JP6785436B2 - Game machine - Google Patents

Description

The present invention relates to a game machine such as a slot machine or a pachinko game machine in which a game medium is inserted, a reel is rotated and then stopped, and a game result is determined by a combination of symbols drawn on the reel displayed at that time. ..

Conventionally, a slot machine (rotary cylinder type game machine) has been known as one of the game machines. In this slot machine, a player inserts a game medium such as a game medal, and operates a start lever to rotate a plurality of reels on which a pattern is drawn. After that, the player operates the stop button to stop each round cylinder, and depending on the combination of the stopped symbols (display result), it is possible to receive a predetermined number of game medals and the like. Further, in the slot machine, in addition to such a basic game, various effects are performed to improve the taste as a whole.
JP-A-2017-018540

By the way, in this type of slot machine, individual basic operations such as acceptance of insertion of game media (game medals, etc.), rotation of reels, production control, stop of rotation, and withdrawal of game medals, etc. Is repeated as the operation of. It is desirable that these operations be performed properly in any case, but it is conceivable that unexpected operations may be performed when various situations occur in combination. Therefore, it is effective to assume as many complex situations as possible and to decide in advance what kind of operation is to be performed at that time.

The present invention has been made in view of these problems, and an object of the present invention is to provide a gaming machine capable of smooth control even when various situations are combined.

In order to solve the above problems, the present invention
With reel
With the start switch
With a stop switch
Equipped with internal lottery means
When the start switch is operated, the acceleration process for rotating the reel can be executed for a predetermined period of time .
If an event occurs in which the power supply to the game machine is cut off and then a power outage is detected, the power outage processing can be executed.
If the acceleration process for rotating the specific reel is started, the power supply cutoff process is executed by the elapse of the predetermined period, and then the power is restored after the specific reel is stopped, the rest of the predetermined period. It is configured so that the acceleration process for rotating the specific reel can be continuously executed during the period of.
A predetermined result is determined as a determination result of the internal drawing means, and an operation of a predetermined stop switch for first stopping the predetermined reel in a situation where all the reels are rotating is detected at a predetermined timing. When the predetermined symbol corresponding to the predetermined result is stopped at the predetermined position and then all the reels are stopped and the predetermined symbol combination corresponding to the predetermined result is stopped in the predetermined situation, the predetermined symbol combination is used. It is configured to be able to grant the corresponding game medium,
The predetermined result is determined as the determination result of the internal lottery means, and the operation of the predetermined stop switch for first stopping the predetermined reel in a situation where all the reels are rotating is performed at the predetermined timing. The predetermined symbol corresponding to the predetermined result in a predetermined situation in which the predetermined symbol corresponding to the predetermined result is not stopped at the predetermined position and all the reels are subsequently stopped despite being detected. The game machine is characterized in that it is configured so that a game medium corresponding to the predetermined symbol combination can be applied even when the combination is not stopped.
Further, the present invention includes a game control means (main control board, etc.) for controlling the progress of the game.
It is equipped with display control means (sub-control board, etc.) that controls the effect display related to the game.
The game control means can perform a freeze process (freeze effect, etc.) for a predetermined time when ending a predetermined game state that is advantageous to the player.
The display control means can display an effect based on display data (special state start display, special state end display, etc.) as an effect to be displayed when the freeze process is being performed.
The display data includes at least the first display data and the second display data.
In the situation where the power is restored after the power is cut off during the freeze process and during the display of the effect based on the first display data (the effect in the special state start display), the freeze process that was performed before the power is turned off. The display control means may be a gaming machine characterized in that an effect based on the second display data (an effect in the start / end waiting display) is displayed.

According to the present invention, it is possible to provide a gaming machine capable of smooth control even when various situations are combined.

It is a perspective view of the slot machine which concerns on one Example of this invention. It is a perspective view of the slot machine with the front door part open. It is a rear view of the front door part. It is a front view which shows the inside of the housing part. (A) is a block diagram schematically showing an electrical configuration of each control board, and (b) is an explanatory diagram showing an outline of a component configuration in the main control board. It is a perspective view which shows the game medal selector. It is a perspective view which shows the game medal selector open. (A) is a chart showing the detection modes of the insertion sensors 1 and 2 when the game medal is normally inserted, (b) is a chart showing other detection modes of the insertion sensors 1 and 2 that are not regarded as errors, and (c) is It is a timing chart which shows the detection mode of a C0 error. (A) is a timing chart showing a C1 error detection mode, and (b) is a timing chart showing a CH error detection mode. It is a timing chart which shows the detection mode of a CE error. It is explanatory drawing which shows the memory map which concerns on the main CPU. It is a flowchart which shows the process at the time of power-on in the main control board. It is a flowchart which shows the setting change apparatus processing in a main control board. It is a flowchart which shows the game progress main process in a main control board. It is a flowchart which shows the process of starting an internal lottery. It is a flowchart which shows the processing of a condition device command set. It is a flowchart which shows the display determination process. It is a flowchart which shows the timer interrupt processing in a main control board. It is a flowchart which shows the power-off processing in a main control board. It is a flowchart which shows the process of error management. It is a flowchart which shows the power restoration process. It is a flowchart which shows the game medal acceptance start processing. (A) is a flowchart showing the blocker ON process, and (b) is a flowchart showing the blocker OFF process. It is a flowchart which shows the error display processing. It is a flowchart which shows the input error set processing. It is a flowchart which shows the game medal management process. It is a flowchart which shows the storage input process. It is a flowchart which shows the game medal clearing process. It is a flowchart which shows the unrecoverable error processing. It is a flowchart which shows the process of RWM initialization 2 in the 2nd control. It is a flowchart which shows the process of RWM initialization 3 in the 2nd control. It is a flowchart which shows the process of the serial communication setting in the 2nd control. It is a flowchart which shows the processing of the symbol stop signal output in the 2nd control. It is a flowchart which shows the processing of the symbol stop signal set in the 2nd control. It is a flowchart which shows the process of the test signal output in the 2nd control. It is a flowchart which shows the process of the input / withdrawal sensor abnormality set in the 2nd control. It is a flowchart which shows the process of clearing the input / payout sensor abnormality in the 2nd control. It is a flowchart which shows the error check process in the 2nd control. It is a flowchart which shows the process of the setting value error check in the 2nd control. It is a flowchart which shows the process of the built-in random number check in the 2nd control. It is a flowchart which shows the process of the timer measurement 2 in the 2nd control. It is a flowchart which shows the process of the game medal insertion check in the 2nd control. It is a flowchart which shows the process of the game medal insertion check following FIG. 42. It is a flowchart which shows the process of the game medal passing state update in the 2nd control. It is a flowchart which shows the process of the input / withdrawal sensor abnormality check in the 2nd control. It is a flowchart which shows the process of the input / withdrawal sensor abnormality check following FIG. It is a flowchart which shows the process of clearing the error display request data in the 2nd control. It is a flowchart which shows the process of the 8-bit random number check in the 2nd control. It is a flowchart which shows the non-recoverable error processing 2 in the 2nd control. (A) is a timing chart showing an example of a management mode related to the minimum game time in the normal time, and (B) is a timing chart showing an example of the management mode related to the minimum game time at the time of a recoverable error. (A) is a timing chart showing an example of a management mode related to the minimum game time at the time of an unrecoverable error, and (B) is a timing chart showing an example of the management mode related to the minimum game time at the time of clearing a game medal. (A) is a timing chart showing an example of a management mode related to the minimum game time when a game medal is inserted, and (B) is a timing chart showing an example of a management mode related to the minimum game time when confirming a set value. It is a timing chart which shows the relationship between the minimum game time and a test signal output. (A) to (c) are charts showing the first to third correspondences when a power failure occurs. (A) to (d2) are charts showing the fourth to seventh correspondences when a power failure occurs. (A) and (b) are charts showing the first response and the second response when an error occurs. It is a flowchart which shows the input / payout sensor abnormality display processing in the 1st control. (A) is a flowchart showing the basic operation related to the countermeasure pattern 1, (b) is a flowchart showing the countermeasure pattern 1-1 when a power-off situation occurs, and (c) is also a power-off situation. It is a flowchart which shows the measure pattern 1-2 which concerns on the case. (A) is a flowchart showing the basic operation related to the countermeasure pattern 2, (b) is a flowchart showing the countermeasure pattern 2-1 when a situation of poor rotation of the rotating cylinder occurs, and (c) is also a flowchart showing the defective rotation of the rotating cylinder. It is a flowchart which shows the countermeasure pattern 2-2 when the situation occurs. (A) is a timing chart showing an example of a change in the rotation speed of the rotating cylinder with respect to the countermeasure pattern 2 and the like, (b) is a timing chart showing the basic operation when the symbol is stopped with respect to the countermeasure pattern 3-2, and (c) is the same countermeasure pattern. It is a timing chart which shows the operation when a rotation failure occurs about 3-2. (A) is a flowchart showing the basic operation related to the countermeasure pattern 3, (b) is a flowchart showing the countermeasure pattern 3-1 when a rotation failure situation occurs, and (c) is also a rotation failure situation. It is a flowchart which shows the measure pattern 3-2 which concerns on the case. (A) is a timing chart showing a countermeasure pattern 3-1-1A related to the situation where the power is cut off while the third stop is pressed, and (b) is a countermeasure related to the situation where the power is cut off while the third stop is pressed. It is a timing chart which shows the pattern 3-1-1B. (A) is a timing chart showing the countermeasure pattern 4-7-1 related to the door opening notification sound and the payout sound, and (b) is a timing chart showing the countermeasure pattern 4-7-2 related to the door opening notification sound and the payout sound. Is.

<Outline of the slot machine according to this embodiment>

Hereinafter, the slot machine according to the embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows the appearance of the slot machine 10 according to the present embodiment from the front. The slot machine 10 is configured by combining the front door portion 11 shown in FIGS. 1 to 3 and the housing portion 12 shown in FIG. 4 in front of and behind the front door portion 11. The front door portion 11 is supported by the housing portion 12 via a hinge device, and can be locked in a closed state with respect to the housing portion 12.

On the front side (front side) of the front door portion 11, as shown in FIG. 1, an operation unit 14 is arranged in the middle stage in the vertical direction, and a rotating cylinder display unit 15 is arranged above the operation unit 14. .. Further, at the lower part of the front door portion 11, a game medal payout outlet 16 opened in a rectangular shape and a saucer 17 for receiving the game medals released from the game medal payout outlet 16 are arranged, and further, a rotating cylinder display portion 15 The production unit 18 is arranged above the above. Further, below the operation unit 14, a translucent lower panel 19 on which a model-specific name, a design image, or the like is drawn is provided.

Of these, the operation unit 14 is provided with a game medal insertion slot 21, a game medal return button 22, a lock portion 23 (also referred to as a lock portion), a stop button portion 24, a start lever 25, and the like. Further, a main input unit 26 and a sub input unit 27 are provided on the upper part of the operation unit 14, and the main input unit 26 is provided with a clearing button and a single input button (so-called 1BET), although the reference numerals are omitted. Buttons), three-sheet insertion buttons (so-called MAXBET buttons) are provided. Further, although not shown, the sub input unit 27 is provided with a cross key, a sub input switch, and the like.

The game medal insertion slot 21 is for inserting a game medal as a game medium via a guide, and the game medal return button 22 is used to return the game medal accumulated in the game medal selector (described later). It is used for. Further, the lock portion 23 is used by inserting a predetermined key when unlocking the front door portion 11, and the stop button portion 24 is used for three rotating cylinders (first cylinder 51L, which will be described later). It is used to stop the rotation of the 2nd cylinder 51C and the 3rd cylinder 51R).

The stop button unit 24 is provided with three stop buttons (first stop button 24L, second stop button 24C, third stop button 24R). These stop buttons 24L, 24C, 24R are associated with the respective cylinders 51L, 51C, 51R, and by individually pressing the stop buttons 24L, 24C, 24R, the corresponding cylinders 51L, 51C, 51R are operated. Is supposed to stop. In this embodiment, the first cylinder 51L to the third cylinder 51R are arranged from the left when viewed from the front of the slot machine 10, the first cylinder 51L, the second cylinder 51C, and the third cylinder 51R. The order is such that the stop buttons 24L, 24C, and 24R are arranged in the order of the first stop button 24L, the second stop button 24C, and the third stop button 24R from the left. The start lever 25 is also used when rotating the rotating cylinder and determining the set value (described later).

The clearing button in the main input unit 26 is used for refunding the inserted game medals and clearing the game medals stored in the storage device (described later). The 1-card insertion button is used when inserting the stored game medals one by one, and the 3-card insertion button is used.
It is used when a maximum of three stored game medals are inserted within the range not exceeding the number of stored game medals and the specified number related to insertion (described later). The sub-input switch in the sub-input unit 27 is for performing an operation related to the effect, and is used for switching display contents such as a liquid crystal screen provided in the effect unit 18 and for input related to the effect.

Further, although not shown, the operation unit 14 is provided with various display units that indicate the game content depending on whether or not the LED emits light, the display mode of the 7-segment (7-segment) display, and the like. Various display units showing the status of the game include an acquired number display unit, a stored number display unit, a re-game display unit, an input display unit, a stop display unit, a game start display unit, an input number display unit, and the like. In the vicinity of these various display units, characters are printed so that it is possible to know what kind of information display function each display unit has. Further, among these display units, the acquired number display unit and the stored number display unit have a function of displaying numbers, characters, etc. using a 7-segment display, and the other display units are LED-lit. Predetermined information is displayed depending on the presence / absence and the mode of lighting. The LEDs used as the light source in each display unit are described below as the acquired number display LED, the stored number display LED, the re-game display LED, the input display LED, the stop display LED, the game start display LED, and the input number display. It may be called an LED.

In addition, among various display units, the acquired number display unit can be used for any of the purposes of displaying the number of game medals according to the number of acquired medals, displaying when switching settings, and displaying an error code, depending on the situation. Used. The stored number display unit displays the number of game medals stored in the storage device, and the re-game display unit displays whether or not the re-game is activated. Further, the insertion display unit displays that the game medals can be inserted and accepted, and the stop display unit displays that the stored game medals are being settled. The game start display unit displays that the operation of the start lever 25 can be accepted while the game can be started. Further, the inserted number display unit displays the number of inserted game medals, and when the re-game is activated, the same number of game medals as the previous game is displayed.

The stop button unit 24 is provided with three stop buttons, a first stop button 24L, a second stop button 24C, and a third stop button 24R. Further, the reel display unit 15 is provided with a reel display panel 28 in which a display window opened in a rectangular shape is closed with a transparent panel, and the reel display panel 28 is seen through the reel display panel 28 in FIGS. 2 and 4. As shown in the above, the three reels of the first cylinder 51L to the third cylinder 51R housed in the housing portion 12 can be visually recognized. Further, the effect unit 18 is provided with a liquid crystal display device or the like, and the effect unit 18 displays the effect associated with the game.

Further, the front door portion 11 is provided with various light sources (LEDs) used for the effect. Examples of the light source for these effects include, although not shown, a three-sheet input display LED, a stop button LED, and a sub-input display LED. Of these, the three-sheet insertion display LED illuminates the three-sheet insertion button arranged in the main input unit 26 from the inside, and is used for displaying the effect content using the three-sheet insertion button. Further, the stop button LED illuminates the stop buttons 24L, 24C, 24R from the inside, and is used for displaying the effect content using the stop buttons 24L, 24C, 24R. Further, the sub-input display LED illuminates the sub-input switch arranged in the sub-input unit 27 from the inside, and is used for displaying the effect content using the sub-input switch.

In addition to these, as the light source for the production, although not shown, the upper part LED, the lower part LED, the side LED, the chance LED, the left wing LED, the lower left circle LED, the right wing LED, and the lower right circle There are LEDs, upper left circle LEDs, upper upper LEDs, upper right circle LEDs, AR lamp LEDs, lower panel lighting LEDs, left mini LEDs, right mini LEDs, V-shaped LEDs, and the like. Each light source is used to display the content of the effect according to its arrangement and function.

FIG. 3 shows the back side of the front door portion 11. Various boards, devices for handling game medals, various sensors, and the like are arranged on the back side of the front door portion 11. Among these, various boards include a sub control board 31, an image control board 32, an image display connection board 33, an audio board 34, a production rom (ROM) board 35, a switch sensor board 36, a display board 37, and a door relay terminal board. 38, a rotating cylinder lighting board 39, a lower panel lighting board 40, and the like are provided.

Of these, the sub-control board 31 is a board for controlling images for production, various solenoids, various LEDs, and sound effects. The sub-control board 31 is housed in a dedicated board case, and is attached to the front door portion 11 by screwing the board case to the front door portion 11.

The image control board 32 mounts an audio board 34 and an effect rom board 35, which will be described later, and relays between the sub control board 31 and the image display connection board 33 to control an image and sound effects for effect. Is. The image control board 32 is housed in a dedicated board case, and is attached to the front door portion 11 by screwing the board case to the front door portion 11.

The image display connection board 33 is a board that relays between the image control board 32 and the liquid crystal display of the effect unit 18, and is fixed by being screwed into a screw hole provided in the front door part 11. .. The audio board 34 is a board to which a ROM in which audio data for production is stored is attached, and is fixed by being screwed into a screw hole provided in the image control board 32. The effect rom board 35 is a board to which a rom in which image data for effect is stored is attached, and is fixed by being screwed into a screw hole provided in the image control board 32. The various roms may be fixed by pointing the pins provided in the roms into the sockets provided on the board on which the roms are mounted. Further, not only the various boards are fixed by screws, but also the connectors provided on the various boards may be fixed by fitting them into the connectors provided on the door, case, board, or the like of the other party. Such a substrate fixing method can be similarly adopted for various substrates described below. Further, the image control connection board is not necessarily provided, and the image control board 32 may be directly connected to the effect unit 18 and mounted.

The switch sensor board 36 relays between the sub control board 31 and the two solenoids (first solenoid and second solenoid) described later, and displays the effect content by the LED, or switches and inputs the liquid crystal screen. It is a substrate of. Then, the switch sensor board 36 is fixed by being screwed into a screw hole provided in the dedicated board case.

The display board 37 is a board to which the above-mentioned acquired number display LED, stored number display LED, re-game display LED, input display LED, stop display LED, game start display LED, and input number display LED are attached, and is a front door portion. It is fitted and fixed to the hook provided in 11. The door relay terminal board 38 is a board that relays between the main control board (described later) and various sensors, blockers 47 (described later) and the display board 37 arranged at various locations on the front door portion 11. .. The door relay terminal plate 38 is housed in a dedicated board case, and the board case is screwed to the front door portion 11 to be attached to the front door portion 11.

The rotating cylinder lighting substrate 39 is a substrate to which LEDs for illuminating the first cylinder 51L to the third cylinder 51R are attached, and is fitted and fixed to a hook provided on the front door portion 11. The lower panel lighting board 40 is a board having an upper and lower two-divided structure to which an LED for illuminating the lower panel 19 is attached, and is fitted and fixed to a hook provided on the front door portion 11. The lower panel lighting board 40 is a board to which an LED is attached to illuminate the lower panel, and is fitted and fixed to a hook provided on the front door portion 11.

Next, as devices such as various sensors provided on the front door portion 11, the start lever sensor 41, the three-sheet insertion button sensor 42, the one-sheet insertion / clearing button switch 43, the game medal selector 44, the insertion sensor 45, and the selector There are a passage sensor 46, a blocker 47, a game medal return passage 48, a stop button sensor 49, a speaker 50, and the like. Of these, the start lever sensor 41 is for detecting the operation of the start lever 25, and the three-sheet insertion button sensor 42 is for detecting the operation of the three-sheet insertion button.

Further, the one-sheet insertion / clearing button switch 43 is a device equipped with a one-sheet insertion button and a clearing button switch. The game medal selector 44 is a device to which a insertion sensor 45, a selector passage sensor 46, and a blocker 47, which will be described later, are attached, and is also a device for selecting whether or not the inserted game medals are within the acceptable range. The above-mentioned insertion sensor 45 is a sensor for detecting the insertion of a game medal, and the selector passage sensor 46 is a sensor for detecting the passage of a game medal. Further, the blocker 47 is a device for returning a game medal according to the game state, and the game medal return passage 48 is a passage when the game medal is returned. The stop button sensor 49 is a sensor for detecting the operation of the stop buttons 24L to 24R, and a plurality of speakers 50 are provided for outputting sound effects.

Although not shown, the front door portion 11 is provided with a solenoid 1, a solenoid 2, and a cross key substrate. Of these, the solenoid 1 and the solenoid 2 are devices for vibrating the sub input switch. Further, the cross key board is a board for switching and inputting a liquid crystal screen, and the board is housed in a special board case, and the special case is screwed and fixed.

FIG. 4 shows the front side of the housing portion 12. A main control board 61, a setting unit 62, a game medal payout device (hopper) 63, a power supply unit 64, and the like are arranged in the housing portion 12. Of these, the main control board 61 controls the input and output to the slot machine 10 to control the game, and although the reference numerals are omitted, a stop switch, a setting display LED, a monitor LED, and the like, which will be described later, are attached. It is a board. The main control board 61 has a board housed in a main board case 65, which is a dedicated board case, and the main board case 65 is fixed to a housing portion 12 with a special stopper. The setting display LED 66 displays a set value that defines the theoretical ease of hitting (the degree of advantage of the player). The stop switch is set to either the upper side or the lower side to select either the stop function or the automatic clearing function. However, since the stop function and the automatic clearing function are not installed in this embodiment, the stop switch is not provided. This stop switch is not used. Therefore, the stop switch does not affect the outcome of the game. An IC tag sealing sticker (not shown) is attached to the main board case 65, and the IC tag sealing sticker is a sealing paper in which an IC tag is embedded.

Further, the housing portion 12 is provided with a door switch 60, and the door switch 60 is a switch for detecting the opening / closing of the front door portion 11. Further, the setting unit 62 described above is a box containing a setting door switch 67, a setting key switch 68, and a setting / reset button 69 (“/” means “or”), which will be described later. Of these, the setting door switch 67 is a switch for detecting the opening / closing of the setting door that constitutes a part of the housing of the setting unit 62 and closes the setting unit 62. The setting key switch 68 is a switch for switching the setting and confirming the setting in the slot machine, and the setting / reset button 69 is a button for selecting the above-mentioned setting value or canceling the error. The setting door switch 67 does not necessarily have to be provided. Further, in this embodiment, the setting / reset button 69 that also serves as the setting button and the reset button is used, but they may be provided separately. Furthermore, the above-mentioned lock portion 23 is provided with a setting and reset function. For example, when the key inserted in the lock portion 23 is rotated to the right, the lock is released, and when the key is rotated to the left, the lock is released. It may function as a setting / reset switch. Further, either one of the setting key switch 68 and the setting / reset button 69 shown in FIG. 4 may be provided separately from the setting unit 62. Examples of such a device include a setting key cylinder (not shown) provided with a setting key switch 68 provided in the power supply unit 64 and a setting / reset button 69 provided in the setting unit 62.

Further, the housing portion 12 is provided with an external centralized terminal plate 70, and the external centralized terminal plate 70 provides a medal insertion signal output, a medal payout signal output, and an external signal output 1 to an external signal output 5 to the outside. It is a board on which monitor LEDs (7) are mounted while outputting. Then, the external centralized terminal plate 70 is fitted into a hook provided on the housing portion 12 and fixed to the housing portion 12.

The game medal payout device 63 described above is provided with a payout sensor (not shown, sometimes referred to as a “payout sensor”), and the payout sensor is a sensor for detecting the payout game medal. Is.

Further, the housing portion 12 is provided with a game medal auxiliary storage 71, and the game medal auxiliary storage 71 is a storage for storing game medals exceeding the storage capacity of the game medal payout device 63. Is. The game medal auxiliary storage 71 is provided with a full detection electrode (not shown), and the full detection electrode is an electrode for detecting the full state of the game medal auxiliary storage.

The power supply unit 64 described above is a box in which the power supply switch 72 is housed, and the power supply switch 72 is a switch for turning on / off the main power supply. Then, by turning the power switch 72 from OFF to ON, predetermined power is supplied to various devices including the control board and the like via the power supply unit 64.

Further, the housing portion 12 is provided with the above-mentioned first cylinder 51L to third cylinder 51R. The rotating cylinders 51L to 51R are devices for rotating a pattern drawn on the outer peripheral surface. Inside each of the rotating cylinders 51L to 51R, a rotating cylinder sensor (not shown) is provided, and the rotating cylinder sensor sets a reference position of the rotating cylinder on the rotating cylinder and serves as an index (hereinafter referred to as an index). This part is sometimes called an "index") and is a sensor for detecting.

Further, although not shown, the housing portion 12 is provided with a BL (backlight) relay board, a rotating cylinder device board, a backlight LED, an LED backlight board, and the like. Of these, the BL relay board is a board that relays between the sub control board 31 and the LED backlight board, the rotating cylinder sensor, and the like, which will be described later. The BL relay board is mounted on the housing portion 12 by storing the board in a special board case and fixing the board case with a special stopper.

