motor to the origin position. As a result, the upper / left / right / upper left movable accessories 43a to 43d return to the initial positions (step S1005).

Next, the sub-control CPU 800a sets a CTC (Counter Timer Circuit) provided inside the sub-control CPU 800a, which has a function of creating a pulse output having a fixed cycle, a function of measuring time, and the like. That is, the sub-control CPU 800a sets the time constant register of the CTC so that the timer interrupt is periodically applied every 1 ms (step S1006).

Next, the sub-control CPU 800a performs a checksum operation, which is an 8-bit addition operation targeting the work area of the sub-control RAM 800c (step S1007), and obtains the checksum operation value and a memory backup (see step S1015) described later. It is calculated and compared with the checksum calculation value stored in the sub-control RAM 800c, and it is confirmed whether or not they match (step S1008). If they do not match (step S1008: NO), a process of clearing all the areas in the sub-control RAM 800c is performed (step S1009).

On the other hand, after matching (step S1008: YES) or finishing the process of step S1009, the sub-control CPU 800a cancels the watch dock timer function (step S1010) (not shown), and hardware such as the sub-control CPU 800a and VDP803. Is refreshed (step S1011).

Next, the sub-control CPU 800a reads the effect control command DI_CMD received from the main control board 60 (see FIG. 7) stored in the memory area in the sub-control RAM 800c, and sub-subsulates the effect pattern according to the contents. It is determined by lottery from a large number of effect patterns stored in advance in the control ROM 800b (step S1012). At this time, if the customer waiting demo command is not provided and the game state shifts to the customer waiting demo state triggered by the symbol stop command, the timer is activated and counts for a predetermined time when the symbol stop command is received. It will be.

Next, the sub-control CPU 800a performs a process of analyzing the input contents of the setting button 15 or the effect button device 13 acquired in the timer interrupt process described later (step S1013). Specifically, the player analyzes whether the setting button 15 or the effect button device 13 is pressed, released, or remains pressed by the player.

Next, the sub-control CPU 800a controls the operation of the upper / left / right / upper left movable accessories 43a to 43d (see FIG. 5) and the decorative lamp substrate 90 (see FIG. 5) based on the effect pattern determined by lottery in step S1012. (See FIG. 7), the lighting or extinguishing of decorative lamps such as LED lamps, the control of the speaker 17, and the control of the image displayed on the liquid crystal display device 41 are executed (step S1014). The specific processing method will be described later.

Next, the sub-control CPU 800a performs a checksum operation, which is an 8-bit addition operation targeting the work area of the sub-control RAM 800c, and performs a memory backup process for storing the checksum operation value in the sub-control RAM 800c (step). S1015).

Next, the sub-control CPU 800a confirms whether or not the VSYNC interrupt signal has been transmitted from the VDP 803 to the sub-control CPU 800a (step S1016). If the VSYNC interrupt signal is not transmitted (step S1016: NO), the sub-control CPU 800a repeatedly executes the process of step S1016 until the VSYNC interrupt signal is transmitted, and when the VSYNC interrupt signal is transmitted. (Step S1016: YES), the process returns to the process of step S1007, and the processes of steps S1007 to S1016 are repeated.

<Sub-control: data analysis processing>
Subsequently, with reference to FIG. 45, the data analysis process in step S1014 of the main process will be described in detail. First, the sub-control CPU 800a selects the effect scenario data PS_DATA (see FIG. 10A) corresponding to the effect pattern determined by lottery in step S1012 from the effect scenario table PR_TBL, and stores it in the selected effect scenario data PS_DATA. An image to be displayed on the liquid crystal display device 41 on the VDP 803 based on various data (frame data PS_DATA10, control code data PS_DATA11, coordinate data PS_DATA12, pixel calculation data PS_DATA13, scaling data PS_DATA14) stored in the one-layer data PS_DATA1. Generate a command list for generating data (step S1050).

Next, the sub-control CPU 800a has data or a setting button 15 indicating that the pressing effect of the effect button device 13 is effective in the button data PS_DATA113 (see FIG. 10C) stored in the selected effect scenario data PS_DATA. When the data indicating that the repeated hitting effect of is effective is stored, the data is stored in the memory area in the sub-control RAM 800c.

Further, the sub-control CPU 800a generates a control signal related to light based on the data content of the lamp data PS_DATA17 (see FIG. 10B) stored in the selected effect scenario data PS_DATA, and is in the sub-control RAM 800c. Performs the process of storing in.

Further, the sub-control CPU 800a is based on the data contents of the movable accessory data PS_DATA16 (see FIG. 10B) stored in the selected effect scenario data PS_DATA, and the upper / left / right / upper left movable accessory 43a The operation contents of ~ 43d are determined, and the motor data of the motor (not shown) of the movable accessory device 43 according to the determined operation contents is generated.

Furthermore, the sub-control CPU 800a generates a control signal related to sound based on the data content of the sound data PS_DATA15 (see FIG. 10B) stored in the selected production scenario data PS_DATA (step S1051). As a result, the sound LSI 801 (see FIG. 7) reads the sound corresponding to the control signal from the sound data storage area 805c of the game ROM 805 shown in FIGS. 20 and 23. As a result, the sound LSI 801 performs processing based on the read sound data and outputs the sound source data to the speaker 17. When the sound data stored in the sound data storage area 805c of the game ROM 805 is transferred to the predetermined storage area 802a of the sound RAM 802 using the DMA controller 800a1 (see FIG. 7), the sound shown in FIG. 22 The BGM corresponding to the control signal is read out from the predetermined storage area 802a of the RAM 802.

Specifically, at the timing T1 shown in FIG. 17B, as the effect control command DI_CMD, a start hold subtraction command (for example, B001H) in which the number of start hold balls is subtracted from 1 to 0, and a decorative pattern. Receives a variation pattern command (for example, A001H) for a variation pattern (for example, a loss pattern 1) of (special symbol), and a symbol designation command (for example, BB01H) for designating a decorative symbol (special symbol) (for example, a loss pattern). Then, the BGM is played back in a loop regardless of the fluctuation time (for example, 120 seconds) of the decorative symbol (special symbol).

Further, at the timing T2 shown in FIG. 17B, when a symbol stop command (for example, BF01H) for stopping the decorative symbol (special symbol) is received as the effect control command DI_CMD, the sound LSI 801 is loop-reproduced. The loop playback is performed as it is without stopping the BGM.

Thus, in this way, at the timing T3 shown in FIG. 17B, even if the customer waiting demo command cannot be received (missing), the BGM continues to be played back in a loop. Therefore, as the BGM continues to be played in a loop, even if the liquid crystal display device 41 does not display a "command reception error", a command reception error is sent to an employee of the amusement park who understands the error specifications. Can be notified that has occurred.

Further, in a state where the customer waiting demo command cannot be received and the BGM continues to be played back in a loop, at the timing T4 shown in FIG. When the variable pattern command (for example, A001H) of the loss pattern 1) and the symbol designation command (for example, BB01H) for designating the decorative symbol (special symbol) (for example, the loss symbol) are received, the sound LSI 801 receives a new BGM. Instead of playing back, the BGM that is playing back in a loop is played back as it is. As a result, when shifting from the error state to the normal gaming state, the player can play the game without feeling uncomfortable.

Even if the game state shifts to the customer waiting demo state triggered by the symbol stop command, the same processing is performed.

Thus, the sub-control CPU 800a repeats the processes of step S1050 and step S1051 until all the data based on the effect pattern determined by lottery in step S1012 shown in FIG. 44 is generated (step S1052: NO). When all the data has been generated (step S1052: YES), the process proceeds to step S1053.

Next, the sub-control CPU 800a performs button activation processing based on the contents stored in the sub-control RAM 800c in step S1051 and the input contents of the setting button 15 or the effect button device 13 processed in step S1013 shown in FIG. 44. (Step S1053).

<Sub-control: Command reception interrupt processing>
Subsequently, with reference to FIG. 46, the processing when the effect control command DI_CMD and the interrupt signal are transmitted from the main control board 60 during the execution of such a main processing will be described.

As shown in FIG. 46, when the sub-control CPU 800a receives the interrupt signal, it executes a save process of saving the contents of each register in the stack area in the sub-control RAM 800c (step S1100). After that, the sub-control CPU 800a reads the register of the input port that has received the effect control command DI_CMD (step S1101), and calculates a pointer indicating the address address of the command transmission / reception memory area in the sub-control RAM 800c (step S1102).

After that, the sub-control CPU 800a again reads the register of the input port that has received the effect control command DI_CMD (step S1103), and whether or not the value read in step S1101 and the value read in step S1103 match. To confirm. If they do not match (step S1104: NO), the process proceeds to step S1107, and if they match (step S1104: YES), the effect control command received from the main control board 60 is sent to the address address corresponding to the calculated pointer. The DI_CMD is stored (step S1105). The stored effect control command DI_CMD is read out by the sub-control CPU 800a during the process of step S1012 shown in FIG. 44.

Next, the sub-control CPU 800a updates the pointer indicating the address address of the command transmission / reception memory area in the sub-control RAM 800c (step S1106), and restores the register saved in the process of step S1100 (step S1107). As a result, the process returns to the main process shown in FIG.

<Sub-control: Timer interrupt processing>
Subsequently, with reference to FIG. 47, the process when the timer interrupt every 1 ms, which is set in the process of step S1006 (see FIG. 44) of the main process, occurs will be described.

As shown in FIG. 47, when a timer interrupt occurs every 1 ms, the sub-control CPU 800a executes a save process of saving the contents of each register to the stack area in the sub-control RAM 800c (step S1150).

Next, the sub-control CPU 800a acquires the data of the setting button 15, the data of the effect button device 13, the motor data of the movable accessory device 43, etc. twice (step S1151), and whether the acquired data match. It is confirmed whether or not (step S1152). If the data do not match (step S1152: NO), the sub-control CPU 800a repeats the process of step S1151 until the data match, and if they match (step S1152: YES), the sub-control RAM 800c uses the matched data. Store in (step S1153).

Next, the sub-control CPU 800a receives a signal from the setting button 15 or the effect button device 13 (step S1154). This received signal will be analyzed by the button analysis process of step S1013 shown in FIG.

Next, the sub-control CPU 800a transmits a control signal regarding the light stored in the sub-control RAM 800c in step S1051 shown in FIG. 45 to the decorative lamp substrate 90 (see FIG. 7) (step S1155). A control signal required to turn on or off the identification lamp device 50A (see FIG. 5) is also transmitted.