Further, the rotating cylinder device substrate is a substrate that relays between the main control substrate 61, the rotating cylinder stepping motor (described later), and the rotating cylinder sensor in order to rotate or stop each rotating cylinder 51L to 51R. It is also a board that relays between the main control board 61 and the above-mentioned fullness detection electrode, door switch 60, game medal payout device 63, external centralized terminal board 70, and power supply unit 64. The rotating cylinder device board is attached to the housing portion 12 by storing the board in a special board case and fixing the board case with a special stopper. The backlight LED is arranged inside each of the rotating cylinders 51L to 51R, and is an LED for illuminating the design on the rotating cylinders 51L to 51R from the back surface. The LED backlight substrate is a substrate on which the above-mentioned backlight LED is mounted.
<Electrical basic configuration of various control boards>

Next, the electrical basic configuration of the main control board 61, the sub control board 31, and the image control board 32 described above will be described. As shown in FIG. 5A, the main control board 61 stores a main CPU 81 that controls the progress of the game, a program (game control program) used for game control of the main CPU 81, and various data. It is provided with various electronic components such as a main ROM 82, a readable and writable RWM83 that temporarily stores data for control related to the progress of the game, an interface unit (not shown), and the like. In this embodiment, the game control program is roughly divided into two control programs, a first control program and a second control program. The control executed based on the first control program can be referred to as a first control, and the control executed based on the second control program can be referred to as a second control. Further, the first control may be referred to as "control provided for games" and the second control may be referred to as "control not used for games", but the details thereof will be described later.

Further, the sub-control board 31 stores a sub-main CPU 86 that controls the effect based on a command from the main control board 61, a program (effect control program) used for the effect control of the sub-main CPU 86, and various data. It is provided with various electronic components such as a sub-main ROM 87, a readable and writable RWM88 that temporarily stores data for effect control, and an interface unit (not shown). Then, the sub control board 31 receives a command (main command) transmitted from the main control board 61, and performs control based on this main command. Then, the sub-control board 31 transmits a command (sub-main command) to the image control board 32 for image display and sound output.

The image control board 32 includes a sub-sub CPU 91 that performs image control based on a sub-main command from the sub-control board 31, a program (image control program) used for image control of the sub-sub CPU 91, and an effect ROM 92 that stores various data. Based on the command from the sub-sub CPU 91, the VDP 94 controls the image display using the image data stored in the character ROM 93, the audio chip 96 controls the audio output using the audio data stored in the audio ROM 95, and the image display and audio. It is provided with various electronic components such as a readable and writable RWM97 that temporarily stores data for output, an interface unit (not shown), and the like. Here, the effect ROM 92 is mounted on the effect rom board 35 described above, and the sound ROM 95 is mounted on the sound board 34 described above. However, the present invention is not limited to this mode, and the sub-control board 31 may supplement some functions and all the functions of the image control board 32. For example, the sub control board 31 may be provided with the voice ROM 95, and the voice data may be selected and output controlled without going through the image control board 32, or the sub control board 31 may be provided with the character ROM 93 and VDP 94. More specific operations of the main control board 61, the sub control board 31, and the image control board 32 will be described later.
<< Component configuration related to the main control board >>

Subsequently, an outline of the component configuration of the main control board 61 described above will be described. The main control board 61 is a rectangular plate-shaped wiring board having printed wiring, and in this embodiment, a board having a plurality of layers (here, two layers) structure is used. Further, a through hole for mounting a lead type electronic component is provided at a predetermined portion of the main control board 61, and soldering such as a flow type is performed with the lead inserted in the through hole. Then, the lead type electronic equipment is mounted on the main control board 61. Further, not only lead type electronic components but also surface mount type electronic components and the like can be mounted on the main control board 61.

FIG. 5B schematically shows a mounting surface on the surface side of the main control board 61. The main CPU 81, which is a lead-type packaging device, is mounted on the main control board 61. The main CPU 81 is mounted by inserting the lead of the main CPU 81 into a lead type socket soldered to the main control board 61 and fitting the main CPU 81. Further, various electronic components 181 and various connectors 182 are soldered on the main control board 61 as shown in part.

Of these, the various connectors 182 are arranged along the peripheral edge portion (outer edge portion) of the main control board 61, and the connection port is exposed to the outside from the above-mentioned main board case 65. Then, the various connectors 182 are fitted with connectors provided on the harness from the boards related to the external devices such as the above-mentioned sub control board 31, rotating body device board, various LED boards, etc., and are fitted with the main control board 61. , Used for electrical connection with various external devices.

Further, reference numeral 183 in FIG. 5B is a non-mounting area in which a connector is not provided. This non-mounting area 183 is an area reserved for mounting an emergency connector for connecting a testing machine at the product development stage, and the slot machine 10 according to this embodiment is from the development stage to the commercialization. This is the area where the emergency connector was removed during the transition. Then, in the non-mounting area 183, the plate surface of the main control board 61 is exposed, and a plurality of through holes 184 for inserting the leads of the emergency connector can be visually observed. Further, since the mounting position of the emergency connector is the peripheral edge of the main control board 61 as described above, the non-mounting area 183 is also located on the peripheral edge of the board, which is outside the board from the main CPU 81. Note that FIG. 5B shows only a part of the through holes of the emergency connector in order to avoid complicating the drawings.

The emergency connector is used to connect a performance tester (not shown) used in the development stage, particularly in the stage of receiving official approval, to the main control board 61. More specifically, a test relay board (not shown) is connected to the emergency connector, and a performance tester is connected to the test relay board. Then, the test data signal taken out via the test relay board is input to the performance tester, and the performance tester inputs the performance data of the slot machine 10 based on the input test data signal. get.

The test relay board is not used at the stage of commercialization, and is not provided in the commercialized slot machine 10. In addition, a test drive circuit (test driver) is used to output the test data signal. This test driver is mounted on the test relay board, and is tested in the commercialized slot machine 10. The area for mounting the driver is not provided on the main control board 61. Furthermore, the components such as the shape of the emergency connector, the dimensions of each part, the number of pins, and the color are different from any of the other various connectors 182, and are structurally different from the other connector connected to the other connector. The connection is impossible.

On the other hand, in the commercialization stage, the performance tester is not connected, so that the emergency connector is not mounted at the time of manufacturing the main control board 61. However, if the printed wiring of the main control board 61 and the game machine control program were changed in line with the fact that the emergency connector was not installed, the commercialized slot machine 10 and the slot machine at the time of the test were used. The conditions cannot be matched. Also, if an emergency connector is left in the commercialized slot machine 10 so as not to change the conditions, a connector that can be fitted with the emergency connector is used for the equipment for fraud, and fraud is easy. It is also possible that it will become.

For this reason, in order to remove the emergency connector and take measures against fraud and to minimize the change in conditions, the printed wiring for the emergency connector is left in the same form as when the emergency connector is installed. .. Further, solder is supplied to the through holes 184 for the emergency connector, and the through holes 184 for the emergency connector are closed by the solder over the entire length. By closing the through hole 184 with solder, it is possible to prevent fraudulent acts such as using the through hole 184. Further, by soldering, it is possible to make the wiring for the emergency connector conductive with other wiring (for example, grounding wiring).

Further, during soldering, it is conceivable that the surface tension of the molten solder causes the solidified solder to rise to some extent (for example, about 0.1 mm) and protrude from the substrate surface. However, as described above, since the emergency connector is not mounted at the time of commercialization, the raised solder does not come into contact with the emergency connector or other electronic components. It is possible to close the through holes 184 with a material other than solder (for example, solder resist), but in this case, solder for closing the through holes 184 is not required. It is also possible to leave the through hole 184 open without blocking it. In this case, a material for closing the through hole 184 becomes unnecessary.

Although not shown, the above-mentioned main substrate case 65 is configured by combining a box base made of transparent resin and having a substantially rectangular parallelepiped shape and a box cover made of transparent resin and covering the opening of the above-mentioned box base. Has been done. A hole for exposing the permanent connector 182 is provided in the box cover at a position corresponding to the mounting area of various permanent connectors 182 that will be used even after commercialization, but the non-installed connector is not mounted. At the position corresponding to the area 183, no hole for exposing the emergency connector is left, and the non-mounting area 183 is in a sealed state.
<Mechanism related to rotation of the rotating cylinder>

Next, the mechanism for rotating the first cylinder 51L to the third cylinder 51R described above will be described. Reel tapes are attached to the outer peripheral surfaces of the cylinders 51L to 51R, and a predetermined number of symbols are drawn on the reel tapes. In this embodiment, the number of symbols is 21 each. The sizes of all the rotating cylinders are set to be the same, and the rotation axes are located in the same linear shape. Further, each of the rotating cylinders 51L to 51R is connected to the rotating cylinder rotating device 54 shown in FIG. 4 and integrated with the rotating cylinder rotating device 54, and the rotating shaft is set by the rotating cylinder rotating device 54 of the slot machine 10. It is driven to rotate in the left-right direction. Here, the arrangement of the symbols in the first cylinder 51L to the third cylinder 51R and the control mode related to the symbol display will be described later. The number of symbols is not limited to 21, and may be, for example, 20 or 14.

The rotating cylinder rotating device 54 is a device for rotating the first cylinder 51L to the third cylinder 51R, and is operated by operating the start lever 25 to rotate the first cylinder 51L to the third cylinder 51R. It has a function to rotate.

Although not shown, the rotating cylinder rotating device 54 is composed of a rotating cylinder stepping motor, a reel bush, a rotating cylinder sensor, a rotating cylinder device substrate, and the like, and includes a first control program and a second control program as described later. It is controlled by a computer program (game control program). Each of the rotating cylinders of the 1st cylinder 51L to the 3rd cylinder 51R is unevenly incorporated into the stainless steel shaft of the rotating cylinder stepping motor via a cylindrical reel bush, and the rotating cylinder stepping motor is incorporated via a screw and a resin washer. It is fixed to the axis of. Then, the shaft of the rotating cylinder stepping motor is used as the shaft of the first cylinder 51L to the third cylinder 51R, and the rotating cylinder stepping motor is fixed to a motor frame made of metal or the like with a screw, and the rotating cylinder rotating device 54 is also used. Since the motor frame is inserted into a reel frame made of metal or the like, which is the skeleton of the above, and fixed by a latch (here, a so-called snap latch equipped with a plunger or a grommet), even if the rotating cylinder rotating device 54 operates. , The 1st body 51L to the 3rd body 51R do not sway (they do not sway in the rotation direction or the axial direction).

When stopping the first cylinder 51L to the third cylinder 51R, the rotation cylinder rotating device 54 functions as a rotation stopping device. That is, the rotation stop device has a function of stopping the rotating cylinder and a function of displaying a combination of symbols. Of these, the function of stopping the rotating cylinder is the above-mentioned stop button 24.
When there are individual pressing operations of L, 24C, and 24R, it is a function of stopping the rotating cylinder corresponding to the pressed stop button. In addition, the function of displaying the combination of symbols is such that all three 1st cylinders 51L to 3rd cylinders 51R are stopped by the above-mentioned function of stopping the rotation cylinders, and the 1st cylinders 51L to the 3rd cylinders 51R are stopped. It is a function to display the combination of symbols by.

Further, the rotation stop device is composed of a stop button 24L, 24C, 24R, a stop button sensor, a door relay terminal plate, a rotating cylinder stepping motor, a rotating cylinder sensor and a rotating cylinder device board, and is controlled by the above-mentioned game control program. It operates when the player operates the stop button, and does not operate otherwise. Here, an index serving as an index of the rotation angle is formed on each of the rotating cylinders 51L to 51R, and the rotating cylinder is based on the positional relationship between this index and each symbol drawn on each of the rotating cylinders 51L to 51R. The position of the symbol when the rotation is stopped is controlled.
<Control of the mechanism related to the rotation of the rotating cylinder>

Each of the rotating cylinders 51L to 51R has various data described below, that is, the rotating cylinder drive state number, the rotating cylinder drive pulse output counter, the number of times the rotating cylinder drive pulse is switched during acceleration, the step number of one symbol, and the symbol number (passing). It is managed by using (for position), symbol number (for stop position), rotating cylinder rotation failure detection counter, rotating cylinder drive pulse data search counter, rotating cylinder rotation start standby counter, and the like. The driving state of each rotating cylinder is checked by the rotating cylinder drive management module for each interrupt (2.235 ms), and excitation data is output according to the conditions.

Among the various data described above, the rotating cylinder drive state number has a value of 0 to 5, 0 is stopping or shaking, 1 is waiting for rotation start, 2 is decelerating, and 3 is deceleration start. 4 represents constant speed and 5 represents acceleration. Further, the rotating cylinder drive pulse output counter represents the number of interrupts for switching excitation, and the number of rotating cylinder drive pulse switching during acceleration represents the offset of the rotating cylinder rising pattern (interruption number) table. The step number of 1 represents the number of steps of one symbol.

Further, the symbol number (for the passing position) represents the symbol number (0 to 20) passing through the middle row, and when the value is FFH (H indicates that it is in hexadecimal notation), It indicates that the rotation sensor has not passed. The symbol number (for the stop position) represents the symbol number (0 to 20) to be displayed in the middle row, and when the value is FFH, it indicates that the symbol number has not been set. The rotating cylinder rotation defect detection counter is a counter that detects rotation defects of the rotating cylinder, and outputs a value of the number of steps / 2 after passing through the sensor. Further, when each of the rotating cylinders 51L to 51R passes through the rotating cylinder sensor, the rotating cylinder drive state number becomes "4" of "in constant speed".
<Game medal selector>
<< Configuration of game medal selector >>

Next, the game medal selector 44 described above will be described. As shown in FIGS. 2 and 3, the game medal selector 44 is located on the back surface of the front door portion 11 on the open end side (left end side in FIGS. 2 and 3) of the front door portion 11 and. It is attached to the part in the middle of the vertical direction. Further, the game medal selector 44 is located at a portion immediately below the rotating cylinder display portion 15, and the game medal inserted into the game medal insertion slot 21 (see FIG. 1) on the front surface of the front door portion 11 is placed on the front surface. It is designed to be accepted behind the door portion 11.

As shown in FIG. 6, the game medal selector 44 has a rectangular box-shaped outer shape, and includes a main body portion 101, an opening / closing portion 102, and a hinge mechanism portion 103. Of these, the main body 101 is fixed to the front door portion 11, and as shown in FIG. 7, the opening / closing portion 102 is attached to the main body 101 so as to be openable / closable via the hinge mechanism 103. Further, the arrangement of the hinge mechanism portion 103 is a portion on the right side when viewed from the back side of the front door portion 11, and the opening / closing portion 102 is located on the hinge mechanism portion 103 centering on the axis of the hinge mechanism portion 103 extending in the vertical direction. It can be opened in the horizontal direction while resisting the elastic restoring force of the provided coil spring 104 or the like.

When the opening / closing portion 102 is closed, a medal passage 105 having a width somewhat larger than the thickness of one game medal is formed between the opening / closing portion 102 and the main body portion 101. That is, the medal passage 105 opens upward in a slit shape, bends and branches at a portion in the middle, and faces the side of the game medal selector 44 (on the right side when viewed from the back of the front door portion 11) or downward. Is growing. The upper end of the medal passage 105 serves as a game medal entrance (game medal entrance) 106, and the opening that serves as the game medal entrance 106 communicates with the game medal insertion slot 21 described above. Further, the side exit (hereinafter referred to as "first exit") 107 of the game medal selector 44 is capable of ejecting game medals toward the game medal payout device 63 described above, and is a lower exit (hereinafter referred to as "exit"). The (referred to as "second exit") 108 is capable of ejecting game medals toward the above-mentioned game medal payment outlet 16.

Further, as shown in FIG. 7, the bent portion 110 located at a portion in the middle of the medal passage 105 is provided with a deformed plate-shaped deceleration portion 111. The deceleration portion 111 is rotatable in the front-rear direction (front-rear direction of the front door portion 11) with the upper end side as the base end, and elastically protrudes into the medal passage 105 when the game medal does not pass. ing. Then, when the game medal is inserted into the game medal insertion slot 21 and the inserted game medal comes into contact with the deceleration unit 111 while passing through the bent portion 110, the deceleration unit 111 is pushed by the game medal and is immersed in the main body portion 101. To do. Further, when the game medal passes and the deceleration unit 111 is released from the pressing force of the game medal, the deceleration unit 111 protrudes into the medal passage 105 again. Then, the game medal that passes through the bent portion 110 changes its course while being decelerated by contact with the decelerating portion 111, and heads toward the downstream side of the bent portion 110.

The selector passage sensor 46 described above is provided on the downstream side of the bent portion 110. The selector passage sensor 46 includes a rectangular plate-shaped first movable portion 112, and the first movable portion 112 passes through the branch portion 113 of the medal passage 105 in the longitudinal direction and in the width direction (passing) of the medal passage 105. It is arranged in a state facing the radial direction of the game medal to be played. The first movable portion 112 is rotatable in the front-rear direction (front-rear direction of the front door portion 11) with one side on the upstream side of the medal passage 105 as a base end, and if the game medal does not pass, the medal passage It protrudes into 105. However, when the game medal that has passed through the deceleration unit 111 comes into contact with the first movable portion 112, the first movable portion 112 is pushed by the game medal and is immersed in the main body portion 101. Then, when the game medal passes and the first movable portion 112 is released from the pressing force, the first movable portion 112 protrudes into the medal passage 105 again.

Further, the main body 101 has a built-in microsensor (not shown) for the selector passage sensor 46, and the presence or absence of the immersion operation of the first movable portion 112 is detected by the microsensor. That is, when the first movable portion 112 is pushed by the game medal that enters the medal passage 105 and flows down to perform an immersive operation, the operation of the first movable portion 112 is detected and the output signal of the microsensor changes. To do. Then, in the above-mentioned main control board 61, the control related to the insertion of the game medal (FIGS. 22 to 29, etc.) as described later is executed by utilizing the output from the microsensor for the selector passage sensor. To. Here, as the microsensor for the selector passage sensor 46, various microsensors such as a contact type and a non-contact type can be applied. Further, the first movable portion 112 is configured so that a foreign matter or the like that has flowed back can be caught (the foreign matter cannot move from the downstream to the upstream of the first movable portion 112). As a result, it is possible to prevent the goto machine from being easily pulled out when the goto machine (machinery / equipment used for so-called goto action) is inserted.

Further, a second movable portion 114 is provided in the upper part on the upstream side of the first movable portion 112, and the second movable portion 114 also usually elastically protrudes into the medal passage 105 and is pushed by the game medal. In that case, it is designed to be immersed in the main body 101. Then, in this embodiment, the selector passage sensor 46 is composed of movable portions such as the first movable portion 112 and the second movable portion 114, and a detection unit such as a micro sensor for the selector passage sensor 46. In the present embodiment, the selector passage sensor 46 is formed by the first movable portion 112 and the second movable portion 114, but the present invention is not limited to this, and for example, even if only one of them is provided. It may be good, and it does not have to have the above-mentioned shape.

The insertion sensor 45 is provided at a portion of the medal passage 105 on the way from the selector passage sensor 46 to the first exit 107. The closing sensor 45 is composed of two sensors, a closing sensor 1 indicated by reference numeral 115 and a closing sensor 2 represented by reference numeral 116, and each closing sensor is built in the main body 101. In the following, when the closing sensor 1 and the closing sensor 2 are described by adding reference numerals in the drawings, the closing sensor 1 (115) and the closing sensor 2 (116) are described.

The closing sensor 1 (115) and the closing sensor 2 (116) both use a non-contact type microsensor (not shown) built in the main body 101. Further, the insertion sensor 1 (115) and the insertion sensor 2 (116) are arranged at a predetermined distance (for example, about 5 to 10 mm) smaller than the diameter of the game medal (here, 25 mm) in the flow direction of the game medal. Of these, the insertion sensor 1 (115) is located on the upstream side of the medal passage 105 with respect to the insertion sensor 2 (116).

Further, as the microsensor used for the closing sensor 1 (115) and the closing sensor 2 (116), a light receiving type is used, and a light emitting unit arranged diagonally above the black rectangular window portion 117. The light emitted from 118 (detection light) can be received. That is, a light emitter (not shown) using an LED or the like is built in the light projecting unit 118, and the positional relationship between the light emitting device and the light emitting sensor 1 (115) and the light emitting sensor 2 (116) is as follows. The detection light output from the light emitter is set to pass through the window portion 117 and enter the input sensor 1 (115) and the input sensor 2 (116).

Then, when the game medal flowing down the medal passage 105 blocks the detection light, the detection light does not enter the insertion sensor 1 (115) and the insertion sensor 2 (116), the game medal is detected, and the insertion sensor 1 ( The output signal of the microsensor used in 115) and the input sensor 2 (116) changes. Then, in the above-mentioned main control board 61, the output from the insertion sensor 1 (115) and the insertion sensor 2 (116) is used to control the insertion of the game medal as described later (FIGS. 22 to 22). 29 etc.) is executed.

Further, in this implementation, the insertion sensor 1 (115) and the insertion sensor 2 (116) are arranged at a portion closer to the upper side of the medal passage 105, and for example, even if a plurality of game medals pass continuously. , The upper gap between the game medals passes through the insertion sensor 1 (115) and the insertion sensor 2 (116). As a result, the game medals can be reliably detected one by one.

Further, as shown in FIG. 7, the opening / closing portion 102 is provided with the above-mentioned blocker 47. The blocker 47 is composed of a plate-shaped movable block portion 119 formed into an L-shaped cross section, a solenoid (not shown), and the like, and the movable block portion 119 is provided with a shielding plate portion 120 protruding in the horizontal direction. Has been done. Further, in the arrangement of the blocker 47, when the opening / closing portion 102 is closed, most of the movable block portion 119 is directed toward the first outlet 107 rather than directly below the first movable portion 112 in the selector passage sensor 46. It is set to be located on the downstream side with respect to the game medal. Then, the blocker 47 advances and retreats the movable block portion 119 in the front-rear direction (front-rear direction of the front door portion 11) as the solenoid (not shown) is driven ON / OFF.

In this embodiment, when the solenoid is turned off, the blocker is turned off. When the blocker is turned off, the movable block portion 119 retracts into the opening / closing portion 102, and the shielding plate portion 120 is pulled into the opening / closing portion 102. It is in a state of being. Then, when the blocker is turned off, the lower second outlet 108 is open, and the game medal falls to the side of the second outlet 108 without facing the first outlet 107 and is guided to the second outlet 108. It will be returned to the saucer 17.

On the other hand, when the solenoid is turned on, the blocker is turned on. When the blocker is turned on, the movable block portion 119 advances toward the main body portion 101, and the shielding plate portion 120 advances to the medal passage as shown in FIG. It is in a protruding state in 105. Then, when the blocker is turned on, the lower second outlet 108 is blocked by the shielding plate portion 120, and is guided to the side of the side first outlet 107 through the shielding plate portion 120. Then, the game medal passes through the selector passage sensor 46 and the insertion sensor 45 toward the first outlet 107, and is discharged from the first outlet 107 toward the game medal payout outlet 16.

Here, reference numeral 121 in FIG. 7 is a reject switch provided in the main body 101 to form a reject mechanism, and reference numeral 122 is a reference to the reject switch 121 when the opening / closing portion 102 is closed. It is a receiving part for rejection arranged so as to. The function of the reject switch 121 will be described later.
<< Function of game medal selector >>

Subsequently, the function of the game medal selector 44 will be described. The game medal selector 44 has a game medal selection function, a game medal non-acceptance function, and a game medal detection function. Of these, the game medal selection function is a function for selecting whether or not the inserted game medal is within the acceptable size range. Further, the game medal non-acceptance function is a function of returning the game medal without accepting it by the blocker 47 according to the game state, and the game medal detection function detects the game medal that has passed the insertion sensor 45. It is a function to do.

Regarding the above-mentioned non-acceptable game medal function, as a game state in which 50 game medals are stored in a storage device (described later) and a specified number (described later) of game medals are returned without accepting the game medals. When is inserted, from the reception of the operation of the start lever 25 after inserting the specified number of game medals to the end of the game at that time, the inserted game medals and the stored game medals For refunds, when an error occurs, when switching settings and when confirming settings.

When a game medal within the acceptable game medal size range is inserted from the game medal insertion slot 21, the game medal entrance 106 of the game medal selector 44 passes through the medal passage 105 and the game medal exit (first exit 107). ) Drops onto the game medal payout device 63. When the game medal passes through the selector passage sensor 46 and the input sensor 45, detection signals are sent from the sensors 45 and 46 to the main control board 61. The detection signal of the selector passage sensor 46 is used to confirm the number of game medals that the game medals have passed through the selector passage sensor 46 in the above-mentioned game control program.

The detection signal of the input sensor 45 is used to determine the time and order in which the game medal has passed through the selector passage sensor 46 in the above-mentioned game control program. If the detection signals of the selector passage sensor 46 and the insertion sensor 45 are within the specified time, and the specified order and the specified number of medals are specified, the game medal detection is normally performed. If the time is longer than the specified time, the order is not specified, or the number of medals is not specified, an error will occur and the inserted game medals will be invalid. However, if the detection signal is only the output signal of the input sensor 1 (input sensor 1 signal) and is not detected by the detection signal of the input sensor 2 (input sensor 2 signal), no error occurs.

Here, as a case where only the input sensor 1 signal is detected and the input sensor 2 signal is not detected, there may be a case where the game medal returns from the input sensor 1 in the opposite direction. Further, a specific mode of such a game medal detection will be described later.

When the deformed game medal is inserted from the game medal insertion slot 21, it stays at the game medal entrance 106. For the accumulated game medals, by operating the game medal return button 22 (see FIG. 1), the above-mentioned reject switch 121 is pressed, the opening / closing part 102 of the game medal selector 44 is slightly opened, and the game medal payout outlet 16 is used. It will be returned to the saucer 17. When a game medal smaller than the size that can be accepted is inserted from the game medal insertion slot 21, the medal is returned to the saucer 17 from the game medal payment exit 16 after passing through the game medal entrance 106.