By the way, when the decorative lamps such as the LED lamps mounted on the decorative lamp substrate 90 (see FIG. 7) are turned on or off, the effect control command DI_CMD is used at the timing T1 shown in FIG. 17 (b). , The start hold subtraction command (for example, B001H) in which the number of start hold balls is subtracted from 1 to 0, and the variation pattern command (for example, A001H) of the variation pattern (for example, loss pattern 1) of the decorative symbol (special symbol). , When a symbol designation command (for example, BB01H) for designating a decorative symbol (special symbol) (for example, a lost symbol) is received, the decorative symbol (special symbol) changes regardless of the fluctuation time (for example, 120 seconds). The command lamp effect will be executed in a loop.

Further, at the timing T2 shown in FIG. 17B, when a symbol stop command (for example, BF01H) for stopping the decorative symbol (special symbol) is received as the effect control command DI_CMD, it is executed in a loop for variation. The lamp effect is not stopped, and the loop is executed as it is.

Thus, in this way, even if the customer waiting demo command cannot be received (missing) at the timing T3 shown in FIG. 17B, the variable lamp effect continues to be executed in a loop. Therefore, by continuing to execute the variable lamp effect in a loop, employees of the amusement park who understand the error specifications without displaying a "command reception error" on the liquid crystal display device 41, etc. It is possible to notify that a command reception error has occurred.

By the way, as the lamp effect, instead of executing the variable lamp effect as described above in a loop, as shown in FIG. 17 (c), the symbol stop lamp effect may be executed. That is, at the timing T2 shown in FIG. 17C, when a symbol stop command (for example, BF01H) for stopping the decorative symbol (special symbol) is received as the effect control command DI_CMD, the symbol stop lamp effect is executed. It becomes. This symbol stop lamp effect is a pattern in which the brightness of a decorative lamp such as an LED lamp that produces a lamp effect effect is lowered and looped is continued, or a pattern in which the decorative lamp is repeatedly turned on and off is continued. Is.

Even in this way, even if the customer waiting demo command cannot be received (missing) at the timing T3 shown in FIG. 17C, the symbol stop lamp effect will continue to be executed. Therefore, by continuing to execute the symbol stop lamp effect, even if the liquid crystal display device 41 does not display a "command reception error" or the like, it is possible to inform the employees of the amusement park who understand the error specifications. It is possible to notify that a command reception error has occurred.

Further, in a state where the customer waiting demo command cannot be received and the variable lamp effect continues to be executed in a loop, at the timing T4 shown in FIG. 17 (b), the effect control command DI_CMD is used as a decorative symbol (special symbol). When a fluctuation pattern command (for example, A001H) of the fluctuation pattern (for example, loss pattern 1) and a symbol designation command (for example, BB01H) for designating a decorative symbol (special symbol) (for example, loss symbol) are received, a loop is performed. The variable lamp effect that is being executed is not stopped, but is executed in a loop as it is. As a result, when shifting from the error state to the normal gaming state, the player can play the game without feeling uncomfortable.

Even if the game state shifts to the customer waiting demo state triggered by the symbol stop command, the same processing is performed.

Next, the sub-control CPU 800a restores the register saved in the process of step S1150 (step S1156). As a result, the process returns to the main process shown in FIG.

<Sub-control: command list>
Here, the command list generated in step S1050 shown in FIG. 45 will be described in detail with reference to FIG. 48.

This command list is a command sequence in which commands for VDP803 (command parser 8035) are listed, and the description contents and description order are slightly different depending on whether a moving image is instructed or a still image is instructed. It's different.

When instructing the VDP 803 to draw a moving image, the initial command list shown in FIG. 48 (a) and the stationary command list shown in FIG. 48 (b) are configured.

As shown in FIG. 48A, the sub-control CPU 800a first generates a command for setting the memory area of the DDR2 SDRAM 804 in which the frame buffer area is set and the memory area for storing the moving image data of the DDR2 SDRAM 804 (. Step S1200). In setting the memory area of the DDR2 SDRAM 804 in which the frame buffer area is set, the image size data PS_DATA112 shown in FIG. 10C is referred to. That is, if the size is, for example, 640 × 320, the memory area corresponding to the size is set.

Next, a command for instructing the decoding of the moving image is generated (step S1201). Specifically, it is an instruction as to which video compressed data is to be decoded, and the address address of the CG data storage area 805a of the game ROM 805 shown in FIGS. 20 and 23 in which the corresponding video is stored and the number of frames of the video. Instruct with such as. For the address address of the CG data storage area 805a in which the corresponding moving image is stored, the address data PS_DATA111 shown in FIG. 10C is referred to, and the number of frames of the moving image is the frame data shown in FIG. 10B. PS_DATA10 is referenced.

Next, the end processing command is entered to finish the generation of the initial command list (step S1202).

Subsequently, the sub-control CPU 800a generates the stationary command list shown in FIG. 48 (b).

As shown in FIG. 48 (b), this stationary command list is composed of moving image drawing instructions, and in the above initial command list, the decoded data of which frame number is displayed on the liquid crystal display device 41 with respect to the decoded moving image data. A command for drawing at which coordinate position of the throat is generated (step S1203). Next, a command for termination processing is entered to complete the generation of the steady-state command list (step S1204). For the command generation for this drawing instruction, the frame data PS_DATA10, the coordinate data PS_DATA12, the pixel calculation data PS_DATA13, and the scaling data PS_DATA14 shown in FIG. 10B are referred to.

On the other hand, when instructing the VDP 803 to draw a still image, as shown in FIG. 48 (c), the sub-control CPU 800a first stores the memory area of the DDR2 SDRAM 804 in which the frame buffer area is set, and the still image data. A command for setting the memory area of the built-in VRAM8040 is generated (step S1210). In setting the memory area of the DDR2 SDRAM 804 in which the frame buffer area is set, the image size data PS_DATA112 shown in FIG. 10C is referred to. That is, if the size is, for example, 640 × 320, the memory area corresponding to the size is set.

Next, a command for instructing the decoding of the still image is generated (step S1211). Specifically, it is an instruction as to which still image compressed data is to be decoded, such as the address address and data size of the CG data storage area 805a of the game ROM 805 shown in FIGS. 20 and 23 in which the corresponding still image is stored. Instruct with. For the address address of the CG data storage area 805a in which the corresponding still image is stored, the address data PS_DATA111 shown in FIG. 10C is referred to, and the data size is the image size data PS_DATA112 shown in FIG. 10C. Is referenced.

Next, a command for drawing the decoded still image data at which coordinate position of the liquid crystal display device 41 in what mode (rotation angle, reduction / enlargement, etc.) is generated (step S1212). Next, a command for end processing is entered to complete the generation of the command list related to the still image (step S1213). For the command generation for this drawing instruction, the frame data PS_DATA10, the coordinate data PS_DATA12, the pixel calculation data PS_DATA13, and the scaling data PS_DATA14 shown in FIG. 10B are referred to.

Thus, the command list related to such a moving image and the command list related to a still image are transmitted to the VDP 803 (see FIG. 11), appropriately processed, and then transmitted to the liquid crystal display device 41. As a result, a desired image (for example, FIGS. 17 to 19) is displayed on the liquid crystal display device 41.

Specifically, at the timing T1 shown in FIG. 17B, as the effect control command DI_CMD, a start hold subtraction command (for example, B001H) in which the number of start hold balls is subtracted from 1 to 0, and a decorative symbol (special). When a fluctuation pattern command (for example, A001H) for a fluctuation pattern (for example, a loss pattern 1) of a symbol) and a symbol designation command (for example, BB01H) for designating a decorative symbol (special symbol) (for example, a loss symbol) are received, The variable image is displayed on the liquid crystal display device 41.

Further, when a symbol stop command (for example, BF01H) for stopping the special symbol is received as the effect control command DI_CMD at the timing T2 shown in FIG. 17 (b), the image in which the variation of the decorative symbol (special symbol) is stopped is displayed. It will be displayed on the liquid crystal display device 41. The image in which the variation of the decorative symbol (special symbol) has stopped is continuously displayed on the liquid crystal display device 41.

Thus, in this way, at the timing T3 shown in FIG. 17 (b), even if the customer waiting demo command cannot be received (missing), the image in which the variation of the decorative symbol (special symbol) has stopped is displayed on the liquid crystal display. It will continue to be displayed on the device 41. Therefore, by continuing to display the image in which the fluctuation of the decorative symbol (special symbol) has stopped, the game understands the error specifications without displaying a "command reception error" on the liquid crystal display device 41. It is possible to notify the employees of the field that a command reception error has occurred.

Further, in a state where the customer waiting demo command cannot be received and the image in which the fluctuation of the decorative symbol (special symbol) is stopped is continuously displayed, the decoration is performed as the effect control command DI_CMD at the timing T4 shown in FIG. 17 (b). A variation pattern command (for example, A001H) for a variation pattern (for example, a loss pattern 1) of a symbol (special symbol), and a symbol designation command (for example, BB01H) for designating a decorative symbol (special symbol) (for example, a loss pattern). Upon reception, the liquid crystal display device 41 displays the variation image in which the variation of the decorative symbol (special symbol) is started from the image in which the variation of the decorative symbol (special symbol) is stopped. As a result, when shifting from the error state to the normal gaming state, the player can play the game without feeling uncomfortable.

On the other hand, when the customer waiting demo command is not provided and the game state shifts to the customer waiting demo state triggered by the symbol stop command, the effect control command DI_CMD is used at the timing T10 shown in FIG. 18 (b). A start hold subtraction command (for example, B001H) in which the number of start hold balls is subtracted from 1 to 0, a change pattern command (for example, A001H) for a change pattern (for example, loss pattern 1) of a decorative symbol (special symbol), When a symbol designation command (for example, BB01H) for designating a decorative symbol (special symbol) (for example, a lost symbol) is received, the variable image is displayed on the liquid crystal display device 41.

In this variation image, the variation of the decorative symbol (special symbol) is displayed, but since the variation time (for example, 120 seconds) of the decorative symbol (special symbol) is fixed, the determined variation time (for example, 120 seconds) is determined. , 120 seconds, etc.), the fluctuation of the decorative symbol (special symbol) will be swaying.

The fluctuation of the decorative symbol (special symbol) is stopped when the sub-control CPU 800a receives the symbol stop command (for example, BF01H). However, assuming that the symbol stop command (for example, BF01H) could not be received by the sub-control CPU 800a, the fluctuation of the decorative symbol (special symbol) is displayed on the liquid crystal display device 41 in a loop state. It becomes.

Thus, in this way, even if the symbol stop command cannot be received (missing) at the timing T11 shown in FIG. 18B, the image in which the decorative symbol (special symbol) is swaying and fluctuating is displayed on the liquid crystal display. It will be displayed on the device 41 in a loop state. Therefore, by continuing to display the image in which the decorative design (special design) is swaying and fluctuating in a loop state, the error specifications can be understood without displaying a "command reception error" on the liquid crystal display device 41. It is possible to notify the employees of the amusement park, etc., that a command reception error has occurred.