Further, the above-mentioned blocker 47 is turned off according to the game state by the above-mentioned game medal non-acceptance function, and the movable block portion 119 is retracted from the medal passage 105. When a game medal within the acceptable range is inserted from the game medal insertion slot 21 at that time, as described above, the game medal passes through the game medal entrance 106 and reaches the bent portion 110 of the medal passage 105, and further by free fall. , It passes through the second exit 108 and is returned to the saucer 17 from the game medal payment exit 16. <Procedure for changing settings>

In the slot machine 10 of this embodiment, the normal operation for changing the setting of the setting unit 62 (see FIG. 4) described above is performed as follows. First, for example, a game hall clerk or the like opens the front door portion 11 of the slot machine 10 in the power-off state (see FIGS. 1 and 2). When opening the front door portion 11, a predetermined key is inserted into the lock portion 23 (see FIG. 1) of the front door portion 11 locked in the closed state, and the key is unlocked in the unlocking direction. Rotate (eg counterclockwise).

Further, the setting door provided in the setting unit 62 shown in FIG. 4 is opened so that the setting key cylinder into which the setting key is inserted can be accessed, although not shown. Further, the setting key is inserted into the setting key cylinder, and the setting key is rotated (ON operation) in the ON direction (for example, clockwise direction). Then, the power switch 72 described above is turned on to supply power to the slot machine 10. By turning on the power switch 72 while the setting key is turned on in this way, the situation of "setting change device operation" in which the setting change device process (see FIG. 13) described later is performed is established.

When power is supplied to the slot machine 10, the set value is displayed on the above-mentioned setting display LED 66 mounted on the above-mentioned main control board 61 (see FIG. 4). A so-called 7-segment display is used for the setting display LED 66. Further, in the present embodiment, the setting display LED 66 displays any one of the setting values (here, six of "1" to "6") which are integer values in a predetermined range, and the displayed setting. The value becomes visible through the transparent main board case 65.

In the situation where the setting change device is operated in this way, when the above-mentioned setting / reset button 69 (see FIG. 4) is pressed, the display of the set value changes. In this embodiment, each time the setting / reset button 69 is pressed, the display of the set value is incremented by one step. For example, when the power of the slot machine 10 is turned on with the setting 1 (the setting value is 1) and the setting / reset button 69 is operated once, the setting 2 is obtained. After that, each time the setting / reset button 69 is pressed, the display of the set value changes in ascending order to "2", "3", ....

Further, in this embodiment, the player has the highest degree of advantage in the set value 6, which is the highest set value, and the smaller the value of the set value, the lower the degree of advantage. Then, when the setting / reset button 69 is operated once with the setting value 6 which is the maximum setting value described above, the setting 1 which is the minimum setting value is obtained. Further, in a situation where the value displayed on the setting display LED 66 is the set value to be selected, a game clerk or the like operates the above-mentioned start lever 25 (see FIG. 1) to press the start switch (not shown). By turning it on, the set value is fixed.

As described above, the mode of change related to the display of the set value when the setting / reset button 69 is pressed is not limited to the one in which the display of the set value is incremented step by step, for example, the display of the set value. May be decremented step by step and change in descending order. Further, the range of the setting value that can be changed by the setting change device processing (see FIG. 13) described later is not limited to the 6 stages of "1" to "6", and for example, the 4 stages of "1" to "4" and the like. It may be.

Subsequently, the setting key is rotated in the OFF direction (for example, counterclockwise direction) (OFF operation), the setting door provided in the setting unit 62 is closed, the normal setting change operation is completed, and the game is possible. (Normal state).

Here, the situation after the above-mentioned "setting change device operation" situation is reached and the setting / reset button 69 operation is enabled can be referred to as the "setting value changeable" situation. .. This "setting value can be changed" is a situation in which the setting value can be changed (selected) by operating the setting / reset button 69.

Further, a state in which the set value is fixed by operating the start lever 25 (lever operation) after "setting value can be changed" can be referred to as a "set value fixed" situation. Then, when the set value is changed, the setting / reset button 69 is operated as described above in "setting value can be changed", and the start lever 25 is operated in a state where the target set value is reached. Then, the status of "setting value confirmed" is reached. Then, in the "set value confirmed" situation, the display of the set value does not change even if the setting / reset button 69 is operated.

Further, a state of waiting for the setting key to be turned off after the above-mentioned "setting value determination" can be referred to as a "setting value determination waiting" situation. Even in this "waiting for determination of set value" situation, it is impossible to change the set value by operating the setting / reset button 69. Further, in this embodiment, the state in the setting change work can be divided into a first state and a second state. Then, when the power is turned on while the setting key is turned on, the state shifts to the first state related to the setting change, and when the start lever 25 is operated thereafter, the state shifts from the first state to the second state. Further, when the setting key is turned off in the second state related to this setting change, the second state ends.
<Procedure for playing games and processing when inserting game medals>

Next, the procedure for performing the game and the processing at the time of inserting the game medal will be described. In the processing at the time of inserting the game medal, when the game medal selector 44 (see FIG. 6) is in the game medal acceptance state (the game medal passable state), the game medal is inserted from the game medal insertion slot 21 (see FIG. 1). Can be thrown in. Here, "inserting a game medal" is synonymous with "setting the number of bets", and "setting the number of bets" is synonymous with "betting". When the game medals are inserted, the above-mentioned insertion number display LED lights up according to the number of inserted medals, and the start lever 25 can be effectively operated by inserting a specified number of game medals. Then, when the start lever 25 can be effectively operated, processing such as a combination lottery based on the operation of the start lever 25, a freeze lottery (a lottery for a freeze effect described later), and an update of the rotating cylinder drive state can be executed. Will be. The game medal is used as a game medium, and the game medium is not limited to the game medal, but a game ball, electronic data, or the like can also be used.

If the maximum number of medals for each game state is exceeded, the subsequent game medals are stored in the storage device. The storage device fulfills a function of storing up to a predetermined number (here, 50 medals) of game medals under the control of the slot machine 10. However, if the number of stored game medals exceeds the maximum number of 50, the game medal selector 44 will be in the game medal return state, and the game medals inserted from the game medal insertion slot 21 will be paid for. It is returned to the saucer 17 from the exit 16 (see FIG. 1). The storage device is also called "credit", and specifically refers to a device that electrically stores (stores in RWM) game medals.

Regarding the rotation of the rotating cylinder, after inserting a specified number of game medals, the rotating cylinder can be rotated by operating the start lever 25 and operating the rotating cylinder rotating device 54. However, while the clearing button, stop button 24L to 24R, or one-sheet insertion button or three-sheet insertion button is being operated, the rotating cylinder 51L to 51R cannot be rotated even if the start lever 25 is operated. ..

When the start lever 25 is operated, the rotating cylinders 51L to 51R start accelerating rotation, and when the rotation speed reaches a predetermined speed (79.90 rotations / minute in this case), the constant speed state is reached. When the start lever 25 is operated, the game medal selector 44 is in the game medal return state. Even if the start lever 25 is operated when the predetermined time (4.1 seconds in this case), which is the minimum game time (shortest game time), has not elapsed since the rotation cylinders 51L to 51R started to rotate in the previous game. , Rotating cylinders 51L to 51R do not rotate. The rotating cylinders 51L to 51R start rotating 4.1 seconds after the rotating cylinder starts rotating in the previous game. However, in the case of waiting for a game due to a game effect (freeze effect, etc.) as described later, it is also possible to control the rotating cylinder to start rotating after the end of the game standby. Here, in the slot machine 10 of the present embodiment, the management of the minimum game time is performed in various modes depending on the situation, which will be described later.

When it is detected that the rotating cylinders 51L to 51R start to rotate and all of the rotating cylinders 51L to 51R are rotating normally (here, rotation in a constant speed and not stepped out), the stop buttons 24L to 24R are operated. Is ready to accept. However, if it is not detected that all of the rotating cylinders 51L to 51R are rotating normally, the operation of the stop buttons 24L to 24R cannot be accepted until the rotating cylinders 51L to 51R are normally rotated. The game medals inserted from the game medal insertion slot 21 after the start lever 25 is operated until all the rotating cylinders 51L to 51R are stopped are returned to the saucer 17 from the game medal payout outlet 16.

In stopping the rotation of the rotating cylinder, the rotating cylinders 51L to 51R can be arbitrarily selected, and the corresponding stop buttons 24L to 24R can be operated to stop the rotating cylinders 51L to 51R. However, if the clearing button, the start lever 25, the stop button corresponding to the already stopped rotating cylinder, or the 1-sheet insertion button or the 3-sheet insertion button are operated, the rotation will occur even if the stop button is operated. It is not possible to stop the internal rotation. Regarding the buttons (main system buttons) managed by these main control boards 61, it is possible to enable some buttons to be operable (operation is valid) depending on the combination. Then, the combination of the buttons and switches that can be operated (operation becomes valid) and the buttons and switches that cannot be operated (operation becomes invalid) can be arbitrarily determined. For example, a combination mode is exemplified in which the other stop button cannot be operated while any one of the stop buttons is being operated, but the stop button can be operated while the start lever 25 is being operated (after the operation). be able to.

When the stop buttons 24L to 24R are operated, the corresponding rotating cylinder is stopped within a predetermined time (190 ms in this case). Similarly, any of the remaining rotating cylinders is stopped by operating the stop button corresponding to the arbitrarily selected rotation cylinder. If you continue to operate the stop button, even if you operate the remaining stop buttons, the corresponding rotating cylinder will not stop. Start lever 2
After operating 5, the rotating cylinders 51L to 51R do not stop unless the stop buttons 24L to 24R are operated. However, when the freeze effect is being produced, it is possible to configure the rotating cylinder to stop without operating the stop buttons 24L to 24R.

In the display determination of the combination of symbols, when all the rotating cylinders 51L to 51R are stopped, the display determination of the combination of symbols related to winning or the operation of the accessory is performed on the effective line according to the specified number of insertions. However, if the start lever 25 or any of the stop buttons 24L to 24R is continuously operated at the time of the third stop, which is the third stop, after the operation is released, the winning or the operation is related to the valid line according to the specified number. The display judgment of the combination of symbols is performed. It should be noted that the "display determination of the symbol combination" and the "display determination" are such that the main CPU 81 detects the stopped symbol and directly determines what the stopped symbol is (so-called appearance). ), For example, it is determined whether or not an abnormality has occurred in the control of the rotating cylinders 51L to 51R, and if there is no abnormality, it is determined that the symbol display is properly performed, and the symbol is stopped normally. It means that the subsequent processing is proceeded as if it had been lost. Although not shown here, the specified number that can be inserted in the slot machine 10 of this embodiment is two in the game when the accessory is operating and three in the other games, and the effective line is There are three lines, the upper row, the middle row, and the lower row of the rotating cylinder display unit 15 (see FIG. 1). Not limited to this, it is also possible to adopt an effective line of 1 line only in the middle stage, or 5 lines including diagonally rising to the right and diagonally upper left. Then, when the combination of symbols related to the winning is displayed on the effective line according to the specified number, the control in the corresponding case is executed, and the combination of the symbols related to the accessory operation or the accessory continuous operation device is displayed. If this is the case, the control when the combination of symbols related to the accessory operation or the accessory continuous operation device is displayed is executed.

When the combination of symbols related to the winning is displayed, the number of game medals corresponding to the combination of the symbols related to the winning for each specified number is paid out and acquired by the player. The acquired game medals are stored in the above-mentioned storage device. However, if the number of stored game medals exceeds 50, the excess number of acquired medals is paid out from the game medal payout outlet 16 to the saucer 17. The game medals inserted from the game medal slot 21 during the acquisition of the game medals are returned to the saucer 17 from the game medal payout port 16. When all the game medals corresponding to the combination of the symbols related to the winning for each specified number are acquired, the game medal selector 44 is in the game medal acceptance state when the predetermined condition is satisfied. Then, the above-mentioned processing at the time of inserting the game medal is executed. In this embodiment, the upper limit of the number of game medals that can be obtained by one winning is not to exceed 15.

When a combination of symbols related to the operation of the accessory is displayed, the process corresponding to the corresponding accessory is executed. In this embodiment, as an accessory (as a winning combination), a so-called ordinary accessory, a first-class special electric accessory, a second-class special electric accessory, and a series of accessories related to the first-class special electric accessory. There is no combination of symbols that each of the actuating devices will operate, but the combination of symbols that activates the replay and the series of accessories related to the first-class special accessory. A combination of symbols that activates the actuating device is provided. Then, when the combination of the symbols corresponding to these is displayed, the corresponding process is executed.

On the other hand, when the symbols related to the winning and the operation are not displayed, the game medal selector 44 is in the game medal acceptance state. Then, the above-mentioned processing at the time of inserting the game medal is executed.

Next, the combination of symbols related to the winning for each specified number and the number of game medals that can be obtained when the combination of the symbols is displayed will be described. The combination of symbols related to winning and the number of game medals that can be obtained correspondingly are predetermined for each specified number. It is not possible to win a game medal without displaying the combination of symbols related to the winning. In addition, the combination of symbols related to the prize is not displayed without the condition device related to the prize being activated.

The combination of the winning symbols and the number of game medals won when the accessory and the continuous operating device of the accessory are not activated are defined only for the specified number of 3 medals, and the combination of the winning symbols (1 symbol or As the number of (including those in which only 2 symbols are specified), a predetermined number is specified for each acquired number. Furthermore, the combination of symbols related to winning and the number of game medals won when the first-class special accessory is activated are defined only for the specified number of two, and the combination of symbols related to winning (only one symbol or two symbols). As the number (including the specified one), a predetermined number is specified for each acquired number. The combination of the symbols related to these prizes and the specific relationship with the number of winning cards will be described later.

Next, the combination of symbols related to the operation for each specified number will be described. The combination of symbols related to the re-game, the accessory, and the operation of the accessory continuous operation device is predetermined for each specified number. When the condition device related to the operation of the re-game, the accessory and the accessory continuous operating device, etc. does not operate (when not activated), the combination of the symbols related to the operation of the re-game, the accessory and the accessory continuous operating device is displayed. It is supposed to never happen.

The combination of symbols and the operation name related to the operation when the accessory and the continuous actuation device of the accessory are not activated are defined only for the specified number of 3 sheets, and the combination of the symbols related to the operation (1 symbol only or 2). Eight types are provided in this embodiment as the number of (including those in which only the symbols are specified). The specific relationship between these operation names and the combination of symbols will be described later. Then, when the combination of the symbols related to the operation is displayed, the game control according to the operation name is executed thereafter.

Next, a combination of symbols that can be replayed, an effect when the combination of symbols is displayed, and a process when the combination of symbols is displayed will be described. When all the rotating cylinders 51L to 51R are stopped, if the combination of symbols displayed on the effective line is a combination of symbols related to the re-game, the re-game is activated. Further, the slot machine 10 of the present embodiment is provided with a game in which the probability that the condition device related to the re-game is activated varies.

The change in the probability that the condition device related to the re-game will be activated is that when the condition device related to the operation of the continuous operation device for the first-class special accessory is activated, the continuous accessory related to the first-class special accessory is activated. When the combination of symbols for which the actuating device is to be activated is displayed on the effective line, and when the operation of the accessory continuous actuating device related to the first-class special accessory is completed. As a process when a combination of symbols that can be replayed is displayed, the same number of game medals as the previous game are automatically inserted, and the start lever 25 can be operated. The game medals inserted from the game medal insertion slot 21 after the combination of symbols related to the re-game is displayed are stored in the storage device when the predetermined conditions are satisfied. After that, as in the normal time described above (here, in the case other than the replay), the control regarding the rotation of the rotating cylinder, the control regarding the stop of the rotation of the rotating cylinder, and the control regarding the display determination of the combination of the rotating cylinders are performed. Is executed.

Next, the first-class special character will be described. When the accessory continuous operating device related to the first-class special accessory is activated, the first-class special accessory when the accessory continuous operating device related to the first-class special accessory is activated is activated at the same time. In addition, when the operation of the accessory continuous operation device related to the first-class special accessory is completed, as soon as the operation of the first-class special accessory is completed, the first operation of the accessory continuous operation device related to the first-class special accessory is performed. A kind of special character works again. When the first-class special accessory is activated as described above, the processing at the time of inserting the game medal and the rotation of the rotating body are the same as in the normal time (here, in the case other than the game related to the first-class special accessory). Play a game under the control of.

Further, in controlling the stop of the rotation of the rotating cylinder, the player can arbitrarily select the rotating rotating cylinder and operate the corresponding stop button to stop the rotating cylinder. However, when the clearing button, the start lever, the stop button corresponding to the already stopped rotating cylinder, or the 1-sheet insertion button or the 3-sheet insertion button are operated, the rotation is performed even if the stop button is operated. It is not possible to stop the rotation of the cylinder. When the stop buttons 24L, 24C, 24R corresponding to the 1st cylinder 51L to the 3rd cylinder 51R are operated, the rotation of the corresponding rotation cylinder is within a predetermined time (190 ms in this case) as in the above case. Stop.

If one of the stop buttons is continuously operated, the corresponding rotating cylinder will not stop even if the remaining stop buttons are operated. After operating the start lever 25, the rotating cylinder does not stop unless the stop button is operated. Then, as for the display determination of the combination of symbols, the control of the display determination of the combination of the rotating cylinders is executed as in the normal case described above. In the present embodiment, after the operation of the stop button is effectively accepted, a waiting time of about 200 ms (also referred to as a rotation cylinder stop acceptance waiting time) is provided until the next stop button is effectively accepted. There is. That is, when all the reels (51L to 51R) are rotating, for example, after the left stop button (first stop button 24L) is operated, the middle or right stop button (second stop button 24C or first stop button 24C) is 200 ms later. 3 Stop button 24R) can be accepted.

Regarding the end of operation of the first-class special accessory, the first-class special accessory requires that the specified number of games have been completed or that the number of winnings has reached the specified number, and these When at least one of the operation termination conditions is satisfied, the operation is terminated.

Subsequently, the accessory continuous operation device related to the first-class special accessory will be described. In the game when the continuous operating device for the first-class special accessory is not activated, the combination of the symbols displayed on the effective line when all the rotating cylinders are stopped is the continuous accessory for the first-class special accessory. If it is a combination of symbols related to the operation of the operating device, the game related to the above-mentioned first-class special accessory is executed. The trigger for the end of operation of the accessory continuous operation device related to the first-class special accessory is when the number of game medals acquired exceeds a predetermined number (for example, 465). Then, after that, the process may be started when the game medal is inserted, as in the normal case described above.
<Game production>

As the above-mentioned game production, there is typically a freeze production. This freeze effect delays the progress of the game by suspending it for a predetermined period of time, and in this sense, it can also be called a delayed effect. Furthermore, the freeze effect can be classified and understood as follows. That is, the freeze effect can be divided into those that the player can easily recognize the execution of the freeze effect and those that cannot (or are difficult to recognize) the execution of the freeze effect. Among these, those that can easily recognize the execution of the freeze effect include those that do not respond to the operation of the start lever 25, and those that respond but rotate in a mode different from the operation mode of the reel during normal games. There are those that perform a reel effect (rotation effect) that operates the body. Those that do not respond to the operation of the start lever 25 include those in which the rotating cylinder does not start operating even if the start lever 25 is operated, and those in which a predetermined period (for example, 10 seconds) is required to start the operation. ..
<Main operation on the main control board>

Next, the main operation of the main control board 61 that functions as the main control means of the slot machine 10 according to the present embodiment will be described with reference to the drawings after FIG. First, the main control board 61 includes the above-mentioned first control program in which the above-mentioned main CPU 81 is stored in, for example, the built-in ROM of the main CPU 81 or an external ROM (main ROM 82) mounted on the main control board 61. Based on the second control program (described later), random number lottery, control of various devices, etc. are performed using the built-in RWM of the main CPU 81, the external RWM (main RWM83) mounted on the main control board 61, and the like. It is what you do.

Further, the main control board 61 has commands (“main command”, “sub control command”, “sub-main”) according to the game state and the lottery result with respect to the sub control board 31 that controls the effect using images and the like. It has a function to send a command (also called a command). Then, power is supplied to the main control board 61 from the power supply unit 64 described above. Here, for convenience of illustration, the external ROM and RWM are described by adding reference numerals 82 and 83, but in the following, unless otherwise specified, the ROM 82 and RWM 83 are built-in main CPU 81. It is used as a general term for external items.

Here, examples of the above-mentioned random number lottery include the above-mentioned replay, the character, the character continuous operation device, and the like, the freeze lottery, and the like, and the AT lottery related to the execution of AT (assist time). it can. Further, the main control means is a concept that includes not only the main control board 61, but also the main CPU 81 and peripheral devices such as the main ROM 82 and RWM 83 that realize various functions of the main control board 61 in cooperation with the main CPU 81. Is. Furthermore, the terms "lottery" and "lottery" are used properly depending on the case, but these are terms having the same meaning.
<Relationship between the first control and the second control>

Next, the above-mentioned first control and the first control program, and the second control and the second control program will be described. FIG. 11 shows an example of the memory map of the main CPU 81. The memory map in FIG. 11 shows the address space from "0000H" to "FFFFH". Of these, the built-in ROM is allocated a space from "0000H" to "2FFFH", and the built-in RWM is allocated a space from "F000H" to "F3FFH".

Further, a register area (built-in register area) for a register built in each circuit in the main CPU 81 is allocated to the space from "FE00H" to "FEBFH". Then, by causing the main CPU 81 to execute an instruction to access these addresses, it is possible to execute access to the corresponding hardware.

The configuration of the built-in ROM (0000H to 2FFFH) described above can be divided into a first ROM area and a second ROM area. Of these, the first ROM area is mainly an area that controls the progress of the game. In addition, the second ROM area is an area that controls processing related to a situation different from the normal progress of the game, such as mainly related to errors.

The first ROM area has a first control area (from "0000H" to "11FAH") and a first data area (from "1200H" to "1D9EH") shown on the right side in the drawing. Further, the second ROM area also has a second control area (from "2000H" to "22E4H") and a second data area (from "22E5H" to "2346H") shown on the right side in the drawing. ..

Further, the second control region has an unused region (1D9FH to 1FFFH) interposed between the second control region and the first data region described above. Further, the final address (22E4H) of the second control area and the start address (22E5H) of the second data area are continuous, and the unused area (2347H to 2FBFH) follows the final address (2346H) of the second data area. ) And a management area (2FC0H to 2FFFH) are provided.

In this embodiment, the first ROM area is configured to have a larger capacity than the second ROM area. For example, the first ROM area does not include the unused area and consists of only the first control area and the first data area. Similarly, the second ROM area does not include the unused area and includes the second control area and the first data area. This relationship is established even when the data area consists of only two data areas. The memory map shown in FIG. 11 is an example, and the number of bytes in each area and the presence / absence of an unused area can be changed in various ways.

The configuration of the built-in RWM (F000H to F3FFH) described above can be divided into a first RWM region and a second RWM region. Of these, the first RWM area may be referred to as an area (used area) in which information mainly based on the progress of the game (game data) is written and stored as needed, and the written information is further updated. ). Further, the second RWM area is an area (sometimes referred to as outside the used area) for storing information based on processing different from the normal progress of the game such as error-related. It can also be said that the first RWM region is the RWM region used in the first control, and the second RWM region is the RWM region used in the second control.

The first RWM area has a first work area (from "F000H" to "F14AH") and a first stack area (from "F1D7H" to "F1FFH") shown on the right side in the drawing. Further, the second RWM area also has a second work area (from "F210H" to "F21EH") and a second stack area (from "F3F3H" to "F3FFH") shown on the right side in the drawing. .. Here, it is also possible to define the second RWM region to start from F200H.

The first stack area is an area used when the program related to the first control needs to store data internally, and the second stack area is a program related to the second control. Is an area used when it is necessary to store data internally. Then, in the first stack area and the second stack area, for example, the return address information (return address data) stored at the time of transition to the subroutine is written at any time according to the situation of the game. The memory map shown in FIG. 11 is an example, and the number of bytes in each area and the like can be changed in various ways.

An unused area (16 bytes of F200H to F20FH) having a predetermined size is provided between the first stack area and the second work area. It is conceivable that this unused area is essential. Further, unused areas (F14BH to F1D6H, F21FH to F3F2H) having a predetermined size are provided between the first work area and the first stack area, and also between the second work area and the second stack area. ing. It is conceivable that these unused areas are not essential.

The first RWM region has a larger capacity than the second RWM region. Further, in this embodiment, the set of the first work area and the first stack area is set as the first RWM area, and the set of the second work area and the second stack area is set as the second RWM area. However, the present invention is not limited to this, and it is possible to adopt a configuration in which the first stack area is not included in the first RWM area and the second stack area is not included in the second RWM area. In this case, for example, it is possible that the first RWM area is allocated to the space from "F000H" to "F14AH" and the second RWM area is allocated to the space from "F210H" to "F21EH". Is.

Here, it is preferable to configure the ROM mounted on the main control board so that an unused area (unfilled area) is not provided in order to prevent a program or the like modified by fraudulent activity from being written. Is. In order to do so, for example, it is conceivable that all the unused areas are filled with 0, and the used areas are packed in the younger (smaller numerical value) addresses and written. In the unused area in this embodiment, all the bits are "0", and in the area other than the unused area, any bit is "1"("0").
Is no longer).
<Initiation and scope of RWM initialization>

Next, the trigger and range of initialization of the first RWM region and the second RWM region will be described. First, the trigger and range of initialization of the first RWM region are defined as follows (1) to (3) in this embodiment according to the situation of recovery from power failure.
(1) When the power supply / disconnection / recovery cannot be normally executed when the setting change device is operating, data 0 is set in the first RWM area (“F000H” to “F1FFH”).
(2) When the setting change device is operating, except when the power off / off cannot be normally executed. In the first RWM area ("F000H" to "F1FFH"), the set value data, the interrupt counter, the built-in random number processing random number, Data 0 is set in the range (“F008H” to “F1FFH”) excluding the initial value of the soft random number and the RT state number.
(3) When the power is turned off and restored The work area (first work area) of the first RWM area ("F000H" to "F1FFH") and the area excluding the maximum usage amount of the first stack area ("F14BH" to "F1D6H") ") Is set to data 0.