By the way, in a state where the symbol stop demo command cannot be received and the image in which the decorative symbol (special symbol) is swaying and fluctuating is continuously displayed in a loop state, the effect control command is displayed at the timing T13 shown in FIG. 18 (b). As DI_CMD, a pattern designation command (for example, a loss pattern) for designating a variation pattern (for example, loss pattern 1) of a decorative symbol (special symbol), a variation pattern command (for example, A001H), and a decoration symbol (special symbol) (for example, a loss pattern) , BB01H), the variable image is displayed on the liquid crystal display device 41. As a result, the image in which the decorative symbol (special symbol) is swaying and fluctuating is continuously displayed in a loop state, but the fluctuation image is displayed on the liquid crystal display device 41 when the game ball is won. As a result, when shifting from the error state to the normal gaming state, the player can play the game without a sense of discomfort.

On the other hand, when the effect control command DI_CMD, which is a start hold subtraction command for subtracting the number of start hold balls from 3 to 2, cannot be received by the sub control CPU 800a, the speed is high as shown in FIG. 19 (a-5). The fluctuating decorative symbol (special symbol) is displayed (see image P4), and the state in which three start-holding balls are held is displayed as it is (see image P1). That is, the number of start-holding balls actually stored in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c does not match the number of start-holding balls displayed on the liquid crystal display device 41. ..

Then, as shown in FIG. 19 (c-1), the state in which three start holding balls are held is continuously displayed (see image P1), and the decorative symbol (special symbol) fluctuating at high speed changes. , As shown in FIG. 19 (c-2), the stop (in the figure, the combination symbol is stopped in a lost state of "123") (see image P7). After that, as the effect control command DI_CMD, the start hold subtraction command (for example, B002H) in which the number of start hold balls is subtracted from two to one, and the variation pattern (for example, loss pattern 1) of the decorative symbol (special symbol) When a variable pattern command (for example, A001H) or a symbol designation command (for example, BB01H) for designating a decorative symbol (special symbol) (for example, a lost symbol) is received, the speed is high as shown in FIG. 19 (c-3). A fluctuating decorative pattern (special pattern) is displayed (see image P8). Further, the liquid crystal display device 41 instantly displays a state in which two balls are held as start holding balls (see image P11). At this time, instead of displaying an animation on the liquid crystal display device 41 in which the number of start-holding balls is subtracted from three to one, and the number of start-holding balls is subtracted, three are held as start-holding balls. The display will be instantly switched from the state in which the display is on to the state in which two are held.

Then, from this state, an animation in which the number of start-holding balls is subtracted from two to one is erased to one, and as shown in FIG. 19 (c-4), the liquid crystal is displayed. The display device 41 displays an animation (see image P12) in which the number of start-holding balls is subtracted so that the number of start-holding balls is erased from two to one (see image P12). ), A state in which one ball is held as a start holding ball is displayed (see image P13). As a result, the number of start-holding balls actually stored in the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c matches the displayed number of start-holding balls.

By doing so, the player is accustomed to instantly switching the display from the state in which the number of start-holding balls is held to 3 to the state in which 2 are held, and the number is subtracted from 2 to 1. Since the animation is displayed, it is possible to return to the start hold display in which the normal number of start hold balls is displayed without giving the player a great sense of discomfort. As a result, the player can continue the game without feeling unnatural. Further, it is not necessary to separately prepare an animation in which the number of start-holding balls is subtracted from the number of start-holding balls of 3 to 1 by erasing 2 pieces.

By the way, in such a command list, after instructing the drawing of a moving image, the drawing of a still image is instructed. That is, the sub-control CPU 800a uses the effect control command DI_CMD transmitted from the main control CPU 600a to produce any one of the plurality of effect scenario data PS_DATA stored in the effect scenario table PR_TBL shown in FIG. 10 (a). This is because the scenario data PS_DATA is selected, the one-layer data PS_DATA1 stored in the selected effect scenario data PS_DATA is referred to in order from the lowest priority, and a command list is generated. That is, according to the present embodiment, the control code data such that the data PS_DATA110 (see FIG. 10 (c)) showing the moving image is referred to from the control table CH_TBL shown in FIG. 10 (c) at the position where the priority is low. PS_DATA11 is stored, and control code data PS_DATA11 such that data PS_DATA110 (see FIG. 10C) indicating a still image is referred to from the control table CH_TBL shown in FIG. 10C is stored at a position having a high priority. Therefore, the command list instructing the drawing of the moving image is generated first, and then the command list instructing the drawing of the still image is generated. As a result, after the moving image data is drawn, the still image data is overwritten and drawn on the drawn moving image data, and thus the image data displayed on the liquid crystal display device 41 is generated.

By overwriting the still image data on the drawn moving image data in this way, the image data is generated, so that the characters can be clearly displayed even in the compressed image.

Thus, according to the present embodiment described above, it is possible to reduce the possibility that the game is restarted while the game may be affected.

Further, according to the present embodiment, the limited program capacity can be efficiently used.

Further, according to the present embodiment, the efficiency of development can be improved.

Further, according to the present embodiment, it is possible to efficiently perform control and flexibly respond to data changes due to development.