Next, the trigger and range of initialization of the second RWM region will be described.
(1) When the setting change device is operating Data 0 is set in the second RWM area (for example, "F200H" to "F3F5H") excluding the stack usage amount when the setting change device is operating.
(2) When the power is turned off and restored The work area (second work area) of the second RWM area (for example, "F200H" to "F3FFH") and the area excluding the maximum usage amount of the second stack area (for example, "F200H" to "F200H") Data 0 is set in "F20FH" and "F21FH" to "F3F2H").

The first work area can be referred to as, for example, a "work area of a used area". Further, the first RWM area may include the first work area. For example, from the start address of the first work area to the final address of the first stack area (F14BH to F1D6H in the example of FIG. 11 are unused). The region is included) may be used as the first RWM region. Further, the same applies to the second RWM area, for example, from the start address of the second work area to the final address of the second stack area (including the unused area of F21FH to E3F2H in the example of FIG. 11) as the second RWM area. May be good.

Here, with respect to the first control area, the first data area, the second control area, and the second data area, which are the areas used for the ROM data, for example, "writing is not performed during the game" based on the intended use. It can be called an "area" or the like. Further, the first work area, the first stack area, the second work area, and the second stack area can be referred to as, for example, "an area where writing can be performed during the game" based on the intended use.

Then, as described above, by arranging the built-in ROM area and the built-in RWM area via the unused area (3000H to EFFFH), the "area where writing is not performed during the game" and the "game" are used for different purposes. In the RWM, the "area in which writing can be performed" can be clearly separated structurally (and on the address).

Further, in this embodiment, the first data area is arranged after the first control area 1, and then the second control area 2 and the second data area continue with the unused area (1D9FH to 1FFFH) interposed therebetween. Is arranged. Further, the first work area, the first stack area, the second work area, and the second stack area are arranged with an unused area sandwiched between them. Therefore, both the "area where writing is not performed during the game" and the "area where writing can be performed during the game" are classified without being mixed according to the distinction between the first control and the second control. Can be placed in this state.

The distinction between the first control and the second control can be referred to as, for example, "control distinction", "control classification", "control type", or "control classification". Further, the first control area and the non-second control area, the first data area and the second data area, the first work area and the second work area 2, or the set of the first stack area and the second stack area, respectively. , It can be regarded as the same type of information (data) between different control categories, and it can be said that the data type is the same for each of these sets.

Then, in this embodiment, the same data types (first control area and second control area, first work area and second work area, etc.) between different control categories as described above are adjacent to each other. It can be said that the area is arranged without any problem.

Further, in the present embodiment, an unused area is provided between the first stack area and the second work area in the built-in RWM area which is the “area where writing can be performed during the game”. Then, in the region of the built-in RWM, regions of different control divisions (first control and second control) are arranged via unused regions without being adjacent to each other and without being mixed.

Further, in this embodiment, for example, when the control is performed according to the first control program, the writing (update, etc.) to the second RWM area is not performed, and the control is performed according to the second control program. When is performed, writing (update, etc.) to the first RWM area is not performed. However, for example, when control is performed according to the first control program, reference (confirmation, etc.) of the data in the second RWM area may be performed, and control is performed according to the second control program. If so, referencing (confirming, etc.) the data in the first RWM area may be performed.

Further, as will be described later, when returning to the first control after shifting from the first control to the second control, or when returning to the second control after shifting from the second control to the first control, the transition is performed. The contents of the register are kept the same when returning.

According to the area arrangement and handling of the RWM as described above, for example, the first work area related to the first control and the second work area related to the second control can be set to the same data type between different control categories. It is possible to prevent a situation in which the corresponding data is stored in an adjacent area or address. Therefore, for example, even if a fraudulent third party tries to search for predetermined data generated during the game by tracing the RWM address in ascending or descending order and confirming the stored data, the necessary data is required. Cannot be detected efficiently.

That is, it is the first work area and the second work area that store various winning combination lottery results and error information in the game. Therefore, even if a third party tries to find the first work area or the second work area by tracing the addresses in ascending or descending order, there are unused areas and stack areas for storing the return address before and after. Therefore, it is not possible to reach the first work area or the second work area immediately.

Further, even if the detection destination is to be moved from the first work area to the second work area (or from the second work area to the first work area), the target work area is immediately obtained due to the existence of the unused area or the first stack area. Cannot reach. As a result, it becomes possible to delay access to information necessary for fraudulent activity, and it is possible to prevent or deter fraudulent activity.

Further, in the present embodiment, the program code existing in the first control area and accessed from the main CPU 81 and the program code existing in the second control area and accessed from the main CPU 81 are separated on the memory map. It can be arranged (in an arrangement where the addresses are not continuous). Further, since an unused area (1D9FH to 1FFFH) is sandwiched between the first control area and the second control area, the arrangement of both program codes is visually clarified on the program source code or the dump list. It is possible to cut into. It is also possible to prevent fraud by such separation.

Further, in this embodiment, the writing of data to the RWM is limited to the RWM area defined for the control category being executed. That is, between the first control and the second control, the control division is transferred in a predetermined case, and in the situation where the first control is performed, the data about the second work area and the second stack area is performed. No writing or data update is performed, and in a situation where the second control is performed, data writing or data update for the first work area and the first stack area is not performed.

Then, the data in each control division is written only to the work area or stack area corresponding to the control division within the control division without shifting to another control division. Therefore, the first control and the second control can be clearly separated in terms of processing of the main CPU 81, which enables deterrence of fraud and early detection.

The built-in ROM area (0000H to 2FFFH) is divided into an area related to the first control (0000H to 1D9EH) and an area related to the second control (2000H to 22E4H). Then, by shifting between the first control program and the second control program and performing the control process, it is possible to perform the game control while clearly separating the first control and the second control. <Processing when the power is turned on on the main control board>

Next, the processing at the time of turning on the power on the main control board will be described. When the main CPU 81 of the main control board 61 is turned on via the power supply unit 64, the program code arranged at the address (first control area) that becomes "0000H" of the internal ROM (see FIG. 11) described above It will be executed in order. The main CPU 81 sets the Q register to "F000H" based on the data in the ROM area and the RWM area related to the first control.

Next, the main CPU 81 executes the function setting of the main control based on the data in the ROM area and the RWM area related to the first control. Further, the main CPU 81 calculates a checksum based on the data in the ROM area and the RWM area related to the first control, checks the first RWM and the second RWM (for example, holds them in the calculated checksum and checksum area). Based on the checksum data that has been set, it is checked whether the data stored in the built-in RWM is correctly held by turning off the power and returning from the power off), and the power off / returning data is generated.

Explaining with reference to FIG. 12, when the power of the main control board 61 is turned on to the main CPU 81, the processing at the time of turning on the power shown in FIG. 12 (“program start processing”, “processing at power ON”, or “processing at power on” "And so on.) Is executed. In the process at the time of turning on the power, the initial value is set for a predetermined register (S1), and in the process for initializing the register, the initial value is set in the register built in the main CPU 81. The contents of the setting include the setting of the communication speed of the serial communication circuit provided in the main CPU 81, the setting of the interrupt type (mode), the setting of the parity given to the command to be transmitted, and the like. Further, in this embodiment, only one type of masquerade interrupt is used as the interrupt type among the various interrupt types that can be used. In addition, even parity is used in the parity setting.

Subsequently, a masqueradable interrupt is set (S2), and access to the RWM is permitted (S3). Further, the built-in random number is set (S4), and the RWM check is performed. In this RWM check, the checksum calculation (S5) and the power-off processing flag indicating that the power-off processing has been completed are used to determine whether or not the backup at the time of the previous power-off processing is normal. Power on / off recovery data is generated. In the above-mentioned checksum calculation (S5), the checksum is the same storage area range as the RWM checksum in the power off processing (described later) (here, “F000H” to “F3FFH” of the built-in RWM in FIG. 11). To execute.

Further, in the checksum calculation (S5), after the calculation process, it is determined whether or not the calculation for the entire target range is completed (S6), and if the calculation for the entire range is not completed (S6). S6: NO), the process returns to the calculation process (S5). Then, the checksum calculation is repeated until the calculation for the entire target range is completed. Here, it may be determined whether or not the calculation for the entire target range is completed after the calculation for each address, or after the calculation for each predetermined range.

After the checksum calculation for the entire target range is completed (S6: YES), the power supply / disconnection / recovery data is stored in the register (S7). Here, the power-off / recovery data differs depending on whether either the power-off execution processing flag or the RWM checksum is abnormal and the case where both are normal. Further, the data of the input port 1 is stored in the register (S8). Here, the data of the port (input port 1) to which the designated switch signal of the next step (S9) is input is acquired.

Subsequently, it is determined whether or not the designated switch is ON (S9). The designated switch refers to three switches: a door switch, a setting door switch, and a setting key switch. Then, the states of the door switch signal, the setting door switch signal, and the setting key switch signal are checked (S9), and when all the switch signals are ON (S9: YES), the setting change device processing described later (see FIG. 13). I do. Here, in the present embodiment, when all the switch signals are ON, the above-mentioned door (front door portion 11) is opened, the setting door of the setting unit 62 (see FIG. 4) is opened, and the setting key switch 68. Is rotating in the ON direction, and the determination result of S9 is "YES" when these three conditions are satisfied. The setting door switch may be excluded from the designated switch, and the setting changing device may be activated if the two switches, the door switch and the setting key switch, are in the ON state.

For example, when the door (front door portion 11) is closed (when the door switch is in the closed state), the setting door of the setting unit 62 (see FIG. 4) is in the open state, and the setting key switch 68 is turned on. Even if the rotation is in the direction, the judgment of S9 is not "YES". In such a case, there is a possibility that fraud has been performed. Therefore, by not setting the judgment result to "YES", it is necessary not to shift to the setting change device processing (also referred to as "setting change processing") described later. It has become. When the setting door switch 67 (see FIG. 4) is not provided, the case where all the switch signals are ON is the result of checking the state of the door switch signal and the setting key switch signal in the determination process of S9. Indicates that is ON.

If the condition is satisfied and "YES" is satisfied in the determination (S9) of whether or not the above-mentioned designated switch is ON, it is determined whether or not the power supply cutoff / recovery data is abnormal (S10). ). If an affirmative judgment is made in the determination (S10) relating to the power off / returning data and the result is "YES" (when the power off / returning data is abnormal), the setting change device processing (see FIG. 13) described later. Move to. If a negative judgment is made and the result is "NO" (when the power off / returning data is not abnormal), it is determined whether or not the setting change impossibility flag is ON (S1).
1) Even when a negative judgment is made and the result is "NO" (when the setting change impossibility flag is not ON), the process proceeds to the setting change device process (see FIG. 13).

Further, in the determination (S11) relating to the setting change impossibility flag, if an affirmative determination is made and the result is "YES" (when the setting change impossibility flag is ON), the confirmation of the power off / returning data described later is performed. The process proceeds to (S12). The setting non-changeable flag is one of the data stored in the RWM, and is between the combination lottery process (S60) and the check at the end of the game (S68) in the game progress main process (see FIG. 14) described later. Is data indicating that the setting cannot be changed.

In the determination (S9) of whether or not the above-mentioned designated switch is ON, when at least one of the switch signals is not ON (S9: NO), or the above-mentioned setting change impossibility flag is ON. In the case (S11: YES), the process proceeds to the process of confirming the power off / returning data (S12). In the process of confirming the power-off / recovery data (S12), the power-off process (described later) is performed at the time of the previous power-off, and the predetermined RWM area is calculated at the time of the previous power-off. If the value of the checksum is normal, it is determined to be normal, and in other cases, it is determined to be abnormal.

In the process of confirming the power failure / recovery data (S12), if it is determined that the power supply / failure recovery data is abnormal (S12: NO), an error display is executed (S13), and an error code corresponding to the acquired number display LED (S12) E1) is displayed and the operation of the game machine is stopped. The E1 error, which is an error at this time, is an error that cannot be cleared unless the setting change device process (see FIG. 13) is executed, and even one of the non-recoverable errors (non-recoverable error) as described later. is there. In the process of confirming the power supply / disconnection / recovery data (S12), if it is determined that the power supply / disconnection / recovery data is normal (S12: YES), the process proceeds to the power supply recovery process (see FIG. 21). The power restoration process (see FIG. 21) will be described later.
<Setting change device processing>

FIG. 12 shows the above-mentioned setting change device processing. In this setting change device processing, the stack pointer is set and the operation of the setting change device is started. Then, as shown in the figure, the predetermined range of RWM initialization is stored in the register (S21), but here, as the "predetermined range" related to RWM initialization, when it is determined that the power off processing is normally executed. The above-mentioned storage area range (here, addresses F000H to F3FFH in FIG. 11) is set. Further, here, the set value data related to the above-mentioned set value, the RT state number related to the replay time (RT), and the condition device flag related to the above-mentioned condition device are not stored as initialization targets. Here, the RT (replay time) is a gaming state in which the winning probability of the re-game is higher than usual, and the RT state number is a number for distinguishing a plurality of RT states having different winning tendencies of the re-game. .. Further, the set value can be explained as defining the theoretical ease of hitting (the degree of advantage of the player) as described above, but more specifically, the set value is different from the set value, for example. It can be explained that the winning probability of the winning combination is different. In addition to this, the set value may be used in such a manner that the winning probability of the winning combination is the same, but the winning probability of another lottery (AT lottery or the like) based on the winning of the winning combination is different.

Subsequently, it is determined whether or not the power supply cutoff / recovery data is normal (S22), and it is determined whether or not the power supply cutoff process (described later) is normally performed. This power-off / recovery data is stored in a predetermined register after the checksum calculation is completed in the above-mentioned power-on processing. Then, when it is determined that the power is not turned off normally (S22: NO), the above-mentioned set value data, RT status number, and condition device flag are included in the "specific range" to be initialized. , The storage area range including these is stored in a predetermined register (S23).
.. Here, the "specific range" is distinguished from the above-mentioned "predetermined range" in that it is a range including the set value data, the RT state number, and the condition device flag.

On the other hand, in the determination (S22) of whether or not the power-off / recovery data described above is normal, if it is determined that the power-off has been performed normally (S22: YES), a predetermined register (here, the AF register). Is saved (S24), and the contents of the register (return address) are stored in the above-mentioned first stack area. Then, the transition from the first control to the second control is performed, and the RWM initialization 3 (S25), which is the control module related to the second control described above, is executed. The RWM initialization 3 (S25) is a part of the second control program developed in the second control region described above. Then, in the RWM initialization 3 (S25), of the RWM area (here, F200H to F3FFH) related to the second control, the stack usage amount when the setting change device is operated (the stack area required when the setting change device is operated) is set. The excluded RWM area (F200H to F3F5H) is cleared. The details of this RWM initialization 3 will be described later.

After the RWM initialization 3 (S25), there is a return (S26) of the AF register, and a transition (return) from the second control to the first control is performed. Then, the timer interrupt is activated by the interrupt activation setting process (S27). In the interrupt activation setting process (S27), the interrupt type and the timer interrupt cycle are set. After this processing, the timer interrupt processing (see FIG. 18), which is the timer interrupt processing, can be executed. In this embodiment, as described above, the timer interrupt cycle is 2.235 ms.

Subsequently, the data indicating "setting change start" is stored in the register (S28). The data indicating the "setting change start" is a command for notifying the sub-control board 31 that the setting change device process has been started and is being executed. Further, the process of the control command set 1 (S29) is performed, and in the present embodiment, the process of the control command set 1 (S29) is the process of the control command set 2. The process of the control command set 2 is to save the above-mentioned sub-control command in a ring buffer (transmission buffer) that is temporarily stored before transmission. Here, the process (S29) of the control command set 1 sets the sub-control command indicating "start of setting change" in the ring buffer. The details of the processing of the control command set 2 will be described later.

Subsequently, a check is made to see if the set value is within a predetermined range (S30), and if the set value is not within the normal range (here, any of the six "1" to "6") ( In S30: NO), 1 is set in the set value (S31), and the process proceeds to the process of displaying the setting change device in operation (S31). On the other hand, when the set value is in the normal range (S30: YES), the process shifts to the process of displaying the setting change device in operation (S32) without performing the setting (S31) of the set value (= 1). Here, in this embodiment, the normal range of the set value is set to "1" to "6", and "0" is not used as the value in the normal range. This is because it is possible that the value accidentally becomes "0" when an abnormality occurs in the control for some reason, and such a case can be accurately determined as an abnormality.

In the process of displaying the setting changing device in operation (S32), the lamp (LED) during the processing of the setting changing device is turned on and the set value is displayed. The "lighting" and "display" performed here are processes for setting data (flags) for "lighting" and "display". Specifically, the data set here is the timer after that. By a predetermined process during the interrupt process (see FIG. 18) (here, the LED display process (S549) in FIG. 18), the data is output for driving the setting display LED (66) and the number-of-value display LED. Then, in this embodiment, the set value is displayed on the setting display LED (66), and "---" indicating that the setting change device is operating is displayed on the number-of-sale display LED.

Further, the determination process (S33) relating to the setting / reset button signal (setting / reset switch signal) is performed, and the setting / reset button signal changes from OFF to ON while the door switch signal and the setting door switch signal are ON. If (S33: YES), the process proceeds to the process of updating the set value (S34), and in other cases, the process proceeds to the process of determination related to the start lever 25 (S35). Here, the setting / reset button (69) related to the above-mentioned setting / reset button signal also serves as one button device as a setting button (setting switch) and a reset button (reset switch) as described above. It is a thing. Further, the determination (S33) relating to the setting / reset button signal is performed based on the rising data of the setting / reset button signal.

In the process of updating the set value (S34), the set value is added by 1. However, if the value exceeds the maximum set value (6 in this case) as a result of addition, the set value returns to 1. In the determination process (S35) relating to the start lever 25, when the start lever sensor signal (start sensor signal) is changed from OFF to ON (S35: YES), the determination process relating to the setting key switch 68 (S36) In other cases (S35: NO), the process proceeds to the determination process (S33) related to the setting / reset button signal.

In the determination process (S36) relating to the setting key switch 68, when the door switch signal and the setting door switch signal are ON and the setting key switch signal is changed from ON to OFF (S36: YES), the setting is changed. The process proceeds to the process of clearing the display during device operation (S37), and in other cases (S36: NO), the process of S36 is repeated. In the process of clearing the display during operation of the setting change device (S37), the lamp is turned off during the setting change device processing, and the display of the set value is terminated. More specifically, the setting display LED is turned off and "00" is displayed on the acquired number display LED. The "turning off" and "end of display" performed here are processes for setting data (flags) for "turning off" and "end of display" as described above. Specifically, they are set here. The generated data is used to drive the setting display LED and the number of obtained number display LED by a predetermined process (here, LED process (S549) in FIG. 18) in the timer interrupt process (see FIG. 18) after that. Used for.

Subsequently, the data indicating "setting change completion" is set in the register (S38). The data indicating the "setting change end" is a command for notifying the sub-control board 31 that the setting change device process has been completed. Further, the processing of the control command set 1 (S39) is performed, and the control command set 1 (S39) uses the same control module as the control command set 1 (S29) described above. Then, by the process (S39) of the control command set 1, the sub-control command indicating "setting change end" is set in the ring buffer. Then, after that, the process proceeds to the game progress main process (see FIG. 14), which will be described later.

It was necessary to turn on a plurality of switches when the setting change device was put into the operating state (S9 in FIG. 12), but when the setting changing device was put into the non-operating state, only the setting key switch was used. Is being confirmed (S36 in FIG. 13). That is, it can be said that the condition for ending the operation of the setting changing device is relaxed as compared with the condition for starting the operation.
<< Control command set 2 >>

Next, the processing of the control command set 2 performed in the control command set 1 (S29, S39) described above will be described. In this control command set 2, the control command buffer address is set and the control command write pointer data is acquired. Further, the designated address is set, the designated address data is acquired, and it is determined whether or not the control command is smaller than "64".

Then, when the control command is smaller than "64", the control command is set, the control command write pointer is updated, and the process is completed. In the determination process of whether or not the control command is smaller than "64", if the control command is not smaller than "64", the control command is not set or the control command write pointer is not updated. Finish the process. <Game progress main processing>

Next, the game progress main process will be described with reference to FIG. Here, the outline of the game progress main process will be described, and among the various control modules used in the game progress main process, the main ones in this embodiment will be described later. In the game progress main process, the stack pointer is set (S51), and in the game start set process (S52), the following processes are performed. That is, in the process (S52) of this game start set, the game state is set.

That is, in the game start set process (S52), the game start set is performed. Further, although not shown, the game standby display start time is set, the pull-in symbol data is cleared, and the operation state set is entered.

More specifically, based on the symbol combination stopped and displayed in the previous game, whether this game is a re-game or a game in which the accessory continuous operation device related to the above-mentioned first-class special accessory is activated. Set the data indicating whether it is (Type 1 BB game). In addition, wait for the weight after the sub-bonus. Here, the sub-bonus is a bonus managed on the side of the sub-control board 31 described above, and is continued over a predetermined number of games thereafter when, for example, a specific replay (specific replay) is hit. It means a game state such as.

As a specific example, the symbols "7" are displayed in line on the winning line in the production, and the winning state of the specific replay is set. Furthermore, AT (assist time) is applied for 30 games from the winning of the specific replay. A gaming state such as giving a profit by setting the state can be mentioned. And, the weight waiting after the sub-bonus means the waiting time for performing the bonus end demonstration in the same way as the bonus (main bonus) managed by the main control board 61 when the AT state ends. .. Then, the start trigger of the standby time can be set as when 30 games have elapsed since the specific replay was won on the main control board 61 side.

Subsequently, in the processing (S52) of this game start set, although not shown, commands indicating various game information are written to the command buffer. Further, the fullness detection signal is checked, and if the game medal auxiliary storage 71 is full, an error code (FE) indicating that effect is displayed on the acquired number display LED, and the game is stopped.

If the game medal auxiliary storage 71 is not full or the error is cleared, the game medal insertion is accepted. In accepting the insertion of the game medal, when the re-game is not activated, the blocker signal is turned ON (passable state) and the acceptance of the insertion of the game medal is started. In the case of re-game operation, if the game medal can be inserted into the storage device (if the maximum number of credits has not reached 50), the blocker signal is turned ON (medal flow path formation) and the storage device is loaded. If the game medals cannot be inserted, the blocker signal is not turned on, and the game medals of the number of bets in the previous game are automatically inserted. The blocker processing at the time of re-game operation will be described later.

In the game progress main process, subsequently, as shown in FIG. 14, the game medal reading process (S53) is executed. In this game medal reading process (S53), the game medal number data is read and the presence or absence of the game medal number is checked. After the process of reading the game medal (S53), the presence or absence of the game medal is checked (S54), and if there is no game medal (S54: NO), the display when waiting for the game medal to be inserted (the medal can be inserted). (S55), and if there is a game medal (S54: YES), the process proceeds to the game medal management process (S56). Here, the presence of a game medal indicates a state in which a game medal is set (bet) in order to satisfy a specified number for playing a game.

In the display processing (S55) when waiting for the game medal to be inserted, when the setting key switch signal changes from OFF to ON, the blocker is turned off and the control command at the start of the installation value display is set. Further, the set value is displayed on the setting display LED until the setting key switch signal is changed from ON to OFF. Then, the control command at the end of the set value display is set, and the blocker is turned on. Then, when the game standby display start time has elapsed, the process proceeds to the process of clearing the acquired number display, and in other cases, the process ends.

In the game medal management (S56), the blocker status confirmation process is performed, and in the blocker status confirmation process, the insertion process based on the inserted game medals, the settlement button and the MAX bet button (three insertion buttons) are performed. ) Is performed based on the operation. This game medal management (S56) will be described later (see FIG. 26). Further, after the game medal management process (S56), the soft random number update 1 (S57), which is a process for updating the soft random number, is performed. In this soft random number update 1 (S57), the soft random number update 2 is performed, but the soft random number update 2 updates the built-in random number processing random number.

Subsequently, in the start lever check process (S58), the reception check of the start lever is performed. That is, although not shown, the insertion / withdrawal sensor abnormality display is performed, and if the number of insertions does not match the specified number, the process ends. Further, when the monitoring time when the blocker is ON (the monitoring time when the blocker is ON) has not elapsed, the game start display LED signal is turned off and the process is terminated. Then, the game start display LED signal is turned on. Then, when the start lever sensor signal changes from OFF to ON, the process shifts to the start lever reception, and in other cases, the process ends.

More specifically, as a reception check of the start lever 25, the following processes are performed in order. That is, the selector passage sensor retention flag indicating whether or not the game medals are accumulated in the selector passage is checked, and if the game medals are accumulated, the error code (CH) corresponding to the acquired number display LED is displayed. Stop the game. In other cases or when the error is cleared, the input sensor abnormality detection data is checked, and when an abnormality input is detected, the error code (C0) corresponding to the acquired number display LED is displayed and the game is stopped. To do. Specific processing for these will be described later.

Furthermore, in other cases (when no abnormal input is detected) or when the error is cleared, the payout sensor abnormality detection data is checked, and when an abnormal input is detected, H0 is displayed on the acquired number display LED. Display and stop the game. Furthermore, in other cases (when no abnormal input is detected) or when the error is cleared, the overflow detection data is checked, and when the game medal auxiliary storage is full, FE is displayed on the acquired number display LED. Stop the game. In other cases (when the game medal auxiliary storage is not full) or when the error is cleared, the process proceeds to the following.

That is, the number of inserted game medals is compared with the specified number, and if the number matches the specified number, the process proceeds to the next process (process of deciding whether or not to accept the start lever (S59)), and in other cases, the process proceeds to the next process. As the start lever cannot be accepted, the process returns to the game medal reading process (53). Further, in the process (S59) of deciding whether or not to accept the start lever described above, the stop button 2
When 4L to 24R, the clearing button and each input button are not operated, and the start lever sensor signal changes from OFF to ON, the start lever is accepted, and in other cases, the start lever is not accepted. Then, the blocker 47 of the game medal selector 44 is turned off (solenoid OFF), and the game medal selector 44 is put into a return state in which the game medal cannot pass.

In the determination process related to the start lever reception (S59), if it is determined that the start lever is not accepted (S59: NO), the process returns to the game medal reading process (S53), and in the case of the start lever reception (S59: YES). , The built-in random number (hardware random number) is taken in, and the process proceeds to the internal lottery start process (S60), which is the combination lottery process. Here, the loop processing (S53 to S59) in the case where it is determined that the start lever is not received (S59: NO) is arranged after the stack pointer set (S51), and therefore, the stack pointer set (S51). Is always executed before the loop processing (S53 to S59).

In the process of starting the internal lottery (S60), the combination lottery related to the condition device (replay, winning combination, accessory, accessory continuous operation device) and the internal lottery process for determining the symbol control number and the like are performed. In the internal lottery process, different winning combination drawing tables are used according to the gaming state, and the type of winning number (winning combination) and the winning probability are different according to various gaming states and RT states. Further, as the random number for the internal lottery, a random number obtained by adding a processing random number (here, a software random number) to the above-mentioned built-in random number is used. Further, for lottery related to various roles, the order of lottery is determined based on the type of role. The details of the internal lottery start process (S60) will be described later (see FIG. 15).

In the rotation cylinder management processing (S61 to S65) including the rotation cylinder rotation start processing (S61), management of acceleration to stop of the rotation cylinder is performed. Further, although the illustration is omitted, the rotation cylinder management processing (S61 to S65) is also executed in the pseudo game start processing, which is the processing for performing the above-mentioned pseudo game. Then, in the rotation cylinder management process (S61 to S65), the mechanism related to the rotation of the rotation cylinder is controlled, which will be described later.

In the process of starting the rotation of the rotating cylinder (S61), the data set for starting the rotation of the rotating cylinder and the inspection of the rotation defect are performed. More specifically, it is determined whether or not there is a round cylinder with a data set request (data set request round cylinder), and if there is a data set request round cylinder, data is set in the requested round cylinder. Further, when a rotation failure is detected in the rotating cylinder at a constant speed, the required data of the acceleration state set is set for the rotating cylinder, and the process returns to the determination of the presence / absence of the data set required rotating cylinder described above. Then, when there is no data set request rotation, the process proceeds to the soft random number update process 1 which is the control module described above.

Following the rotation cylinder rotation start process (S61), the number of shifted frames (pull-in point) is created (S62). In this process of creating the number of shifted frames (S52), data indicating the number of shifted frames is created for all the rotating cylinders that have not been stopped. More specifically, although not shown, if there is no request for creating the number of shifted frames, the process ends. Further, the following processing is performed on all the rotating cylinders for which there is a request for creating the number of shifted frames in the order of the third cylinder (51R), the second cylinder (51C), and the first cylinder (51L).

First, the RWM address for storing the table search number used for creating the number of shifted frames is saved. Subsequently, the control rotation number is saved in the RWM, and the pull-in point initialization process for the number of symbol array frames is performed. Further, the control control execution process is performed, and the table set control process is performed. Further, the process of initializing the control symbol number is performed, and the following process is performed for each control symbol number.

First, the process of creating a stoptable position is performed. Subsequently, the number of shifted frames is stored in the RWM corresponding to the control rotation cylinder and the control symbol number. Furthermore, the request for creating the number of shifted frames is cleared, and the process shifts to the interrupt waiting process.

After the process of creating the number of shifted frames (S62), the process proceeds to the process of checking the rotation stop reception (S63). In this rotation stop acceptance check process (S63), for the check related to the stop operation, first, the sensor of the whole rotation cylinder is checked, and if the stop acceptance is not possible, the process is terminated. Further, when any of the output signals (stop button sensor signals) of the stop button sensor corresponding to the rotating cylinder is turned on, the process proceeds to the process of accepting the stop button. Further, the stop reception information data is set according to the rotation or stop state of the full rotation cylinder, the stop position is determined, and the process proceeds to the all rotation cylinder stop check process (S64).

In the process of checking the stop of all rotations (S64), it is checked whether all the rotations are stopped and whether the operation of the stop buttons (24L, 24C, 24R) and the start lever 25 is completed. In this process of checking all rotation cylinders (S64), all rotation cylinders 51L to 51R are stopped, and the operations of the start lever 25 and the stop buttons 24L to 24R are started at the third stop as described above, for example. It is checked whether the lever 25 or any of the stop buttons 24L to 24R has been properly operated without being continuously operated.

In the subsequent processing of determining the total rotation stop (S65), if an affirmative determination is made (S65: YES), the process proceeds to the display determination processing (S66), and in other cases, the processing of creating the number of staggered frames (S65). Return to S62).

In the display determination process (S66), the following processes are performed in order. That is, if the combination display of the symbols is abnormal as a result of the display determination, the error code (E5) corresponding to the acquired number display LED is displayed and the operation of the game is stopped.

Subsequently, the process proceeds to the process of paying out the game medals by winning a prize (S67). In the process of paying out game medals by winning (S67), if there is a game medal paying out by winning, the game medal is paid out. Further, although not shown, when paying out the game medals, a display process for displaying the number of paid out game medals is performed. In this display process of the number of game medals, the value displayed on the display device (here, the stored number display unit) is updated every time one game medal is paid out.

More specifically, in order to pay out the game medals by winning and manage the number of payouts when the BB is operated, first, a control command at the start of paying out the game medals is set. Subsequently, the number of times the medal payout signal is output is set, and if there is no game medal payout number, the process ends. Further, the number of sheets that can be acquired when the BB is operated is updated, and the process described later is performed for the number of sheets to be paid out, and the control command at the end of paying out the game medals is set.

As the above-mentioned processing for the number of payouts, first, the following processing is performed according to the payout destination of the game medals. That is, if the payout to the storage device is possible, one stored number is added after waiting for the addition time, and if the payout to the storage device is not possible, one game medal is paid out. Subsequently, 1 is added to the acquired number data as a process according to the number of payouts.

Next, the process (S68) at the end of the game is performed. In the process (S68) at the end of the game, first, the re-game display LED is turned off. Subsequently, the re-game operation status flag and the winning and re-game condition device numbers are cleared. Further, in the case of BB operation, BB operation management processing is performed, and in the case of RB operation, RB operation management processing is performed. If the bonus is not in operation, the process shifts to the RT status management process.

After that, the output request at the end of the game is set (S69), the control command set 1 described above is performed (S70), and the game progress main process is executed again. Even if a prize is generated in the accessory or the continuous operation device, if the corresponding combinations of symbols are not prepared, the flags related to these prizes are carried over. In addition, the flags related to the replay and small role condition devices are cleared. That is, as the end processing according to the game state described above, the RWM clear processing of the condition device number other than the carry-over combination, the RT number generation processing, the freeze state transition processing, the external signal data generation processing, and the like are performed. Will be.

Subsequently, among the various processes in the game progress main process (S51 to S70), the internal lottery start process (S60) will be described in more detail. As described above, the internal lottery start process (S60) is a process of shifting when the reception of the start lever operation is detected in the situation where the game can be started. As shown in FIG. 15, in the internal lottery start process (S60), the condition device number set (S81), the symbol control number set (S82), the pull-in symbol data set (S83), the control symbol set (S84), and the ball ejection Each process of lottery management (S85), condition device command set (S86), rotation cylinder rotation start standby (S87), and rotation cylinder rotation start preparation (S88) is executed in order.

Of these, in the condition device number set (S81), first, it is determined whether or not the bonus condition device is operating. Then, if the bonus condition device is not in operation, the data indicating the bonus condition device number is saved (S502), and the data indicating the winning and re-game condition device numbers is saved.

In the above-mentioned ball-out lottery management process (S85 in FIG. 15), the data related to the effect group number is set, the designated number is set, the main game state management process is performed, and the condition device command set process (FIG. 15). Move to S86) of 15.

In the processing of the condition device command set (S86 in FIG. 15), as shown in FIG. 16, interrupts are prohibited (S511), the AF register is saved (S512), the process shifts to the second control, and the symbol is displayed. The stop signal output process (S513) is executed. The symbol stop signal output process (S513) performed as the second control is a process for outputting symbol stop signal data for the test firing test, and the details thereof will be described later (see FIG. 33).

When the processing of the symbol stop signal output (S513) is completed, the process returns to the processing of the condition device command set related to the first control (FIG. 16), and the AF register is restored (S514). Further, the interrupt is permitted (S515), the command table at the time of receiving the start lever is set (S516), and the caller is returned.

In the process of waiting for the start of rotation of the rotating cylinder (S87 in FIG. 15), it is determined whether or not the above-mentioned minimum game time has elapsed, and when the minimum game time has elapsed, the data of the minimum game time is saved. Subsequently, the condition device output time is saved, and the process of waiting for command transmission is performed.

In the process of preparing to start rotating the rotating cylinder (S88 in FIG. 15), the rotating cylinder stop order data and the pushing order data are initialized, and the data related to the rotation cylinder stop flag and the request for creating the number of shifted frames are initialized. Further, the data of the number of initialized symbol groups is set, and the symbol control data table 1 is set. In addition, the initialization start RWM address is set, and the stop symbol data is initialized.

Subsequently, the data related to the output request at the start of full rotation of the cylinder is set, and the same control command set 1 as described above is executed. Then, the rotation start bit and the data related to the rotation start preparation state are set, and the data indicating that the rotation start rotation is present is set.

Next, the display determination process (S66) in the above-mentioned game progress main process (see FIG. 14) will be described. FIG. 17 shows the contents of the processing of the display determination (S66). In this display determination process, the acquired number display clear process (S401) is executed, and then various data set processes (S402, S403) and E5 error set process (S404) are executed.

The above-mentioned acquired number display clear process (S401) is for clearing the acquired number display data, and is the same process as the acquired number display clear process (S339) in the above-mentioned storage input process (see FIG. 27). Is. Further, the above-mentioned various data set processing (S402, S403) includes a set of RWM addresses related to predetermined stop symbol data (S402) and a set of RWM addresses related to the number of control symbol groups and kicking symbol data (S404). Is.

Here, the kick-off symbol data is symbol data that constitutes a symbol combination that does not correspond to the result of the winning combination lottery. Then, the kicking symbol data corresponds to, for example, symbol data related to some symbols constituting the symbol combination of BB in the case where the above-mentioned BB (big bonus) is not applied.

Further, a set calculation related to the kicking symbol is performed (S405), and the correlation between the kicking symbol data and the symbol displayed in the game at this time is calculated. Then, it is determined whether or not the displayed symbol corresponds to the kicking symbol (S406), and if the kicking symbol is displayed (S406: YES), the non-recoverable error processing (see FIG. 29) is performed. Transition. This non-recoverable error processing will be described later.

On the other hand, when the kick-off symbol is not displayed (S406: NO), the next stop symbol data address is set (S407) and the next kick-off symbol data address is set (S408). Then, it is determined whether or not the determination according to the number of control symbol groups is completed (S409), and if it is completed, (S409: YES), the process proceeds to the one-line display determination process (S421). If the determination for the number of control symbol groups has not been completed (S409: NO), the process returns immediately before the calculation process (S405) related to the kicking symbol.

If the determination for the number of control symbol groups is completed in S409 (S409: YES), the process proceeds to S421 and the one-line display determination process is executed. In this one-line display determination process (S421), the display determination of one effective line and the data set at the time of display are performed. Specifically, the operation type, the symbol combination display flag, the game medal payout number data, the payout number buffer, and the winning symbol group are saved according to the symbol combination determined to stop on the valid line.

Subsequently, by the effect display process (S422) when the full rotation of the body is stopped, the process for displaying the effect when the full body is stopped is performed. In this effect display process (S422) when the full rotation of the body is stopped, the process waits until the third stop waiting time related to the third stop operation is passed, the main game state management process is performed, and the full rotation is stopped. The control command at the time is set, and the RWM is initialized when the body rotation is stopped all times.

Further, the process proceeds to the process of displaying the input / payout sensor abnormality (S423), and the process of the input / payout sensor abnormality set is performed, which will be described in detail later. Then, the presence or absence of an error display request is checked, and if there is an error display request, an error display of the corresponding error is performed, and in other cases, the process is terminated. If the error is cleared, the input / payout sensor abnormality is cleared.

FIG. 57 more specifically shows the above-mentioned input / withdrawal sensor abnormality display process (S423 in FIG. 17). In this input / payout sensor abnormality display process, as shown in FIG. 57, interrupts are prohibited (S431), the AF register is saved (S432), and the input / payout sensor abnormality set processing related to the second control is performed. Do (S433). The details of this input / payout sensor abnormality set process (S433) will be described later (see FIG. 36).

After the input / payout sensor abnormality set process (S433), the AF register is restored (S434), interrupt permission is performed (S435), and error display request data acquisition process is performed (S436). In this error display request data acquisition process (S436), error display request data is acquired. Then, it is determined whether or not there is error display request data (S437), and if there is no error display request data (S437: NO), the process ends. If there is error display request data in S437 (S437: YES), the error display process (S438) is performed. Details of this error display process (S438) will be described later (see FIG. 24).

After that, the interrupt is prohibited (S439), the AF register is saved (S440), and the input / payout sensor abnormality clear process (S441) related to the second control is performed. The details of this input / payout sensor abnormality clearing process will be described later (see FIG. 37). After the input / payout sensor abnormality clearing process (S441), the AF register is restored (S442), interrupts are permitted (S443), and the process returns to the first interrupt prohibition process (S431).
<Timer interrupt processing on the main control board>

Next, the timer interrupt processing will be described with reference to FIG. The outline of the timer interrupt processing will be described here, and among the various control modules used in the timer interrupt processing, the main ones in this embodiment will be described later. The timer interrupt process is repeatedly executed at predetermined cycles (here, 2.235 ms) based on the process at power-on shown in FIG. 12 and the start-up in the setting change device process (see S27) shown in FIG. Is.

In this timer interrupt process, as the initialization process at the start of the interrupt, the register value is saved (S541) and the interrupt flag for prohibiting duplicate interrupts is cleared (S542). The register save process (S541) in this initialization process is for enabling the register used in the above-mentioned game progress main process (see FIG. 14) to be used in this timer interrupt process. is there.

Subsequently, the power cutoff process (S543) is executed. In this power off processing (S543), various processes are performed after determining the presence or absence of the power off detection signal, and the details thereof will be described later. Further, the interrupt counter is updated (S544), input port data generation (S545), rotation cylinder drive management (S546), port output (S547), control command transmission (S548), LED display (S549), sub-notification data output. (S550) and timer measurement (S551) are sequentially executed.

Then, after executing these, as shown in the figure, the process proceeds to the error management process (S552, see FIG. 20). Subsequently, the external signal output data management process (S759) and the external signal output process (S760) are performed in this order. Each of these processes (S759, S760) will be described later.

Further, the AF register is saved (S761), the process shifts to the second control, and the test signal output process (762) is performed. The processing of this test signal output (S762) will be described later (see FIG. 35). When the test signal output processing (S762) is completed, the control returns to the first control and the AF register is restored (S763). Then, the soft random number management process (S764) is performed, interrupt permission is performed after the register return (S765), and the process is completed.

In the following, each process (S543, S545-551, etc.) in the timer interrupt process will be described, but first, the power cutoff process (S543) among the above-described processes will be described.
<< Power off processing >>

In the power off processing (S543), as shown in FIG. 19, it is determined whether or not the previous power off detection signal is ON (S561), and if it is ON (S561: YES), this time. Input port 0 data is input (S562). Further, it is determined whether or not the power cutoff detection signal is ON (S563), and if it is ON (S563: YES), the data of the clear output port address and the number of output ports are set (S564).

Subsequently, the output port (0 to 6) is turned off (S565), and the data of the next output port address is set (S566). Further, it is determined whether or not the output is finished (S567), and if it is finished (S567: YES), the stack pointer is saved (S568). If the output is not completed in S567 (S567: NO), the process returns to the process of turning off the output ports (0 to 6) in S565 (S565).

After the above S568, the power off processing flag is set (S569), the RWM checksum data is cleared (S570), and the initial data for calculating the RWM checksum is cleared (S571). In addition, the RWM checksum is calculated (S572), and it is determined whether or not the calculation for all bytes is completed (S573). Further, if the calculation for all bytes is completed (S573: YES), the RWM checksum data is set (S574). Then, the access of the RWM is prohibited (S575), the processing is looped, and the state of waiting for reset is entered (S576).

If the power failure detection signal was not ON last time in S561 (S561: NO), or if the power failure detection signal was not ON in S563 (S563: NO), the process ends. ..

The trigger for executing the power cutoff process is a hardware-like interrupt that generates a non-maskable interrupt (NMI) based on the input of a power cutoff signal indicating a voltage drop to the NMI terminal (not shown) of the main CPU 81. There is software-like processing that confirms the power off flag set when a voltage drop is detected. Further, the power supply cutoff flag may be set based on the power supply cutoff signal input to the NMI terminal to trigger the execution of the power supply cutoff process.
<< Input port data generation >>

Subsequently, in the input port data generation process, the process of reading the input ports 0 to 2 is performed.
<< Rotating cylinder drive management >>

In the above-described rotation cylinder drive management (S546) process, drive control of each rotation cylinder is performed. More specifically, the number of rotating cylinders is set, and the rotating cylinder data address set is processed. Further, when the rotation cylinder drive control is performed and all rotation cylinders are completed, the process proceeds to the port output process (S547 in FIG. 18). If the rotation cylinder drive control is not completed for all rotation cylinders in the above processing, the process returns to the rotation cylinder data address set processing.
<<< Rotating cylinder drive control >>>

Subsequently, the above-described rotating cylinder drive control process will be described. In the rotation cylinder drive control process, it is determined whether or not the rotation cylinder is stopped, and if it is not stopped, it is determined whether or not the rotation start preparation is in progress. Further, in the situation of preparation for starting rotation, the counter for searching the rotating cylinder drive pulse data is corrected, the data in the acceleration state is set, and the data in the rotating cylinder driving state is set in the update address.

Here, in the determination process of whether or not the rotating cylinder is stopped, if the situation is not the situation where the rotating cylinder is stopped, the processing is terminated. Further, in the determination process of whether or not the rotation start preparation is in the state, if the rotation start preparation is not in the state, the data of the rotating cylinder drive state is set in the above-mentioned update address without performing the interim processing. Perform processing.

After the process of setting the data of the rotating cylinder drive state to the update address, the rotating cylinder drive pulse output counter is set to -1 to determine whether or not the output counter is 0. Further, when the output counter is 0, the drive pulse clear data and the stopped state data are set, and the four phases of the motor (rotary cylinder stepping motor) are turned off. Here, in the determination process of whether or not the output counter is 0, if the output counter is not 0, the process ends.

Subsequently, it is determined whether or not deceleration is in progress, and if deceleration is not in progress, the rotating cylinder drive pulse output counter is incremented by 1. Further, it is determined whether or not the rotating cylinder is in a constant speed state, and if it is in a constant speed, it is determined whether or not the rotating cylinder drive pulse data search counter is an even number.

Then, in the determination process of whether or not the rotating cylinder drive pulse data search counter is an even number, if the rotating cylinder drive pulse data search counter is an even number, the rotating cylinder rotation defect detection counter is incremented by +1 and the rotating cylinder drive is driven. Performs pulse update processing. In addition, in the determination process of whether or not the rotating cylinder is in a constant speed state, in the determination processing of whether or not the rotating cylinder is in a constant speed or whether or not the rotating cylinder drive pulse data search counter is an even number, the rotation is performed. If the body drive pulse data search counter is not an even number, the body drive pulse update process is performed without performing the intervening process.

Subsequently, the constant speed state set process is performed to determine whether or not acceleration is in progress. Further, if the vehicle is accelerating, the number of pulse switching is reduced by -1, and it is determined whether or not the number of switching is 0. Then, when the number of switchings is not 0, the data of the rotating cylinder drive pulse output counter is set in the update address.

Further, the data of the number of pulse switchings is acquired, and the rotating cylinder rising pattern table is set. Then, the designated address data set is processed, the rotation control data set of the update address is updated, and the processing is completed. In the determination process of whether or not the number of switchings is 0, if the number of switchings is 0, the interim processing is not performed and the processing ends.

In the above-mentioned determination process of whether or not acceleration is in progress, if the rotating cylinder is not in an accelerating situation, the step number RWM address of one symbol is set to determine whether or not the speed is constant. Further, when the speed is low, the rotation cylinder sensor signal is acquired, and it is determined whether or not the acquired rotation cylinder sensor signal belongs to the rotation cylinder sensor of the rotation cylinder to be controlled.

If it is determined in the determination process of whether or not the acquired rotation sensor signal belongs to the rotation sensor of the rotation body to be controlled, it is determined that the signal belongs to the rotation sensor of the control rotation body. It is determined whether or not the rise of the rotation sensor signal is detected. Further, when the rotating cylinder sensor starts up, the reference symbol number when passing through the rotating cylinder sensor is saved, and the rotating cylinder rotation defect detection counter is initialized.

Subsequently, the reference step number correction value is set, the reference step number when passing through the rotating cylinder sensor is generated, the reference step number when passing through the rotating cylinder sensor is saved, and the process ends. In the process of determining whether or not the acquired rotation sensor signal belongs to the rotation sensor of the rotation target to be controlled, when the acquired rotation sensor signal does not belong to the rotation target rotation. Shifts to the above-mentioned processing of rotating body sensor signal acquisition. Further, in the determination process of whether or not the rise of the cylinder sensor signal is detected, if the rise of the cylinder sensor signal is detected, it is determined whether or not the rotation sensor has passed. Further, in the above-mentioned constant speed determination process, even if the vehicle is not at low speed, it is determined whether or not the rotation sensor has passed.

In the determination process of whether or not the rotating cylinder sensor has passed, if the rotating cylinder sensor has passed, the number of steps of one symbol is decremented by -1, and it is determined whether or not the movement is performed by one symbol. In the determination process of whether or not the rotating body sensor has passed, if the rotating body sensor has not passed, the process ends. Further, when one symbol moves, 16 which is the number of steps of one symbol is saved and the symbol number is updated.

Further, the step number RWM address of one symbol is set, the symbol number is +3, and a predetermined division ((symbol number +3) / 5) is performed. Further, it is determined whether or not the value of the symbol number +3 is a multiple of 5, and if the determination result is not a multiple of 5, the number of symbol steps is corrected and whether or not the deceleration start symbol position is reached. Is determined.

In the determination process of whether or not the value of the symbol number +3 is a multiple of 5, if the determination result is a multiple of 5, the deceleration start symbol is not performed without the above-mentioned correction of the number of symbol steps. The process of determining whether or not the position has been reached is performed. If the rotating cylinder has not moved by one symbol in the above-mentioned determination process of whether or not it has moved by one symbol, it is determined whether or not the deceleration start symbol position has been reached without performing the interim processing. Is processed.

In the deceleration start symbol position determination process, if the deceleration start symbol position is reached, the deceleration pulse counter is set, and if the deceleration start symbol position is not reached, the process ends. .. Further, after setting the deceleration pulse counter, the deceleration state is set, the deceleration pulse data is set, the four phases of the motor are turned on, and the rotating state is set. Here, in the above-mentioned determination process of whether or not deceleration is in progress, if deceleration is not in progress, the process of setting the rotating cylinder state is performed without performing the interim process.

After the process of setting the rotating cylinder state, it is determined whether or not the rotating cylinder state has changed from the start of deceleration to the deceleration, and if the rotating cylinder state changes during deceleration, the rotation of the rotating cylinder is stopped. Set output requests. Then, the processing (reference) of the control command set 2 described above is performed (S649), and the processing is completed. In the process of determining whether or not the rotating state has changed during deceleration from the start of deceleration, if there is no change in the rotating state, the process is completed without performing the interim process.
<< Port output >>

In the above-mentioned port output processing (S547 in FIG. 18), output ports 0 and 1 are output. More specifically, the data of the output port 0 is generated, and the data of the output port 0 is output. Further, the data of the output port 1 is generated (S663), the data of the output port 1 is output, and the process proceeds to the control command transmission process (S548 of FIG. 18).
<< Send control command >>

In the above-mentioned control command transmission process (S548 in FIG. 18), the control command to be transmitted to the peripheral board is output. More specifically, the control command buffer address is set and the control command read pointer data is acquired. Furthermore, the specified address is set, and the transmission target control command address is set. Then, the presence or absence of the control command is determined, and the presence or absence of the control command is determined.
If there is an untransmitted control command, the control command output process is performed and the control command is output to the output ports 7 and 8.

Subsequently, with the sub-control data strobe signal turned ON, the output data is output to the output port 2, the transmitted control command storage buffer is cleared, and the control command read pointer is updated. Further, the output data is output to the output port 2 with the sub-control data strobe signal turned off. Then, the clear data (control command clear data) is output to the output ports 7 and 8, and the process proceeds to the LED display process (S549 in FIG. 18). If there is no control command that has not been transmitted in the above (S675: NO), the output data is output to the output port 2 with the sub-control data strobe signal turned off, without performing the intervening processing. Perform the processing to be performed.
<< LED display >>

In the above-mentioned LED display processing (S549 in FIG. 18), the LED display counter is updated, the LED digit 1 to 5 signals to be output are determined based on the counter value, and the LED digit 1 to 5 signals to be output are used. If there is a display request for the corresponding LED, the LED segments A to G signals corresponding to the output data are set. When there is no display request, all the LED segments A to G signals are turned off. Then, when there is a display request of the LED displayed by the output LED digit 1 to 5 signal and the LED segment P signal, the LED segment P signal is turned on, the LED digit and the LED segment are output, and the LED digit and the LED segment are output. Update the output of the LED segment.