In this embodiment, only an example in which the measurement / setting display device 610 is lit and displayed is shown as a display method, but the present invention is not limited to this, and the display of the measurement / setting display device 610 is blinked while the setting is being changed. You may do so.

Further, in the present embodiment, the sound LSI 801 and the VDP 803 are separately configured, but they may be integrated as one chip.

Further, in the present embodiment, the frame buffer area is set in the DDR2 SDRAM 804, but the present invention is not limited to this, and the frame buffer area may be set in the built-in VRAM 8040.

Further, in the present embodiment, the example in which the sub-control CPU 800a is provided in the sub-one-chip microcomputer 800 is shown, but the present invention is not limited to this, and the sub-control CPU 800a may be provided in the VDP 803.

Further, in the present embodiment, an example in which the setting change process is performed by the main process of the main control is shown, but the present invention is not limited to this, and the timer interrupt process of the main control may be used. This point will be specifically described with reference to FIGS. 49 to 53. The main processing of the main control and the same processing as the timer interrupt processing of the main control described above are designated by the same reference numerals, and the description thereof will be omitted.

<Main control: Description of main processing according to other embodiments>
Explaining the difference from the main processing shown in FIGS. 24 and 25, as shown in FIG. 49, the main control CPU 600a is a work area of the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c. Make initial settings (step S12A). Specifically, 00H is set in the power supply abnormality confirmation counter. Further, the main control CPU 600a includes a door opening signal indicating whether the upper opening / closing door 7 and the lower opening door 8 are open, and a working area of the normal RAM area 600ca (see FIG. 9A) of the main control RAM 600c. The signal of the RAM clear switch 620 and the signal of the setting key switch 630 saved in the above are acquired (step S17), and it is confirmed whether or not all of them are turned on (step S18). If all are ON (step S18: YES), the backup flag is cleared (step S1A), 02H is set in the system operation status (step S1B), and then the process proceeds to step S20 shown in FIG. It becomes.

On the other hand, as shown in FIG. 50, the main control CPU 600a acquires a door opening signal indicating whether the upper opening / closing door 7 and the lower opening door 8 are open, and a signal of the setting key switch 630 (step S30). , Check whether all are ON (step S31). If all are ON (step S31: YES), 01H is set in the system operation status (step S1C), and the process proceeds to step S40.

<Main control: Explanation of timer interrupt processing according to another embodiment>
Next, with reference to FIG. 51, a timer interrupt program that interrupts the above-mentioned main processing and is started every 4 ms will be described. Explaining the difference from the timer interrupt process shown in FIG. 28, the main control CPU 600a confirms the value of the system operation status after completing the switch input management process (step S102) (step S100A).

If the value of the system operation status is "0" (step S100A: = 0), the main control CPU 600a proceeds to the process of step S103.

<Main control: Timer interrupt processing according to another embodiment: Explanation of setting confirmation processing>
On the other hand, if the value of the system operation status is "1" (step S100A: = 1), the main control CPU 600a transmits a set value command (effect control command DI_CMD) reflecting the set value to the sub control board 80 (effect control command DI_CMD). Step S100B). The setting value command (effect control command DI_CMD) transmission process that reflects this set value is called by the CALL_S command and processed.

Next, the main control CPU 600a sets the security signal output to the hall computer (not shown) used for managing the game islands of the game field to ON via an external terminal (not shown) (step S100C), and sets the setting key. It is confirmed whether or not the switch 630 is OFF (step S100D). If the setting key switch 630 is not OFF (step S100D: NO), the process proceeds to step S100T, and if the setting key switch 630 is OFF (step S100D: YES), the process proceeds to step S100E.

On the other hand, if the setting key switch 630 is OFF (step S100D: YES), the main control CPU 600a sets 00H to the system operation status (step S100E), and manages the game islands of the amusement park via an external terminal (not shown). The timer for outputting the security signal output to the hall computer (not shown) used for is set to 30 seconds (30 s) (step S100F). As a result, a security signal is output to a hall computer (not shown) used for managing the game islands of the game field via an external terminal (not shown) for 30 seconds (30 s). The main control CPU 600a will proceed to the process of step S100T after the process of step S100F.

<Main control: Timer interrupt processing according to another embodiment: Description of setting change processing>
On the other hand, if the value of the system operation status is "2" (step S100A: = 2), a setting switching start command (effect control command DI_CMD) indicating that the setting is being changed is transmitted to the sub control board 80 (step). S100G). The setting switching start command (effect control command DI_CMD) transmission process indicating that the setting is being changed is called by the CALL_S command and processed.

Next, the main control CPU 600a is stored in the main control RAM 600c (see FIG. 7), and is stored in the main control RAM 600c (see FIG. 7). (Set values of "05H") and set in the W register (step S100H).

Next, the main control CPU 600a compares the value set in the W register with the set maximum value of the probability of generating a special gaming state advantageous to the player (for example, "05H" corresponding to "6") (step S100I). .. Then, if the value set in the W register of the main control CPU 600a is larger than the set maximum value of the probability of generating a special gaming state advantageous to the player (for example, "05H" corresponding to "6") (step S100J: YES), it is determined that the value is abnormal, and 00H is set in the W register (step S100K).