More specifically, the output ports 3 and 4 corresponding to the LED digit segment are turned off, and the LED display counter is updated. Further, it is determined whether or not the LED display counter is 0, and if the LED display counter is 0, the LED display counter is initialized and the data of the LED display counter and the LED display request flag are acquired.

If the LED display counter is not 0 in the determination process of whether or not the LED display counter is 0, the data of the LED display counter and the LED display request flag are acquired without initializing the LED display counter. Further, the data related to the confirmation of the segment display request of the digit to be displayed this time is set, and it is determined whether or not there is a display request. Then, when there is a display request, the error display data is acquired and the error display data is set.

Subsequently, the 7-segment LED segment table 2 is set and the setting data is acquired. Further, the set value display data is generated, and it is determined whether or not there is a set value display request. Then, when there is no request for displaying the set value, the stored number data is acquired and the offset data for the upper digit is acquired.

Further, it is determined whether or not there is a storage number (upper digit) display request, and if there is no storage number (upper digit) display request, it is determined whether or not there is a storage number (lower digit) display request. Do. If there is no request to display the number of stored sheets (lower digit) in S707, the display data during operation of the setting change device, the acquired number of sheets data, and the display data are acquired, and it is determined whether or not an error is displayed. Do.

Subsequently, when an error is displayed in the determination process of whether or not the error is displayed, the 7-segment LED segment table 1 is set and the offset data for the upper digit is acquired. Further, it is determined whether or not there is a request for displaying the number of acquired sheets (upper digit), and if not, the offset data for the lower digit is acquired. In addition, the segment output data is acquired, and it is determined whether or not there is a display request related to the predetermined segment P.

Then, when there is a segment P display request (S715: YES), the segment P output data is set (S716), and output to the output ports 3 and 4 corresponding to the LED digit segment is performed.

If there is no display request in the above-mentioned display request determination process, the process proceeds to the process of confirming the display request related to the above-mentioned segment P without performing the interim process. If there is a set value display request in the above-mentioned determination process of whether or not there is a set value display request, the process proceeds to the segment output data acquisition process.

Further, in the above-mentioned processing for determining whether or not there is a storage number (upper digit) display request, if there is a storage number (upper digit) display request, the above-mentioned processing for acquiring the lower digit offset data. In the above-mentioned process of determining whether or not there is a storage number (lower digit) display request, if there is a storage number (lower digit) display request, the above-mentioned segment output data acquisition process is performed. Move to. Further, in the above-described error display determination process, if the error is not displayed, the offset data for the upper digit is acquired without setting the 7-segment LED segment table 1.

Further, in the above-mentioned determination process of whether or not there is an acquisition number (upper digit) display request, if there is an acquisition number (upper digit) display request, the process proceeds to the above-mentioned segment output data acquisition process. .. If there is no segment P display request described above, the process proceeds to the above-mentioned processing of output to the output ports 3 and 4 corresponding to the LED digit segment.
<< Sub notification data output >>

In the above-mentioned sub-notification data output process (S550 in FIG. 18), in order to output the notification data to be transmitted to the peripheral board, the stop buttons 1 to 3 notification data are set by the stop reception information data. Further, when all the predetermined conditions related to whether or not the game medal limit (also referred to as the storage limit number, 50 in this case) has been reached are satisfied, the three-card insertion button notification data is set. Then, the setting / reset button notification data, the setting key switch notification data, the door switch notification data, and the setting door switch notification data are set by the input port 0 level data. In addition, the broadcast data set in the output port 6 is output.

More specifically, the stop reception information data is set and the game medal limit check process is performed. Further, it is determined whether or not the game medal limit has been reached, and if not, it is determined whether or not the blocker signal is OFF.

If the blocker is not OFF, a determination is made to confirm the number of stored sheets, and if there is a stored number, it is determined whether or not the game medal has passed. Then, in the determination process of whether or not the game medal has passed, if the game medal has not passed, the three-card insertion button notification data is set. Then, the setting / reset button notification data, the setting key switch notification data, the door switch notification data, and the setting door switch notification data are set. Subsequently, the broadcast data set in the output port 6 is output.

If the game medal limit has been reached in the game medal limit determination process, or if the blocker signal is OFF in the blocker signal OFF determination process, the storage number is confirmed. If there is no stored number in the determination process of, or if the passage of the game medal is detected in the determination process of whether or not the game medal has passed, the process of setting the three-card insertion button notification data is performed. First, set the setting / reset button notification data, etc.
<< Timer measurement >>

In the above-mentioned timer measurement process (S551 in FIG. 18), the timer is updated and 1 is subtracted from all the timer RWMs (0 is set if it is less than 0). More specifically, the measurement start timer address is set, and the number of 1-byte timers is set. Furthermore, the countdown process is performed and the next timer address is set. Subsequently, it is determined whether or not the 1-byte timer measurement is completed, and if it is completed, the number of 2-byte timers is set. In the determination process of whether or not the 1-byte timer measurement is completed, if the 1-byte timer measurement is not completed, the process returns to the countdown process.

After setting the number of 2-byte timers in the process of setting the number of 2-byte timers, the 2-byte timer value is updated and the next timer address is set. Then, it is determined whether or not the 2-byte timer measurement is completed, and if the 2-byte timer measurement is not completed, the process returns to the process of updating the 2-byte timer value described above.
<< Error management >>

In the above-mentioned error management (see FIGS. 18 and 20), as shown in FIG. 20, it is determined whether or not the rise of the output signal (selector passage sensor signal) of the selector passage sensor is detected (S751). .. Then, when the rise of the selector passage sensor signal is detected (S751: YES), the monitoring time when the blocker is OFF (about 100.57 ms in this embodiment) and the monitoring time when the blocker is ON are set (S752). Further, the AF register is saved (S753), the process shifts to the second control, and the error check process (S754) is performed. This error check process (S754) will be described later (see FIG. 38).

When the error check process (S754) is completed, the process returns to the first control and the AF register is restored (S755). Further, it is determined whether or not an error is detected (S756), and if an error is detected (S756: YES), an output request at the time of error detection is set (S757). If the rise of the selector passage sensor signal is not detected in S751 (S751: NO), the process between them is not performed, and the AF register save process in S753 is performed.

After setting the output request for error detection in S757, the control command set 2 process described above is performed (S758), and the process ends.
<< External signal output data management >>

In the above-mentioned external signal output data management process (S759), since the output data generation process of the external signals 1 to 5 is performed, the external signals 1 to 3 are generated according to the values of the external signal flag and the external signal 1 management time. Set the output data. Further, when the door switch signal or the setting door switch signal is ON, the output data of the external signal 5 is set. If the setting key switch signal is ON and the output time of the external signal 4 has not elapsed or the error detection flag is output when the power is turned off and restored, the output data of the external signal 4 is set.

More specifically, the external signal flag is acquired, and it is determined whether or not the external signal 1 management time has elapsed. If the external signal 1 management time has not elapsed, the external signal 1 output data is set, and it is determined whether or not the door switch signal or the set door switch signal is turned ON. Then, if it is ON, the output data of the external signal 5 is set, and it is determined whether or not the setting key switch signal is ON.

If the setting key switch signal is not ON, the error detection flag and the data check of the external signal 4 output time when the power is turned off and restored are performed, and it is determined whether or not all the data has been lost. Then, if all the data is not lost, the external signal 4 output data set is performed, and the process proceeds to the external signal output processing (S760 in FIG. 18).

In the above-mentioned determination process of whether or not the external signal 1 management time has elapsed, if the external signal 1 management time has elapsed, the door switch signal or the set door switch signal is transmitted without performing the external signal 1 output data set. It is determined whether or not it is turned ON. If the door switch signal or the setting door switch signal is not ON, it is determined whether or not the setting key switch signal is ON without performing the output data set of the external signal 5.

Further, if the setting key switch signal is ON, the external signal 4 output data set is performed without performing interim processing. Further, if all the data is lost in S778, the process proceeds to the external signal output processing (S760 in FIG. 18) without performing the external signal 4 output data set described above.
<< External signal output >>

In the above-mentioned external signal output processing (S760 in FIG. 18), the output data of the external signals 1 to 5, the medal insertion signal and the medal payout signal are output.
<< Soft random number management >>

In the above-mentioned soft random number management process (see S764 in FIG. 18), the soft random number update 2 process is performed.
<Power recovery processing>

Subsequently, the power restoration process described in the power-on processing (see FIG. 12) described above will be described with reference to FIG. This power supply restoration process is a process of shifting to the case where the power supply off / recovery data is determined to be normal (S12: YES) in the above-mentioned power-on processing (see FIG. 12) on the main control board 61.

In the power recovery process shown in FIG. 21, the value in the stack pointer is returned to the state when the power is turned off (S311), and the data of the initialization start address and the number of initialization bytes when the power is turned off is set (S312). Further, the range defined as the target of RWM initialization is initialized (RWM initialization 1 (S313)), and the AF register is saved (S314). Then, after shifting to the second control and performing RWM initialization 2 (see FIG. 30) described later, the process returns to the first control and the AF register is restored (S316).

Further, in the subsequent input port reading process (S317), the predetermined input ports (0 to 2) are read and the input data is updated from the one before the power is turned off to the latest one. Further, the timer interrupt is activated (S318), the data indicating the power off processing completed flag (power off execution processing flag) is cleared from the RWM (S319), and then the process returns to the processing of the timer interrupt generated when the power is turned off. In the above-mentioned interrupt activation setting process (S318), the interrupt type and the timer interrupt cycle are set. After this processing, timer interrupt processing can be executed. In this embodiment, the timer interrupt cycle is 2.235 ms.

Here, in the input port read process (S317), the timer interrupt is activated after the input port is read (S318), and the input data is rewritten to the latest data in the input port read process (S317) as described above. It is a consideration. For example, if the setting key switch 68 is ON when the power is turned off and the setting key switch 68 is OFF before the power is restored, or if there is no input port read processing (S317) processing, timer interrupt processing is performed. The falling data of the setting key switch 68 is generated by the input port data generation process (see S545 in FIG. 18). Specifically, if the power is turned off and the setting key switch 68 is changed as described above at the time of the above-mentioned "display when waiting for the game medal to be inserted" (see S55 in FIG. 14), the power is turned off. At the time of recovery, an unintended process of shifting from the set value confirmation state to the normal state is executed based on the falling data. Therefore, as described above, the timer interrupt activation (S318) is executed after the input port is read (S317).
<Type of error>

Next, among various errors in the slot machine 10 of the present embodiment, errors related to handling of game medals will be described. The error related to the handling of the game medal includes an error that can be restored after the error is cleared and an error that cannot be restored. Among these, the errors that can be returned include HE error, HP error, HQ error, and FE error, which are errors related to the payout of the game medal, and CP error, which is an error related to the insertion of the game medal. There are C0 error, C1 error, CH error, and CE error.

Among the various errors described above, the HE error is an error when it is determined that the game medal in the game medal payout device 63 is empty, and the HP error is an error in which the game medal exits in the game medal payout device 63. This is an error when it is determined that the product is clogged. Further, the HQ error is an error when it is determined that the payout sensor (not shown) has an abnormal input, and the FE error is an error when it is determined that the game medal auxiliary storage 71 is full as described above. ..

Further, the CP error is an error when it is determined that the inserted game medal has passed illegally, and the C0 error is when it is determined that the insertion sensor (here, the insertion sensor 2) has an abnormal input as described above. Error. Further, the C1 error is an error when it is determined that there is an abnormality in the portion of the medal passage 105 where the insertion sensor 45 and the selector passage sensor 46 are provided, and the CH error is a game in the selector passage sensor 46 as described above. This is an error when it is determined that the medals have accumulated. Further, the CE error is an error when it is determined that the game medal has accumulated in the portion where the insertion sensor 1 (115) or the insertion sensor 2 (116) is provided.

The error release condition related to these errors is that a release operation for changing the signal of the setting / reset button 69 (setting / reset button signal) from OFF to ON is performed with the cause removed. Further, when the door switch signal related to the door switch 60 and the setting door switch signal related to the setting door switch 67 are ON, the above-mentioned release operation becomes effective.

On the other hand, errors that cannot be recovered include E1 error, E5 error, E6 error, and E7 error. Of these, the E1 error is an error when the power supply is cut off and restored normally, and the E5 error is an error when the combination display of the symbols when the cylinder is stopped all the time is abnormal. Further, the E6 error is an error when the set value is out of the range, and the E7 error is a frequency abnormality of the clock input to the RCK terminal (not shown) for updating the random number in the main CPU 81, or a built-in random number (16 bits). This is an error when an abnormal update status (random number) is detected.
<< CP error (illegal passage of game medals) >>

Subsequently, the detection modes of CP error, C0 error, C1 error, CH error, and CE error, which are errors related to the insertion of the game medal, will be described. First, regarding the CP error, in the above-mentioned processing at the time of inserting the game medal (more specifically, the processing of the game medal insertion check described later), the ON / OFF order of the insertion sensor as shown in FIG. 8A is normal. Judging that it has passed, it will be in the state of accepting one game medal. That is, in FIG. 8A, the closing sensor ON / OFF order is shown in five stages at the left end. Further, on the right side thereof, the ON / OFF state of the closing sensor 1 signal and the closing sensor 2 signal in each of the stages 1 to 5 is shown. Then, the input sensor 1 signal and the input sensor 2 signal are normally in the OFF state, and are turned ON when a game medal is detected.

When no game medal is detected, both the insertion sensor 1 signal and the insertion sensor 2 signal are OFF, as shown in order 1. Then, when a regular game medal enters the game medal entrance 106 of the game medal selector 44 and flows down the medal passage 105, the insertion sensor 1 signal located on the upstream side of the medal passage 105 comes first, as shown in order 2. It is turned on, and then, while the closing sensor 1 signal is in the ON state, the closing sensor 2 signal is also turned ON as shown in order 3. Further, as the game medal flows down, the input sensor 1 signal is turned off first as shown in the sequence 4, and then the input sensor 1 signal and the input sensor 2 signal are both turned off as shown in the sequence 5. Become. Then, when ON / OFF of the input sensor 1 signal and the input sensor 2 signal is detected in such an order, the main CPU 81 (see FIG. 5) determines that one game medal has passed normally. .. More specifically, the main CPU 81 is used for one game when both errors are not detected by referring to the determination result of the error (CH error) of the selector passage sensor arrangement site retention described later. It is judged that the medal has passed normally.

In other cases, it is judged that the game medal has passed illegally, and an error occurs. However, as shown in the sequences 1 to 3 in FIG. 8B, when only the input sensor 1 signal is turned on and detected and the input sensor 2 signal is not detected, the game medal returns to the upstream side. It is treated as a thing, no error occurs, and the input of the input sensor 1 signal is invalidated. The reason why no error occurs in the case shown in FIG. 8B is that the game medal may detect only the insertion sensor 1 even when the blocker is OFF. Even in such a case, if the error notification or the game stop processing is performed, the rhythm of the player's game will be disrupted, so that the error is not determined.
<< C0 error (input sensor error) >>

Next, in the C0 error, as shown in FIG. 8C, the blocker signal, which is the data for controlling the blocker (47), is changed from ON (passing state of the game medal) to OFF (returning state of the game medal). After a predetermined time (about 500.60 ms in this case) elapses after the change to), it is determined whether or not the input sensor 2 signal has been input while the blocker is OFF (return state). This predetermined time is the closing sensor abnormality input detection start time, which will be described later, and is the time until the detection of the abnormal input related to the closing sensor is started.

Then, after a predetermined time (input sensor abnormality input detection start time) has elapsed, when the input sensor 2 signal is input (turned on) even though the blocker signal remains OFF (game medal return state). In the case of), it is determined that the input sensor (45) has an abnormal input, and error monitoring is enabled (ON) as shown in the middle part of the figure. Then, when an error is detected in this way, the input sensor 2 signal is turned on until the error factor is removed, an output request for an error display corresponding to the C0 error is made, and the C0 error is displayed at a predetermined timing thereafter. Will be executed. The timing at which the error is displayed is while waiting for the game medal to be inserted, while waiting for the star lever to be received, or after the whole rotation of the body is stopped.

However, in this embodiment, while the CE error, CP error, CH error, C0 error, or C1 error has already occurred, the detection factor of the C0 error as shown in FIG. 8C is satisfied again. However, it is not judged as an abnormal input.
<< C1 error (medal passage abnormality) >>

Next, in the C1 error, as shown in the middle part of FIG. 9A, when the selector passage sensor 46 is changed from OFF to ON, the input monitoring counter is incremented by 1 as shown in the upper part of the figure. Further, as shown in the lower part of the figure, the insertion monitoring counter is decremented by 1 when the insertion sensor 2 signal when the game medal normally passes through the insertion sensor 45 changes from ON to OFF. Then, every time the closing sensor 2 signal is switched from ON to OFF when there is a normal closing, the closing monitoring counter is subtracted by 1, and when the closing monitoring counter is out of a predetermined range (for example, a range of 0 to 3). Will result in an error.

That is, if the input monitoring counter has a value within the predetermined range, it is determined to be normal, and if it deviates from the predetermined range, it is determined to be abnormal. The maximum value (3 in this case) of the predetermined range related to the insertion monitoring counter can be determined by the relationship between the distance from the selector passage sensor 46 to the insertion sensor 2 (105) and the size of the game medal. For example, when the distance from the selector passage sensor 46 to the insertion sensor 2 (116) exceeds the diameter of the game medal and is equal to or less than the size (here, 50 (= 25 × 2) mm) in which two game medals are arranged side by side. Is assumed to be a case where a maximum of three game medals are lined up between the selector passage sensor 46 and the insertion sensor 2 (116), with the entire one game medal and one copy of each of the two game medals. Will be done. Therefore, the maximum value in the predetermined range related to the input monitoring counter can be set to 3.

Further, the present invention is not limited to this way of thinking. For example, in order to provide more certainty in error detection, the maximum value of the predetermined range related to the input monitoring counter is set to "2", or the error detection accuracy is intentionally relaxed. , It is also possible to set the above maximum value to "4". Further, the maximum value can be set to a value other than "3" or "4" according to the distance from the selector passage sensor 46 to the input sensor 2 (116). Further, the distance from the selector passage sensor 46 to the input sensor 2 (116) may be set as the central portion (optical axis portion) of the microsensor of the input sensor 2 (116) from the most upstream portion of the selector passage sensor 46, or the selector passage. Various settings can be made, such as from the central portion of the sensor 46 to the most upstream portion of the input sensor 2 (116). The input monitoring counter is cleared to 0 when the blocker signal is changed from OFF to ON, as will be described later.
<< CH error (selector passage sensor placement site retention) >>

Next, in the CH error, as shown in FIG. 9B, when a predetermined time (here, the selector passage sensor residence time of 446.97 ms) elapses while the selector passage sensor 46 is ON, the game medal is awarded. It is judged that it has accumulated, and an error occurs. This predetermined time is the residence determination passing time related to the selector passage sensor. Then, when an error is detected, an output request for an error display corresponding to the CH error is made, and the CH error display is executed at a predetermined timing thereafter. The timing at which the error is displayed is while waiting for the game medal to be inserted, while waiting for the star lever to be received, or after the whole rotation of the body is stopped. However, in this embodiment, if a CE error, a CP error, a CH error, a C0 error, or a C1 error has already occurred, the CH error detection factor as shown in FIG. 9B is satisfied again. However, it is not judged as an abnormal input.
<< CE error (retention of input sensor placement site) >>

Next, in the CE error, as shown in FIG. 10, when the retention determination passing time related to the insertion sensor is out of the range of A to C in FIG. 10 at the time of inserting the game medal, it is determined that the game medal has accumulated. However, an error occurs. Here, the time A in the figure is the residence determination passing time from ON to OFF of the closing sensor 1, and the time B is the staying determination passing time from ON of the closing sensor 2 to OFF of the closing sensor 1. Further, the time C is the residence determination passing time from ON to OFF of the closing sensor 2. Then, in this embodiment, each residence determination passage time A to C is 4.47 ms ≦ A <143.03 ms, 2.23 ms ≦ B <98.33 ms, 4.47 ms ≦ C <143.03 ms. ..

As a process at the time of error display, the detected error display output request is performed at the start of error display or at the time of error detection. In addition, the error code corresponding to each error is displayed on the above-mentioned acquired number display LED, and the game is stopped. Here, the stop of the game will be described later. Further, as a process at the time of canceling the error, the acquired number display LED is returned to the state before the error, an output request is made at the end of the error display, and then the game is restarted.
<Control processing related to the insertion of game medals>

Next, the control process related to the insertion of the game medal described above will be described more specifically with reference to FIGS. 22 to 29 and the like. The processing described here is a part of the control module (program module) executed according to the situation in each processing in the game progress main processing (see FIG. 14) and timer interrupt processing (see FIG. 18) described above. .. That is, what will be described here is the control process related to the insertion of the game medal, which is related to the first control, and the one related to the second control will be described later.

Among the control processes related to the insertion of game medals, the process related to the first control includes the process of starting the reception of game medals (see FIG. 22), the process of turning on the blocker (see FIG. 23 (a)), and the process of turning off the blocker (see FIG. 23 (b)), error display processing (see FIG. 24), and input error set processing (see FIG. 25).

Among these control modules, the game medal acceptance start process, the blocker ON process, the blocker OFF process, and the error display process shown in FIGS. 22 to 24 are in the game progress main process (see FIG. 14). It is executed as needed in various processes. More specifically, the process of starting the acceptance of game medals is executed in the process of the game start set (S52) in FIG. 14, and the process of displaying when waiting for the game medal to be inserted is the process of displaying the game in FIG. This is executed in the display process (S55) when waiting for medal insertion. Then, the blocker ON process (described later) is performed after the game medal acceptance start process is performed, the blocker 47 described above is turned ON (passable state), and the game medal can be inserted.

Further, the blocker ON process, the blocker OFF process, and the error display process are versatile processes, and among these, the blocker ON process is, for example, the above-mentioned game medal acceptance start process (FIG. 22). (See), the process of displaying when waiting for the game medal to be inserted (see S55 in FIG. 14), the process of clearing the game medal (see FIG. 28), and the like may be executed depending on the situation.

Further, the blocker OFF process includes a display process when waiting for the game medal to be inserted (see S55 in FIG. 14) and a game medal clearing process (specifically, a blocker OFF process before the game medal is cleared). (Executed), start lever check process (S58 in FIG. 14), start lever reception process (S59 in FIG. 14), and the like may be executed depending on the situation.

Further, the error display process is executed depending on the situation in the game medal clearing process, the start lever check process (S58 in FIG. 14), the game medal payout process by winning a prize (S67 in FIG. 14), and the like. In some cases.

Regarding the control module executed by the timer interrupt processing, the data set in the game progress main processing (see FIG. 14) (for example, a flag indicating abnormality detection) before the occurrence of the timer interrupt processing of the cycle at that time is displayed. It will be handled. Hereinafter, the individual processes listed as the control processes related to the insertion of the game medal will be described, and then the mutual relationship between these processes will be described.
<Start accepting game medals>

The above-mentioned processing for starting the reception of game medals (see FIG. 22) is the processing for starting the reception of game medals, and the game medal selector 44 (see FIGS. 2, 6, and 7) is in the state of returning the game medals (see FIGS. 2, 6, and 7). When a predetermined condition is satisfied, the game medal can be inserted from the game medal insertion slot 21 (see FIG. 1) by controlling the game medal acceptance state (passable state) from the non-passable state. We are doing the processing to do so. As shown in FIG. 22, the process of starting the acceptance of game medals first clears the game medal number data (S101), and then turns off the inserted number display LED (S102). Further, the game medal management flag is initialized (S103), and the operation flag check process (S104) is executed. This operation flag check process (S104) is a process for confirming the presence / absence of operation of the accessory, the accessory continuous operation device, and the replay.

Then, it is determined whether or not the game is in the re-game operation (S105), and if it is not in the re-game operation (S105: NO), the blocker 47 (see FIG. 7) described above can be passed through the game medal. If the process shifts to the blocker ON process (see FIG. 23 (a)) described later and the re-game is activated (S105: YES), the automatic input standby time 1 (237 interrupts: about 529.65 ms) is set (. S106). Further, it is determined whether or not the display type data is 0 (S107), and if the display type data is 0 (S107: YES), the process proceeds to the process of waiting for 2 bytes (S111). The 2-byte time wait process (S111) is a process of waiting until the designated waiting time (automatic input standby time 1) becomes 0. Here, the display type data is data indicating the type of the re-game combination that has been stopped and displayed. Specifically, when a predetermined replay combination in which "replay-replay-replay" is stopped and displayed on the valid line or the invalid line is stopped and displayed, the display type data is 0. On the other hand, a specific replay role in which "Replay-Replay-Replay" is not stopped and displayed on the valid line or the invalid line (example: "Bell-Bell-Bell", "Red 7-Red 7-Red 7") When is stopped and displayed, the display type data 1 is displayed. This display type data is stored in the RWM 83 at the time of winning determination, and an object is to change the time until the automatic input processing is started based on the symbol combination that is stopped and displayed. For example, for example, when the symbol combination corresponding to the display type data 1 is stopped, the automatic input waiting time 2 (described later) is set, and the effect corresponding to the small winning combination or the bonus winning combination is set when waiting for the set 2 byte time. By outputting a sound, the player can recognize the established combination as a small combination or a bonus role.

Further, in the determination of the display type data (S107), if the display type data is not 0 (S107: NO), the automatic input standby time 2 (500 interrupts: about 1119.50 ms) is set (S108). The process proceeds to the above-mentioned 2-byte time wait process (S111).

After the process of waiting for 2 bytes (S111), the process of reading the number of stored sheets is executed (S112). This storage number reading process (S112) reads the stored number data and checks the presence or absence of storage and the number of stored sheets. After that, it is determined whether or not the number of stored sheets has reached the storage limit number (50 sheets in this case) (S113), and if the number of stored sheets has not reached the storage limit number (S113: NO), the blocker is turned on. The process (S114) is executed. The blocker ON process (S114) will be described later. On the other hand, if the number of stored sheets reaches the storage limit number (S113: YES), the process proceeds to the process of acquiring the display type data (S116) without performing the blocker ON process (S114).

With such a configuration, when the re-game is not operating (S105: NO), the blocker ON process can be executed regardless of the number of stored sheets, and when the re-game is operating (S105: YES). The blocker can be turned on according to the number of stored sheets. Therefore, (1) even if the symbol combination displayed as stopped is a symbol combination that does not seem to be a replay, a uniform medal can be inserted, (2) a blocker ON process can be realized with a small amount of program processing, and (3) a medal. It is possible to reduce the swallowing (capture) of medals compared to the case where the blocker is turned on after detecting the above. (4) Even if the game has a high probability of replay, the player can insert medals at a constant rhythm. It has the effect of being able to do things.

After the determination process (S113) relating to the number of stored sheets or the blocker ON process (S114), the display type data is acquired (S116), and it is determined whether or not the display type data is 1 (S117). .. When the display type data is 1, (S117: YES), the three-sheet input display LED-R (red) is turned on (S118), and the automatic input standby time 3 (8949 interrupt: about 19999.49 ms) is set. (S119), and save the input detection standby time (S120). Further, the inputs of the selector passage sensor signal, the one-sheet input switch signal, the three-sheet input sensor signal, and the clearing switch signal are checked (S121), and it is determined whether or not these inputs are present (S122). Here, the lighting (S118) of the three-sheet insertion display LED-R (red) functions as a notification for urging the player to operate the BET button. Then, if any one of the inputs is input (S122: YES), the input detection standby time is cleared (S123), and the input information command is set (S124). Here, the input information command refers to a command indicating the state of "selector passage sensor signal, 1-sheet input switch signal, 3-sheet input sensor signal, 3-sheet input switch signal". In the above-mentioned S122, when there is no input (S122: NO), the input information command is set without clearing the input detection standby time (S123) (S124). In other words, the automatic closing standby time 3 is released based on the passage of time or the above input information (selector passage sensor signal, 1-sheet input switch signal, 3-sheet input sensor signal, or 3-sheet input switch signal). By adopting such a control mode, when a replay combination belonging to the display type data 1 is displayed, it is possible to pretend to be a small combination or a bonus combination.

Subsequently, it is determined whether or not the input detection standby time has elapsed (S125), and if not (S125: NO), the process returns to S121 to check the input of various signals. When the input detection standby time has elapsed in S125 (S125: YES), the three-sheet insertion display LED is turned off (S126), and the input information output request is set (S127). In the above-mentioned S117, when the display type data is not 1 (S117: NO), the output request of the input information is set without performing the processes of S118 to S126 (S127). Then, the process of the control command set 1 is executed (S128), but the process of the control command set 1 (S128) in this embodiment is the process of the control command set 2. The process of the control command set 2 is to save the above-mentioned sub-control command in a ring buffer (transmission buffer) that is temporarily stored before transmission. In the subsequent steps, there is also a process step of "setting an output request", but this is a process of storing information (command) to be transmitted to the sub control means (here, the sub control board 31) in a register. Point to.

After that, the re-game display LED is turned on (S129), the output request at the time of automatic closing is set (S130), and the process of the control command set 1 (S131) which is the same as the above-mentioned S128 is executed. Then, the process of adding one game medal (S132) is executed, and in the process of adding one game medal (S132), one of the number of game medals is added and the display process of the inserted number display LED is performed. More specifically, in the process of adding one game medal (S132), although not shown, the number of game medals data is added by one and the acquired number display data is cleared. Further, the input number display LED signal data corresponding to the game medal number data is saved, the game medal limit set is processed, and the game medal reading process is performed. Then, when the game medal number data matches the game medal limit number (the above-mentioned specified number), the game medal limit flag is set.

After the process of adding one game medal (S132), the above-mentioned game medal limit flag is confirmed (S133), and if the number of game medals does not reach the game medal limit (S133: NO), one game medal is added. Return to the process (S132). Then, in S133, if the number of game medals reaches the game medal limit (S133: YES), the process returns and returns to the process executed before the start of the process of starting the game medal acceptance, which is a subroutine.
<Blocker ON>

Next, the process of turning on the blocker will be described with reference to FIG. 23 (a). As shown in FIG. 23A, this blocker ON process determines whether or not the blocker OFF monitoring time (about 100.57 ms in this embodiment) has elapsed (S211), and if not. (S211: NO), S211 is repeated until it elapses. If the monitoring time when the blocker is OFF has elapsed (S211: YES), the interrupt is disabled (S212), the blocker signal is turned ON (S213), and the closing monitoring counter is cleared (S214). Further, the blocker signal state is turned ON (S215), interrupts are permitted (S216), and the process returns to the process before the start of the blocker ON process. Here, the “blocker signal_ON” in S213 refers to a process of storing “1” in the RWM area for turning on the blocker 47 in the present embodiment. In the figure, the description of "_" is omitted (the same applies hereinafter). By the process of S213, the blocker 47 is turned on by the port output process (S547) in the timer interrupt process (see FIG. 18) executed after the process. The process of S213 can be a process of storing "1" in the output port for directly outputting the blocker signal.

Further, the “input monitoring counter_clear” in S214 refers to a process of setting the data in the RWM83 of the input monitoring counter, which is updated when the selector passage sensor 46 is input, to 0 in the present embodiment. By this process, for example, after the binary data determined to have passed the selector passage sensor 46 is "10B", an error is determined when the game medal insertion check (see FIGS. 42 and 43) described later is executed. It can be prevented from being done. Further, the “blocker signal state_ON” of S215 means that in the present embodiment, information indicating that medals can be inserted is stored in the RWM83. By the process of S215, the lamp (game start display LED) indicating that the game medal can be inserted can be turned on by the LED display process (S75) of the interrupt process executed after the process. The processing order of S213 to S215 is not limited to this.

The above-mentioned process of turning on the blocker signal (S213) is performed after the monitoring time when the blocker is turned off has elapsed (S211: YES). This is done in order to prevent the medals from being pinched by not turning on the blocker 47 when there is a possibility that the game medal is passing. That is, as in this embodiment, the ON operation of the blocker 47 is reserved for a predetermined period by turning on the blocker signal (S213) after determining whether or not the monitoring time when the blocker is OFF has elapsed (S211). It is possible to secure a time for waiting for the passage of the game medal between the output of the blocker signal from the main control board 61 and the mechanical operation of the blocker 47.

Further, the above-mentioned interrupt prohibition (S212) is executed after waiting for the elapse of the monitoring time when the blocker is OFF (S211). In this embodiment, as described above for the C1 error related to the input sensor and the selector passage sensor (see FIG. 9A), the value of the input monitoring counter increases / decreases based on the detection of the selector passage sensor signal and the input sensor 2 signal. Then, when the value of the input monitoring counter exceeds a predetermined range (for example, a range of 0 to 3), the blocker 47 is turned off. Then, in the blocker ON process (see FIG. 23 (a)), the process related to the blocker signal (S213, S215) and the process related to the input monitoring counter (S214) are executed as a series of processes, and the blocker 47 operates. And the detection result of the selector passage sensor signal and the input sensor 2 signal are matched.

If a timer interrupt process (see FIG. 18) occurs between the blocker signal ON process (S213) and the blocker signal state ON process (S215), the timer interrupt process (the interrupt) at this time occurs. ) In the predetermined process (here, input data is created in S5).
As described above, the blocker 47 can be turned on (passable state) via 45, S547 that outputs the port, and the like). However, in the game progress main process (see FIG. 14), since the blocker signal state ON process (S215) following the blocker signal ON process (S213) is not performed, a predetermined process of the interrupt (here, here). In S549), which is an LED display process, the lamp (game start display LED) indicating that a game medal can be inserted cannot be turned on. That is, a situation may occur in which the game start display LED is not displayed even though the blocker 47 is ON.

However, as in this embodiment, interrupts are disabled (S212), and the processing related to the blocker signal (S213, S215) and the processing related to the input monitoring counter (S214) are performed by the timer interrupt processing (see FIG. 18). By executing the process as a series of processes without intervention, the operation of the blocker 47 can be matched with the LED display, and appropriate control related to the insertion of the game medal becomes possible.
<< Blocker OFF >>

Next, the blocker OFF process will be described with reference to FIG. 23 (b). As shown in FIG. 23B, this blocker OFF process determines whether or not the blocker signal is OFF (S221), and if the blocker signal is not OFF (S221: NO), interrupts are prohibited. (S222), the blocker signal is turned off (S223), and the blocker signal state is turned off (S224). Further, for the C0 error, the input sensor abnormality input detection start time (about 500.60 ms in this embodiment) described above is set (S225), interrupts are permitted (S226), and the process before the start of the blocker OFF process is performed. Return. Here, the “blocker signal_OFF” in S223 refers to a process of storing “0” in the RWM area for turning on the blocker 47 in the present embodiment. By this process, the blocker 47 is turned off by the port output process (S547) in the timer interrupt process (see FIG. 18) executed after the process. The process of S223 can be a process of storing "1" in the output port for directly outputting the blocker signal.

Further, the “blocker signal state_OFF” of S224 means that in the present embodiment, information indicating that a medal cannot be inserted is stored in the RWM83. By this process, the lamp (game start display LED) indicating that the game medal can be inserted is kept off. Further, in the input sensor abnormality input detection start time set of S225, a predetermined time related to the C0 error (about 500.60 ms in this embodiment) is set.

Further, also in the blocker OFF process (see FIG. 23B), the setting of the input sensor abnormality input detection start time (S225) is set by disabling interrupts (S222), the blocker signal OFF (S223), and the blocker signal. It is performed following each process of the state OFF (S224). That is, in the blocker OFF process, the process related to the blocker signal (S223, S224) and the process related to the input error check, the input sensor abnormality input detection start time set (S225), are executed as a series of processes.

If a timer interrupt (see FIG. 18) occurs between the blocker signal OFF (S223) and the blocker signal state OFF (S224), a predetermined timer interrupt process (corresponding interrupt) at this time occurs. As described above, the blocker 47 may be in the OFF state (return state) through processing (here, S79 for creating input data, S82 for port output, and the like). However, in the game progress main process (see FIG. 14), since the blocker signal state OFF process (S224) following the blocker signal OFF process (S223) is not performed, a predetermined process of the interrupt (here, here). In S75), which is an LED display process, the lamp (game start display LED) indicating that a game medal can be inserted cannot be surely turned off. That is, a situation may occur in which the game start display LED is lit even though the blocker 47 is turned off.

However, as in this embodiment, interrupt is disabled (S222), and the blocker signal OFF (S223) and the blocker signal state OFF (S224) are set as a series of processes without intervening timer interrupt processing (see FIG. 18). By executing this, the operation of the blocker 47 can be matched with the LED display, and appropriate control related to the insertion of the game medal becomes possible.
<< Error display >>

Next, the error display process will be described with reference to FIG. 24. As shown in FIG. 24, this error display process saves the error number (S231) and saves the state information related to the pre-error blocker signal and the hopper motor drive signal (S232). When saving the state information, the data is saved from the state information storage area (blocker signal data storage area, hopper motor drive signal data storage area) in the RWM83 to a predetermined storage area (C register serving as the state information save area). Will be executed. Further, the information in the hopper motor drive signal data storage area in the state information storage area is cleared (S233), and the blocker OFF process (S234) is executed. The blocker OFF process (S234) is the above-mentioned blocker OFF process (see FIG. 23B). Then, the start lever acceptance permission flag is cleared (S235), the information of the acquired number display is saved (S236), and the error display is set (S237). When saving the acquired number display information, data saving is executed from the acquired number display information storage area in the RWM 83 to a predetermined storage area (B register serving as the acquired number display information save area).

Further, the output request at the start of the error display is set (S238), the processing of the control command set 1 is executed (S239), and the rise of the setting / reset button signal (setting button signal or reset button signal) is detected. It is determined whether or not it is (S240). In the above-mentioned S240, if the rising edge of the setting / reset button signal is not detected (S240: NO), S240 is repeated until it is detected, and if the rising edge of the setting / reset button signal is detected, the rising edge of the setting / reset button signal is detected. (S240: YES), the setting / reset button signal rising data is cleared (S241).

Subsequently, the fullness detection signal inspection data is set (S242), and it is determined whether or not it is the above-mentioned FE error related to the payout of the game medal (S243). In this S243, when it is determined that the FE error has not occurred (S243: NO), the payout inspection data is set (S244), and it is determined whether or not the payout-related error has occurred (S245). Then, when it is determined that it is not a payout-related error (S245: NO), the inspection data of the input sensor and the selector passage sensor are set (S246), and the input state for each error based on the inspection data is checked (S247). .. Specifically, it corresponds to a process of confirming the level data of the input sensor 45 (input sensors 1 and 2), the level data of the selector passage sensor 46, and the level data of the payout sensor (not shown). When it is determined in S243 that it is an FE error (S243: YES) and in S245 it is determined that it is a payout-related error (S245: YES), the above-mentioned processing is not performed. To S247 of.

After the above-mentioned S247, it is determined whether or not the error factor has been removed (S248), and if the error factor has not been removed (S248: NO), the process returns to the above-mentioned S240 and the setting / reset button signal rises. Is detected or not. “Removal of error factors” in the present embodiment means that the level data of the various sensors described above is “0”. When the error factor is removed (S248: YES), the error number is cleared (S249), the acquired number display is restored (S250), and the output request at the end of the error display is set (S250). Further, the process of the control command set 1 is executed (S252), the state information of the blocker signal and the hopper motor drive signal before the error is restored (S253), and the hopper motor drive signal is restored (S254). Then, it is determined whether or not the blocker signal before the error was ON (S255), and if it is ON (S255: YES), the blocker ON process (S256) is executed, and the error display process is started. Return to the previous process. On the other hand, if the blocker signal before the error is not ON (S255: NO), the process returns without executing the blocker ON process (S256).
<< Input error set >>

Next, the processing of the input error set will be described with reference to FIG. As shown in FIG. 25, the processing of this input error set updates the abnormal input flag (also referred to as “abnormality occurrence flag”, “error flag”, etc.) (S301). In this S301, although not shown, the data stored in the A register is saved in the D register. Further, the logical operation (OR) of the data stored in the A register and the data stored in the E register is executed, and the operation result is stored in the A register. Then, the value of the A register is stored (updated) in the abnormal input data storage area provided at the predetermined address of the RWM83.

That is, S301 executes a process of storing the data of the abnormal input flag stored in the abnormal input data storage area of the RWM 83 in the A register. Here, the abnormality input flag in the present embodiment is composed of 1-byte data, D0 to D3 bits are unused, D4 bit is the selector passage sensor retention, D5 bit is the input sensor 2 abnormality input, and D6 bit is the payout sensor abnormality input. It represents, and the D7 bit is unused. For example, when only the selector passage sensor retention is detected, the abnormality input flag is "00010000B". Further, when an abnormality of the payout sensor is detected after detecting the retention of the selector passage sensor, the abnormality input flag is set to "01010000B".

Further, in the above-mentioned S301, using the above-mentioned abnormal input flag data, a command for creating and transmitting data as to whether or not to transmit (data for determining whether or not to make an output request) is used. (Control command) is created. That is, the value of the D register is stored in the A register when creating data as to whether or not to transmit. Then, the logical operation (AND) of the A register and the E register is executed, and the operation result is stored in the A register. For example, when the value of the A register is "01000000B" and the value of the E register is "00010000B", the value of the A register after the logical operation (AND) is "0000000000" (Example 1). Further, for example, when the value of the A register is "01010000B" and the value of the E register is "00010000B", the value of the A register after the logical operation (AND) is "00010000B" (Example 2). ..

On the other hand, in creating a command for transmission, a logical operation (XOR) of the A register and the E register is executed, and the operation result is stored in the A register. For example, if the value of the A register is "0000000000B" as in Example 1 above and the value of the E register is "01000000B", the value of the A register after the logical operation (XOR) is "01000000B". .. Further, for example, when the value of the A register is "00010000B" and the value of the E register is "00010000B" as in Example 2 described above, the value of the A register after the logical operation (XOR) is "0000000000B". ".

Subsequently, it is determined whether or not an abnormal input error is detected (S302). The determination performed in S302 is to check whether or not the abnormal input flag updated in S301 is new (whether or not it is duplicated). Such an inspection is performed by determining whether or not the data stored in the target storage area (abnormal input flag storage area) of the RWM 83 is the same before and after the update. More specifically, when the value of the A register is "0", that is, the above-mentioned Z (zero flag) is "= 1", it is determined as NO, and the value of the A register is other than "0", that is, the above-mentioned Z (zero flag). ) Is "≠ 1", it is determined as YES.

Then, if a new abnormal input error is detected (S302: YES), the output request at the start of error display is set (S303). In this S303, a predetermined value (= 01H) is stored in the D register. Then, the process proceeds to the control command set 1, but the control command set 1, which is the transfer destination of the input error check, performs the process of the control command set 2 as described above. Here, the processing of the control command set 2 is for storing the above-mentioned sub-control command in the transmission buffer. This control command set 1 (control command set 2) makes it possible to transmit information such as an error type to the sub control board 31. Further, in the above-mentioned S302, if the abnormal input error has already been detected (S302: NO), the process returns and returns to the original process.
<Relationship between blocker operation control and other processing>
<< Relationship with replay >>

Next, the relationship between the process for operating the blocker 47 described above and other processes will be described. First, here, the relationship between the above-mentioned blocker ON processing (see FIG. 23A) and the replay will be described. First, as described above, the blocker 47 (see FIG. 7) is in a state where the game medal can pass when it is ON, and is in a state where the game medal is returned when it is OFF. The control for turning on the blocker 47 is the game. In the progress main process (see FIG. 14), the blocker ON process shown in FIG. 23 (a) is used.

Further, the drive signal is input to the blocker 47 through the process of turning on the blocker described above, and the port output process (S547) in the timer interrupt process (see FIG. 18) described above is performed until the blocker 47 performs a mechanical operation. ) And the process of transmitting the control command (S548) are required. Then, the timer interrupt process is generated every predetermined cycle (here, 2.235 ms). Therefore, even if the blocker signal ON data is set in the blocker ON process (see FIG. 23A) (S213), a timer interrupt occurs after that, and the blocker 47 can actually pass the game medal. By the time, there will be a delay in control and mechanical operation. Then, after the blocker signal ON data is set, until the blocker 47 actually closes the second outlet 108 (see FIG. 7), the blocker is in the blocker ON state in the game progress main process, but the blocker 47 is in the OFF state. It can be said that this is the situation.

Further, as described above, the selector passage sensor 46 (see FIG. 7) can detect the passage of the game medal, and is arranged in front of the insertion sensor 45 and the blocker 47 (upstream side of the medal passage 105). ing. Then, the determination as to whether or not the game medal has passed using the selector passage sensor 46 can be performed before the game medal reaches the insertion sensor 45 or the blocker 47. Further, the first movable portion 112 and the second movable portion 114 of the selector passage sensor 46 also have a function of preventing the backflow of the game medal by projecting into the medal passage 105.

Then, when the start lever 25 is operated as described above, the blocker 47 is turned off and the medal is returned. At this time, the blocker OFF process shown in FIG. 23B is executed, and a predetermined value in the RWM 83 is executed. Data for turning off the blocker signal is stored in the area (blocker signal data storage area). Here, whether or not the start lever 25 is operated is determined in S59 of the game progress main process (see FIG. 14), but in FIG. 14 and the description of the main operation of the game progress main process, the blocker 47 is controlled. The (not shown) and description of such processing are omitted.

In this embodiment, as shown during the process of starting the acceptance of game medals in FIG. 22, it is determined in S105 whether or not the re-game is in operation. Further, if the re-game is activated (S105: YE)
S), the process of reading the number of stored sheets (S112), the determination of whether or not the number of stored sheets has reached the storage limit number (S113), and the like are performed. Then, if the number of stored sheets reaches a specific value (50 in this case) which is the storage limit number, the blocker ON process (S114) is executed.

In the blocker ON process (S114), as shown in FIG. 23 (a), it is determined whether or not the blocker OFF monitoring time has elapsed (S211). The blocker OFF monitoring time is described above. As described above, in this embodiment, it is set to about 100.57 ms, and the time is measured based on the timer data stored in the monitor time storage area when the blocker of the RWM 83 is turned off. The monitoring time when the blocker is turned off substantially coincides with the time required to execute the above-mentioned timer interrupt cycle (here, 2.235 ms) a predetermined number of times (here, 50 times).

Then, if the monitoring time when the blocker is OFF has elapsed (S211: YES), the interrupt is prohibited (S212), and the data for turning on the blocker signal is stored in the blocker signal data storage area of the RWM83 (S21). S213). Further, after clearing the input monitoring counter (S214) and setting the blocker signal ON flag (S215), the interrupt is permitted (S216), and the process returns to the process before the start of the blocker ON process. Then, in the timer interrupt (see FIG. 18) generated at the timing after the interrupt enable (S216), the blocker 47 is mechanically driven through processing such as port output (S82), and it is possible to accept the insertion of game medals. It becomes.

On the other hand, if it is not during the re-game operation (S105: NO in FIG. 22), the blocker ON process shown in FIG. 23 (a) is executed without going through the determination (S113) related to the number of stored sheets, and the blocker is executed. A series of processes from monitoring the OFF monitoring time (S211) to enabling interrupts (S216) are executed. In this way, by performing processing such as S113 at the time of re-game, it is possible to accept the insertion of game medals even at the time of re-game, depending on the number of stored sheets.

Further, in this embodiment, in the timer interrupt processing (see FIG. 18), the input detection processing related to the selector passage sensor 46 and the operation information output processing for operating the blocker 47 based on the blocker ON signal data and the blocker OFF signal data. Is being done. That is, the input detection process based on the selector passage sensor signal is performed by the input port data generation process (S545) of the timer interrupt process and the error check process of the second control (see FIG. 38) described later, and the blocker 47. The drive data output process for operating the timer interrupt process is performed in the control command transmission process (S548) of the timer interrupt process or the like. Then, these input detection processes and operation information output processes are executed at timings according to the control status at that time in the timer interrupt process based on the data set in the game progress main process.

In the blocker OFF process (see FIG. 23B) for turning the blocker 47 into the OFF state (return state), the closing sensor abnormality input detection start time is set (S225) as described above. The input sensor abnormality input detection start time is set to about 500.60 ms in this embodiment. The input sensor abnormality input detection start time substantially coincides with the time (time required for 224 interrupts) required to execute the timer interrupt cycle (2.235 ms here) a predetermined number of times (224 times here). There is. Then, the abnormal input related to the closing sensor is detected after waiting for the elapse of the closing sensor abnormality input detection start time.

According to the control mode related to the re-game as described above, when there is a possibility that the game medal is passing, it is possible to prevent the medal from being pinched by not turning on the blocker 47. That is, in the medal passage 105, in the portion near the selector passage sensor 46 and the blocker 47, the presence of the bent portion 110 (see FIG. 7), the eccentricity between adjacent game medals, and the blocker 47 are turned on. There is a possibility that the game medals may be engaged with each other due to the influence of the timing or the like, and the game medals may be pinched.

In particular, for example, when a player continuously inserts game medals into the game medal insertion slot 21 (see FIG. 1) from the end of one game to the start of the next game, the medal passage 105 It is difficult to secure a gap between the game medals, and when the blocker 47 is turned on, the game medals are engaged depending on the positional relationship of multiple game medals and the balance of factors such as the force applied to the game medals from the blocker 47. It is possible that medals will occur.

However, as in this embodiment, the ON operation of the blocker 47 is reserved for a predetermined period by turning on the blocker signal (S213) after determining whether or not the monitoring time when the blocker is OFF has elapsed (S211). It is possible to secure a time for waiting for the passage of the game medal between the output of the blocker signal from the main control board 61 and the mechanical operation of the blocker 47. Then, it is possible to prevent the game medal from being pinched.

Further, when the blocker 47 is turned off (returned state) as in the case of operating the start lever 25, wait for the elapse of the closing sensor abnormality input detection start time (500.60 ms) as described above. An abnormal input related to the closing sensor is detected. Therefore, the blocker 47 turns off almost at the same time that the game medal is normally detected by the insertion sensor 45 or the like, and the normally counted game medal is returned from the game medal payout port 16. It can be prevented from occurring.

Further, when the blocker 47 is turned off (returned state), as described above, the blocker signal OFF data is set in the RWM83 and an output request is made to perform timer interrupt processing (return state) that occurs after that time. (See FIG. 18), the blocker 47 performs a mechanical operation to be returned. However, when the abnormality input inspection by the closing sensor 2 is started immediately after the blocker signal OFF data is set, it reaches immediately before the closing sensor 2 while the blocker 47 is still in the ON state (passable state). There may be a case where the input sensor 2 subsequently detects the game medal that has been played. Then, although the passing of such a game medal is normal, the determination of the occurrence of an abnormality related to the insertion sensor 2 is made.