On the other hand, if the value set in the W register is smaller than the set maximum value of the probability of generating a special gaming state advantageous to the player (for example, "05H" corresponding to "6") (step S100J: NO), it is a normal value. The security signal output to the hall computer (not shown) used for managing the game islands of the amusement park is set to ON via an external terminal (not shown), and the security signal is set to ON via an external terminal (not shown). , Output to a hall computer (not shown) (step S100L).

Next, the main control CPU 600a sets the value of the W register as a set value of the probability of generating a special gaming state advantageous to the player (for example, "1" to "6") stored in the main control RAM 600c (see FIG. 7). (Set values of "00H" to "05H" corresponding to "") are overwritten and stored (step S100M).

Next, the main control CPU 600a confirms the setting key switch 630 (step S100N), if it is OFF (step S100N: YES), proceeds to the process of step S100Q, and if it is ON (step S100M: NO), clears the RAM. Check the switch 620 (step S100O). If the RAM clear switch 620 is ON (step S100O: YES), the value of the W register is incremented (+1) (step S100P), and the process returns to step S100I.

On the other hand, if the RAM clear switch 620 is OFF (step S100O: NO), the process proceeds to step S100T.

Thus, the above process is repeated until the setting key switch 630 is turned off, and when the setting key switch 630 is turned off, the process proceeds to confirm the setting. That is, the main control CPU 600a outputs the setting confirmation display to the LED data port (step S100Q). As a result, a value indicating the setting confirmation display is output from the second LED dynamic lighting data signal 611c2 shown in FIG. 8, and thus, the first measurement / setting display device 610A of the measurement / setting display device 610 shown in FIG. The dot on the lower right side of the 7-segment lights up, and it is displayed that the setting contents have been confirmed.

Next, the main control CPU 600a transmits a setting switching end command (effect control command DI_CMD) reflecting the set value to the sub control board 80 (step S100R). The setting switching end command (effect control command DI_CMD) transmission process that reflects this set value is called by the CALL_S command and processed.

Next, the main control CPU 600a sets 00H to the system operation status (step S100S) and performs the LED management process (step S100T).

<Main control: Timer interrupt processing according to another embodiment: Description of LED processing>
This LED management process will be specifically described with reference to FIG. 52. The main control CPU 600a clears the LED common port and the LED data port (step S500A), and updates the LED output counter (step S501A).

Next, the main control CPU 600a confirms the value of the system operation status (step S502A). If the value of the system operation status is "0" (step S502A: = 0), the LED common output selection table 0 is selected (step S503A), and the LED data port 0 is selected (step S504A). The LED common output selection table 0 is programmed as shown in FIG. 53 (a).

Specifically, the destination where the LED data is output is the special symbol 1 display device 50a (see FIG. 5), and the common data for outputting the LED data to the special symbol 1 display device 50a (see FIG. 5). And are programmed as follows.
DB 0001 0001B
DW D_MKLED0, D_MKLED0

Next, the destination where the LED data is output is the special symbol 2 display device 50b (see FIG. 5), and the common data for outputting the LED data to the special symbol 2 display device 50b (see FIG. 5). It is programmed as follows.
DB 0010 0010B
DW D_MKLED1, D_MKLED1

Next, the destination where the LED data is output is the 7-segment display device 52a (see FIG. 5), and the common data for outputting the LED data to the 7-segment display device 52a (see FIG. 5) are as follows. Is programmed to.
DB 0100 0100B
DW D_MKLED2A, D_MKLED2B

Next, the destination to which the LED data is output is the normal symbol display device 51 (see FIG. 5), the right-handed notification lamp 52c (see FIG. 5), the round lamp 52b (see FIG. 5), and the normal symbol display device. The common data for outputting LED data to the 51 (see FIG. 5), the right-handed notification lamp 52c (see FIG. 5), and the round lamp 52b (see FIG. 5) are programmed as follows.
DB 1000 1000B
DW D_MKLED3, D_MKLED3

By the way, as for the common data to be output, of the 8-bit signals, the 4 bits in the previous stage are output from the first LED dynamic lighting common data signal 611a2 (see FIG. 8) (in FIG. 53 (a), it is described as common 00 to 04). , The latter 4 bits are output from the second LED dynamic lighting common data signal 611a3 (see FIG. 8) (in FIG. 53 (a), they are described as commons 10 to 13). Therefore, in the present embodiment, the common data is output from the same port. This is because when trying to output different common data from the same port, the LED does not light normally unless one of the common data is reflected and output.

That is, in order to output "1" from the first LED dynamic lighting common data first signal 611a2a (see FIG. 8) of the first LED dynamic lighting common data signal 611a2, "0000 0001" is output from the port and then the second LED dynamic. When "0001 0000" is output from the port in order to output "1" from the second LED dynamic lighting common data first signal 611a3a (see FIG. 8) of the lighting common data signal 611a3, the first LED dynamic lighting common data signal 611a2 First LED dynamic lighting common data The data of the first signal 611a2a (see FIG. 8) is cleared. As a result, the LED does not light normally, so that data must be newly output to the first LED dynamic lighting common data first signal 611a2a (see FIG. 8) of the first LED dynamic lighting common data signal 611a2.

Therefore, in the present embodiment, the common data is output together in advance, and the LED data is output to the measurement / setting display device 610 later. Even in this way, the LED will light up without any problem in appearance.

On the other hand, if the value of the system operation status is "1" (step S505A: = 1), the main control CPU 600a selects the LED common output selection table 1 (step S505A) and selects the LED data port 1 (step S505A). S506A). The LED common output selection table 1 is programmed as shown in FIG. 53 (b).

Specifically, the destination where the LED data is output is the first digit data (first measurement / setting display device 610A) of the seven segments, and the first digit data (first measurement / setting). The common data for outputting the LED data to the display device 610A) is programmed as follows.
DB 0001 0000B
DW D_7SEG, D_7SEG

Next, the destination where the LED data is output is the second digit data of the 7 segment (second measurement / setting display device 610B), and the second digit data (second measurement / setting display device 610B). The common data for outputting the LED data to) is programmed as follows. It should be noted that this program is a program for displaying nothing on the second measurement / setting display device 610B.
DB 0010 0000B
DW 0000H, 0000H

Next, the destination where the LED data is output is the third digit data (third measurement / setting display device 610C) of the seven segments, and the third digit data (third measurement / setting display device 610C). The common data for outputting the LED data to) is programmed as follows. It should be noted that this program is a program for displaying nothing on the third measurement / setting display device 610C.
DB 0100 0000B
DW 0000H, 0000H

Next, the destination where the LED data is output is the 4th digit data (4th measurement / setting display device 610D) of the 7 segment, and the 4th digit data (4th measurement / setting display device 610D). The common data for outputting the LED data to) is programmed as follows. It should be noted that this program is a program for displaying nothing on the fourth measurement / setting display device 610D.
DB 1000 0000B
DW 0000H, 0000H

On the other hand, if the value of the system operation status is "2" (step S507A: = 1), the main control CPU 600a selects the LED common output selection table 1 (step S507A) and selects the LED data port 1 (step S507A). S508A).

Thus, when any of the processes of step S504A, step S506A, and step S508A is completed, the main control CPU 600a selects the output data from the LED output counter and the selected LED common output selection table (step S509A), and then the LED. Data is output to the common port (step S510A). As a result, for example, if it is selected in step S509A that the destination to which the LED data is output is the special symbol 1 display device 50a (see FIG. 5), "0001 0001" is output in step S510A. The Rukoto. As a result, the first LED dynamic lighting common data first signal 611a2a (see FIG. 8) of the first LED dynamic lighting common data signal 611a2 and the second LED dynamic lighting common data second signal 611a3a of the second LED dynamic lighting common data signal 611a3 (see FIG. 8). (See FIG. 8), "1" will be output.

Next, the main control CPU 600a creates the output destination LED data of the selected LED common (step S511A). For example, if it is selected in step S509A that the destination to which the LED data is output is the special symbol 1 display device 50a (see FIG. 5), the LED to be displayed on the special symbol 1 display device 50a (see FIG. 5) is displayed. Data will be created.

Next, the main control CPU 600a outputs the created LED data to the selected LED data port (step S512A). As a result, the data created from the first LED dynamic lighting data signal 611b2 (see FIG. 8) is output. For example, in the case of LED data to be displayed on the special symbol 1 display device 50a (see FIG. 5), the data is output to the special symbol 1 display device 50a (see FIG. 5), and thus the special symbol 1 display device 50a (see FIG. 5) is output. The output data will be displayed in (see 5).

<Main control: Explanation of timer interrupt processing according to another embodiment>
Thus, after completing the LED management process (step S100T shown in FIG. 51) as described above, the main control CPU 600a proceeds to the process of step S116 shown in FIG. 51. The LED management process in step S112A shown in FIG. 51 is the same as the LED management process shown in FIG. 52.

Then, if the processing is performed in this way, the setting change processing can be performed by the timer interrupt processing of the main control. Therefore, even with such a process, it is possible to reduce the possibility that the game is restarted while the game may be affected, and the limited program capacity is efficiently used. can do.

1 Pachinko game machine 60 Main control board 610 Measurement / setting display device 610A First measurement / setting display device (display means)
620 RAM clear switch (setting operation means)
630 Setting key switch 1310 Voltage monitoring unit (voltage monitoring means)

Claims (1)

A main control means that can collectively control game operations and send predetermined control commands,
When a plurality of types of identification information are variablely displayed when a predetermined start condition is satisfied, the right to perform a variable display of the identification information for which the start condition is satisfied but has not been started is stored up to a predetermined upper limit. Means and
Sub-control means that controls various production operations based on receiving the predetermined control command, and
It has a display means for displaying various images including decorative patterns, and has.
In a state where the number of the first rights is stored in the reserved storage means and the number of the first rights is displayed in the display means.
The holding command indicating that the variable display of the identification information is started and the number of the first rights stored in the holding storage means is subtracted from the number of the second rights and the number of the second rights is reached, and the variable pattern command are the main ones. If the sub-control means can receive the variation pattern command but cannot receive the hold command even though it has been transmitted from the control means, the display means is given the number of the second rights. Without displaying, the decorative pattern is variablely displayed while the number of the first rights is displayed.
When the number of the second right is stored in the hold storage means and the variable display of the identification information is started while the number of the first right is still displayed on the display means, the hold A hold command indicating that the number of the second right is subtracted from the number of the second right stored in the storage means to reach the number of the third right, and a variation pattern command are transmitted from the main control means, and the hold command and the hold command When the variation pattern command is received by the sub-control means, the display means displays the number of the first rights instead of subtracting the number of the first rights from the displayed state. of the number of rights on which is switched and displayed, to display the animation corresponding to the subtracted from the state of displaying the number of the second rights to a few of the third right, of the decorative pattern A game machine that displays fluctuations.

Images