In response to such a situation, as in the present embodiment, the abnormality input related to the input sensor 45 is determined after the input sensor abnormality input detection start time of about 500 ms becomes effective from the timing of the blocker OFF data set. As a result, it is possible to prevent the normal passage of the game medal from being determined to be abnormal, and it is possible to more accurately determine the occurrence of an error.
<< Interrupt prohibition processing in blocker ON / OFF processing >>

As described above, in the blocker ON process (see FIG. 23A), interrupts are disabled after waiting for the elapse of the blocker OFF monitoring time (S211) (S212). In this embodiment, as described above for the C1 error related to the input sensor and the selector passage sensor (see FIG. 9A), the value of the input monitoring counter increases / decreases based on the detection of the selector passage sensor signal and the input sensor 2 signal. Then, when the value of the input monitoring counter exceeds a predetermined range (for example, a range of 0 to 3), the blocker 47 is turned off. Then, in the blocker ON process (see FIG. 23 (a)), the process related to the blocker signal (S213, S215) and the process related to the input monitoring counter (S214) are executed as a series of processes. The operation of the blocker 47 is matched with the detection result of the selector passage sensor signal and the input sensor 2 signal.

Further, also in the blocker OFF process (see FIG. 23B), the setting of the input sensor abnormality input detection start time (S225) is set by disabling interrupts (S222), the blocker signal OFF (S223), and the blocker signal. It is performed following each process of the state OFF (S224). That is, in the blocker OFF process, the process related to the blocker signal (S223, S224) and the process related to the input error check, the input sensor abnormality input detection start time set (S225), are executed as a series of processes. As a result, the operation of the blocker 47, which is in the returned state, and the error check are ensured to be integrated.

Further, in the present embodiment, in the timer interrupt processing (see FIG. 18), the input detection processing related to the selector passage sensor 46, the addition processing of the count value of the input monitoring counter, and the blocker ON signal data and the blocker OFF signal data are used. Based on this, operation information output processing for operating the blocker 47 is performed. That is, the input detection process based on the selector passage sensor signal is performed by the input port data generation process (S545) of the timer interrupt process and the second control error check process (see FIG. 38) described later, and the input monitoring is performed. The process of adding the count value of the counter is performed in the error check process (see FIG. 38) of the error management (see FIG. 20) in the timer interrupt process, and further, the drive data output for operating the blocker 47 is performed. The processing is performed in the control command transmission processing (S548) of the timer interrupt processing. Then, these input detection processes, input monitoring counter update processes, and operation information output processes are performed at timings according to the control status at that time in the timer interrupt process based on the data set in the game progress main process. Will be executed.

Here, the relationship between the update processing of the count value of the input monitoring counter in the game progress main process and the update process of the count value of the input monitoring counter in the timer interrupt process is limited to the above-mentioned correspondence between addition and subtraction. is not. For example, the count value of the input monitoring counter may be added in the game progress main process, and the count value of the input monitoring counter may be subtracted in the timer interrupt process. In this case, for example, the initial value of the count value of the input monitoring counter is set to "3" or more, the initial value is subtracted by the timer interrupt process, and the count value of the input monitor counter is performed in the game progress main process. It is conceivable that a control mode such as performing addition to and executing a determination process of whether or not the count value is within the normal range is performed.
<< Relationship with setting key switch operation >>

Next, the relationship between the process for operating the blocker 47 and the operation of the setting key switch will be described. First, in the above-mentioned processing when waiting for the game medal to be inserted, when the setting key switch signal is ON, that is, the data of the setting key switch signal in the predetermined area (setting key switch signal data storage area) of the RWM 83 indicates ON. If this is the case, the blocker OFF process shown in FIG. 23B is executed. Then, data for turning off the blocker signal is stored in a predetermined area (blocker signal data storage area) in the RWM 83.

Subsequently, the setting display LED 66 (see FIG. 4) for displaying the set value is enabled. At this time, in the process of waiting for the insertion of the game medal (S55 in FIG. 14), each process of lighting the setting display LED is executed from the set of the output request at the start of setting value display. Further, when the data stored in the setting key switch signal data storage area of the RWM 83 indicates OFF, the blocker ON process is executed. The case where the data stored in the setting key switch signal data storage area is OFF means the case where the rising and falling data of the setting key switch signal is stored.

Then, as described above, when the monitoring time when the blocker is OFF has elapsed (S211: YES), a series of subsequent processes (S212 to S216) are performed, and in S213, data for turning on the blocker signal. To set. The input data and downlink data related to the setting key switch are generated in the input port data generation process (S545) of the timer interrupt (see FIG. 18). Therefore, even in this case, it is possible to prevent the medals from being pinched by not setting the ON data of the blocker signal while the game medal may be passing.

Further, in this embodiment, in the timer interrupt processing (see FIG. 18), based on the input detection processing related to the selector passage sensor 46, the input detection processing related to the start lever 25, and the blocker ON signal data and the blocker OFF signal data. Operation information output processing for operating the blocker 47 is performed. That is, the input detection process based on the selector passage sensor signal and the input detection process based on the start lever sensor signal are performed by the input port data generation process (S545) and the input error check process (S83) of the timer interrupt process. The drive data output process for operating the blocker 47 is performed in the control command transmission process (S548) of the timer interrupt process. Then, these input detection processes and operation information output processes are executed at timings according to the control status at that time in the timer interrupt process based on the data set in the game progress main process.

According to the control mode as described above, the cooperation between the setting key switch operation and the blocker operation can be accurately performed, and the blocker operation control at the time of setting key switch operation can be appropriately performed.
<< Relationship with error handling >>

Next, the relationship between the processing for operating the blocker 47 and the error processing will be described. The description described here is an example of processing when the above-mentioned CE error (see FIG. 10) occurs, and the CE error is a portion where the closing sensor 1 (115) or the closing sensor 2 (116) is provided (FIG. 10). This is an error when it is determined that the game medals have accumulated in (see 7).

First, in the game progress main process (see FIG. 14), when the input sensor 1 signal or the input sensor 2 (116) is continuously detected for a predetermined time or longer, it is determined that the game medal stays (CE error). Here, the predetermined time for determining the retention of the game medal is about 143.03 ms, which is the upper limit of the retention determination passage times A and C described above. Then, the process proceeds to the error display process shown in FIG. 24, the error number is saved (S231), and the state information related to the pre-error blocker signal and the hopper motor drive signal is saved (S232). Further, after the hopper motor drive signal is turned off (S233), the blocker OFF process (S234) is executed, and as shown in FIG. 23 (b), data for turning off the blocker signal is set in S223. ..

Subsequently, when the error factor is removed (S248: YES), the blocker signal before the error is transmitted through processing such as clearing the error number (S249) and returning various information (S250, S253, S254). It is determined whether or not it was ON (S255). Then, if the blocker signal before the error is ON (S255: YES), the blocker ON process (S256) is executed, and after waiting for the elapse of the monitoring time when the blocker is OFF (S211), the blocker signal is transmitted. Data for turning on is stored (S213). Therefore, even in this case, it is possible to prevent the medals from being pinched by not setting the ON data of the blocker signal while the game medal may be passing.

Further, in the present embodiment, in the timer interrupt processing (see FIG. 18), the input detection processing related to the selector passage sensor 46 and the operation information output processing for operating the blocker 47 based on the blocker ON signal data and the blocker OFF signal data. Is performed by timer interrupt processing (see FIG. 18). That is, the input detection process based on the selector passage sensor signal is performed by the input port data generation process (S545) of the timer interrupt process and the error check process of the second control (see FIG. 38) described later, and the blocker 47. The drive data output process for operating the timer interrupt process is performed in the control command transmission process (S548) of the timer interrupt process. Then, these input detection processes and operation information output processes are executed at timings according to the control status at that time in the timer interrupt process based on the data set in the game progress main process.

According to the control mode as described above, the error processing and the blocker operation can be accurately linked, and the blocker operation control at the time of error occurrence can be appropriately performed.
<< Game medal management process >>

Subsequently, the above-mentioned game medal management process (see S56 in FIG. 14) will be described with reference to FIG. 26. This game medal management process is a process of shifting to the case where there is a game medal (S54: YES) by checking the presence or absence of the game medal (S54) in the above-mentioned game progress main process (see FIG. 14).

In the game medal management process shown in FIG. 26, the game medal insertion and settlement processing are managed. More specifically, it is determined whether or not the data set for turning the blocker 47 into the ON state (the game medal passable state) is set (S321). Here, it is confirmed whether or not the blocker 47, which is the flow path switching portion of the game medal selector 44 that accepts or ejects the manually inserted game medals, is in the receiving state (medal flow path forming state).

Then, if the data set for turning on the blocker 47 is set (S321: YES), it is confirmed whether or not the insertion sensor signal is ON (S322), and it is determined whether or not the game medal is inserted. .. The determination of whether or not the insertion of the game medal is detected is to determine whether or not the actual game medal is detected by the above-mentioned insertion sensors 115 and 116, and determines whether or not there is a bet setting (bet). This is a process different from the above-mentioned S54 (see the game progress main process of FIG. 14).

Here, among the insertion sensor 1 (115) and the insertion sensor 2 (116), even if only the insertion sensor 2 (116) located on the downstream side of the medal passage 105 detects the game medal, the game medal It is determined that there was an input (S322: YES). Then, if the insertion of the game medal is detected (S322: YES), the processing of the second control game medal insertion check (FIG. 42, FIG. 42), in which the insertion process of determining whether or not the insertion of the game medal is appropriate is performed. (See FIG. 43) is executed. That is, when both the blocker signal and the insertion sensor signal are ON (S321: YES, S322: YES), the process proceeds to the game medal insertion check (FIGS. 42 and 43).

On the other hand, when it is determined in the blocker status confirmation process (S321) that the blocker ON data is not set (S321: NO), or when the insertion of the game medal is not detected (S322: NO), the game is played. It is determined whether or not the operation of the bet button or the clearing button in the main input unit 26 (see FIG. 1) can be accepted without performing the medal insertion check process (see FIGS. 42 and 43) (S323). The determination (S323) of whether or not this button operation is acceptable is to determine whether or not the various bet buttons or the clearing button are in the acceptable state. Then, it is determined that the reception is not possible when the start lever 25 is operated or when any of the stop buttons (24L to 24R), which is another button, is operated.

If the above-mentioned various bet buttons or clearing buttons are not acceptable (S323: NO), the game medal management is exited and the process returns to the original process. If the operation can be accepted (S323: YES), the determination as to whether or not the operation has been accepted (S324) is executed. The determination (S324) of whether or not this button operation has been accepted is a process in which the input is performed in response to the button operation. Specifically, it is determined whether or not the number of bets has already reached the upper limit, and whether or not the operated input button is the above-mentioned 1BET button. And if it is 1 BET button, 1
If it is not the 1BET button, it is determined that the above-mentioned MAXBET is set, and the specified number of the next game is set to the planned number of bets. Then, it is determined whether or not the planned number of bets is larger than the stored number (number of stored medals) indicating the stored number, and if the stored number is smaller, the planned number of bets is set as the stored number. .. Further, a control command indicating that the insertion button is pressed is set, and the number of bets is set and the number of stored cards is subtracted by one, which is repeated as many times as the planned number of bets.

In the process of determining whether or not the button operation is accepted (S324), if the operation is not accepted (S324: NO), the game medal management is exited and the process returns to the original process. On the other hand, if the operation is accepted (S324: YES), the determination as to whether or not the clearing button is ON is executed (S325), and if the clearing button is not ON (S325: NO), the storage input process described later (FIG. 27). If the clearing button is ON (S325: YES), the game medal clearing process (S326) that clears according to the button operation is executed, and the process returns to the original process.

More specifically, when the clearing button signal (clearing switch signal) is turned from OFF to ON, the above-mentioned signal to the game start display LED (game start display LED signal) is turned off to clear the game medal. Shift to (S326). Further, when the above-mentioned 1-sheet insertion switch signal or 3-sheet insertion sensor signal is changed from OFF to ON, the game start display LED signal is turned OFF and the storage / input is started. If at least one of S321 and S322 gives a negative judgment (NO), and S323 or S324 also gives a negative judgment (NO), the game medal management process ends.

FIG. 28 more specifically shows the contents of the above-mentioned game medal clearing process (S326). In this game medal clearing process, the operation flag is checked (S371), it is determined whether or not the re-game is in operation (S372), and if it is in operation (S372: YES), the bet number is set. Check the presence or absence of medals (S373), if there is a game medal for which the number of bets is set (S373: YES), set the blocker OFF data (S374), and set the medal passage 105 of the game medal selector 44 (see FIG. 6). ) Is disabled. Then, a clearing start command is set as a control command (S375).

Further, the number of game medals for which the number of bets is set is read (S376), and the settlement process is performed one by one up to the number of medals for which the number of bets is set. Here, every time one game medal is paid out, the number of bets (number of bets) is subtracted by 1 (S377), the number of game medals for which the number of bets is set is read (S378), and the settlement of the number of bets is completed. It is determined whether or not this has been done (S379). Then, if the settlement for the number of bets is completed (S379: YES), the game medal limit flag is cleared (S380). This game medal limit flag is a flag used to prohibit acceptance of the insertion button.

Subsequently, as a control command, a clearing end command is set (S381), blocker ON data is set (S382), and the medal passage 105 (see FIG. 6) of the game medal selector 44 is returned to the insertable state. Then, the game medal clearing process is completed, and the process returns to the original process. In the determination of whether or not the clearing of the number of bets has been completed (S379), if the settlement of the number of bets has not been completed (S379: NO), the process returns to the reading of the number of bets (S376) and the bet amount The processing of S376 to S379 is repeated until the settlement is completed.

On the other hand, in the above-mentioned determination of whether or not the re-game is in operation (S372), when it is determined that the re-game is not in operation (S372: NO), or the presence or absence of a game medal for which the bet number is set is confirmed (S373). ), If there is no game medal for which the number of bets is set (S373: NO), the process of reading the number of stored medals (S383) is executed. Then, it is determined whether or not there is a stored number (S384), and if there is no stored number (S384: NO), the game medal clearing process is terminated and the process returns to the original process.

In the above-mentioned confirmation of the presence or absence of stored game medals (S384), if there are stored game medals (S384: YES), the blocker OFF data is set (S385), and the game medal selector 44 The medal passage 105 (see FIG. 6) is placed in a non-insertable state. Then, a clearing start command is set as a control command (S386). The blocker OFF data set (S385) and the clearing start command set (S386) can be processed in the same manner as in S374 and S375 described above.

Further, the number of stored game medals is read (S387), and the settlement process is performed one by one up to the number of stored game medals. Here, every time one game medal is paid out, the number of stored medals is subtracted by 1 (S388), the remaining number of stored medals is read (S389), and it is determined whether or not the settlement for the number of stored medals is completed. (S390). Then, if the clearing for the number of stored sheets is completed (S390: YES), the above-mentioned clearing end command is set (S381), the blocker ON data set (S382) is performed, and the game medal clearing process is completed. Return to the original process.

In the above-mentioned determination of whether or not the settlement for the number of stored items has been completed (S390), if the settlement for the number of stored items has not been completed (S390: NO), the process returns to reading the number of stored items (S387) and the stored amount. The processing of S387 to S390 is repeated until the settlement is completed.
<< Storage and input processing >>

Subsequently, the above-mentioned storage input processing will be described with reference to FIG. 27. This storage input process is a process of shifting to the case where the clearing button is not ON (S325: NO) by determining whether or not the clearing button is ON (S325) in the above-mentioned game medal management process (see FIG. 26). Is.

In the storage / loading process shown in FIG. 27, it is determined whether or not the game medal limit flag is set (S331), and if the game medal limit flag is set (S331: YES), the storage / loading process is performed. Is finished, and returns to the original processing in the game progress main processing. If the game medal limit flag is not set (S331: NO), the process of setting the required number of inserts (S332) is executed. In this input request number set (S332), when "1" is set as the input request number and the rise of the MAXBET switch signal is detected, the upper limit of the bet number and the currently set bet number are set. The difference is set as the number of input requests.

Subsequently, a process of reading the number of stored medals (S333) is performed, and it is determined whether or not there is a stored number of game medals (S334). Then, when there is a number of stored sheets (S334: YES), the storage input process is completed, and the process returns to the original process in the game progress main process. If there is no stored number (S334: NO), the rising data of the input switch signal is cleared (S335), and the relationship between the stored number of game medals and the requested number of input is determined (S336). Then, if the number of stored game medals is not equal to or greater than the required number of inserted medals (S336: NO), the value of the number of stored game medals is set in the requested number of inserted medals (S337), and the process proceeds to the process of adding one game medal (S338). .. In S336 described above, if the number of stored game medals is equal to or greater than the required number of inserted medals (S336: YES), the process of adding one game medal (S338) is performed without setting the value of the number of stored game medals (S337). Transition.

In the process of adding one game medal (S338), "1" is added to the number of bets. After that, the process of clearing the display of the number of acquired cards (S339) is executed, the process of displaying the number of bets (S340) is executed, and the specified number and the number of game medals are read (S341). Further, the process of determining the limit on the number of game medals (S342) is executed, and it is determined whether or not the number of bets has reached the upper limit. Then, if the number of bets has reached the upper limit (S342: YES), the game medal limit flag is set (S343), and the process proceeds to the process of reading the stored number of sheets (S345). If the number of bets has not reached the upper limit (S342: NO), the process proceeds to the process of reading the stored number of sheets (S345) without performing the game medal limit flag set process (S343).

After the process of reading the number of stored sheets (S345), the process of subtracting one stored sheet (S345) is executed, and it is determined whether or not a series of processes related to the requested number of sheets to be input has been executed for the requested number of sheets to be input (S346). ) Is executed. Then, if the processing for the requested number of input is completed (S346: YES), the storage input processing is completed, and the process returns to the original processing in the game progress main processing. If the processing for the required number of inserted medals is not completed (S346: NO), the processing after the processing for adding one game medal (S338) is executed again.
<Various processes related to the second control>

Next, various processes in the above-mentioned second control will be described.
<RWM initialization 2>

FIG. 30 shows the process of RWM initialization 2 used in the above-mentioned power recovery process (see FIG. 21) and the like. In the process of this RWM initialization 2, the second work area provided in the predetermined RWM area (F200H to F3FFH) and the maximum usage amount (F210H to F21EH, F3F3H to F3FFH) of the second stack area are not excluded. Clear the used area.

More specifically, the stack pointer is saved (S871), the area outside the used area of the stack pointer is set (S872), and the predetermined register is saved (S873). Further, the RWM initialization start address is set (S874), the number of RWM initialization bytes is set (S875), and the RWM is initialized (S876). Then, the next RWM address is set (S877), and it is determined whether or not the initialization of the RWM is completed (S878).

If the RWM initialization is completed in S878 (S878: YES), the RWM initialization start address is set (S879), and if it is not completed (S878: NO), the RWM of S876 is described. Return to the initialization process. After the above S879, the number of RWM initialization bytes is set (S880), and the RWM is initialized (S881).

Further, the next RWM address is set (S882), and it is determined whether or not the initialization of the RWM is completed (S883). If the RWM initialization is completed in S883 (S883: YES), the register is restored (S884), and if it is not completed (S883: NO), the RWM initialization process in S881 is performed. Return to. After the above S884, the stack pointer is returned (S885) to end the process.
<RWM initialization 3>

Next, the process of RWM initialization 3 used in the setting change device process (see FIG. 13) described above will be described. As shown in FIG. 31, in the process of RWM initialization 3, the stack pointer is saved (S891), the area outside the used area of the stack pointer is set (S892), and the predetermined register is saved (S892). S893). Further, the RWM initialization start address is set (S894), the number of RWM initialization bytes is set (S895), and the RWM is initialized (S896).

Subsequently, the next RWM address is set (S897), and it is determined whether or not the initialization of the RWM is completed (S898). If the RWM initialization is completed in S898 (S898: YES), the register is restored (S899), and if it is not completed (S898: NO), the RWM initialization process in S896 is performed. Return to. After the above S899, the stack pointer is returned (S900) to end the process.

As a control module related to RWM initialization, for example, RWM initialization 1 related to the first control is provided in addition to the above-mentioned RWM initialization 2 and RWM initialization 3. The RWM initialization 1 is shifted from the control module used in the game start set process (S52) of the power-on time process (see FIG. 12) related to the first control, but the RWM initialization 1 The description of the processing of is omitted.
<Serial communication settings>

Next, the processing of the serial communication setting used for serial communication will be described. In this serial communication setting, the transmission function of SCU1 used in the test firing test output is set. More specifically, as shown in FIG. 32, the stack pointer is saved (S911), the area outside the used area of the stack pointer is set (S912), and the predetermined register is saved (S913).

Further, the SCU1 baud rate register address (lower) is set (S914), and the SCU1 baud rate register is set (S915). Subsequently, the SCU channel 1 transmission function is used, the FIFO mode, the data length of 9 bits, the parity is used, and the even parity is set (S916), the register is restored (S917), and the stack pointer is restored (S918). , End the process.
<Sign stop signal output>

Next, the processing of the symbol stop signal output used in the processing of the condition device command set described above (see FIG. 16) and the like will be described. In the processing of this conditional device command set, the symbol stop signal data for the test firing test is output. More specifically, as shown in FIG. 33, the stack pointer is saved (S921), the area outside the used area of the stack pointer is set (S922), and the predetermined register is saved (S923).

Further, the SCU1 data register is set (S924), and the first command (designation of rotation information) is written (S925). Subsequently, the second command (designation of rotating cylinder information) is lighted (S926), and the symbol stop signal set is processed (S927). The processing of this symbol stop signal set (S927) will be described later.

In addition, the number of transmissions and the first command (push order designation) data are set (S928), and the first command is written (S929). Further, the second command data is acquired from the stop reception designation table (S930), and the second command is written (S931). Further, the next first command data is set (S932), and the next table address is set (S933).

Subsequently, it is determined whether or not the transmission is completed (S934), if the transmission is completed (S934: YES), the register is restored (S935), the stack pointer is restored (S936), and the process is completed. To do. If the transmission is not completed in S934 (S934: NO), the process returns to the first command write process in S929.
<Sign stop signal set>

Next, the processing of the symbol stop signal set (S927) used in the processing of the symbol stop signal output described above (see FIG. 33) will be described. In the processing of this condition device command set, the symbol stop signal data table for the test firing test is set according to the instruction number, the operating state flag, and the bonus condition device number.

More specifically, as shown in FIG. 34, the stop reception designation table 2 is set (S941), and the offset is set (S942). Further, it is determined whether or not the instruction number is 0 (S943), and if the instruction number is 0 (S943: YES), the stop reception designation table 1 is set (S944). Further, it is determined whether or not the bonus is activated (S945), and if the bonus is not activated (S945: NO), the stop reception designation table 2 is set (S946).

Subsequently, the offset is set (S947), and it is determined whether or not the bonus condition device is not operating (S948). If the bonus condition device is not inactive (S948: NO), an offset is generated (S949), a stop reception designation table is set according to the offset (S950), and the process ends.

In the above S943, when the instruction number is not 0 (S943: NO), the process of the stop reception designation table set according to the offset (S850) is performed without performing the intervening process. If the bonus is activated in S945 (S945: YES), or if the bonus condition device is not activated in S948 (S948: YES), the subsequent processing is not performed and the processing ends. To do.
<Test signal output>

Next, the test signal output process used in the error management process (see FIG. 20) described above will be described. In the processing of this test signal output, the test signal for the simulation test, the condition device information, and the replay state identification information are output. Then, the bonus operation information and the re-game operation information are output to the output port 10, and the output data is output to the port 9 according to the condition device output time and the re-game state identification information flag. Then, when the accessory condition differential device information is output, the accessory condition device information is output, when the winning and re-gaming condition device information is output, the winning and re-gaming condition device information is output, and when the re-gaming state identification information flag is ON, the re-gaming is performed. The state identification information is output, and in other cases, clear data is output.

More specifically, as shown in FIG. 35, the stack pointer is saved (S961), and the stack pointer (outside the used area) is set (S962). Subsequently, the register is saved (S963), and the test signal output data is generated (S964). Further, the test signal is output (S965), and the RT status number is acquired (S966).

Subsequently, it is determined whether or not the bonus is activated (S967), and if the bonus is activated (S967: YES), the replay is performed except when the predetermined bonus (here, type 1 BB-A) is activated. The state identification signal is set (S968). Further, it is determined whether or not the above-mentioned predetermined bonus (Type 1 BB-A) is in operation (S969), and if it is in operation (S969: YES), the above-mentioned predetermined bonus (Type 1 BB-) is activated. A) Set the re-game state identification signal related to the time (S970).

Subsequently, a re-game state identification signal is generated (S971), and it is determined whether or not the re-game state identification information flag is ON (S972). Here, the re-game state identification information is information generated by the RT state number and the operation type. If the bonus is not activated in S967 (S967: NO), the interim processing is not performed, and it is determined whether or not the replay state identification information flag in S972 is ON. Further, in the above S969, if the above-mentioned predetermined bonus (Type 1 BB-A) is not activated (S969: NO), the above-mentioned S970 is not performed, and the re-game state identification information flag of the above-mentioned S972 is set. It is determined whether or not it is ON.

In the above S972, when the re-game state identification information flag is not ON (S972: NO), the condition device information clear data is set (S973), and it is determined whether or not it is time to output the condition device information. (S974). If it is the time to output the condition device information (S974: YES), the data at the time of outputting the accessory condition device information is set (S975), and the bonus condition device number RWM address is set (S976).

Further, it is determined whether or not it is the time when the character condition device information is output (S977), and if it is not the time when the character condition device information is output (S977: NO), the winning and replay condition device information is obtained. The data set (S978), the winning and replay condition device number RWM address set (S979) are performed, and the condition device number is acquired (S980). If it is the time to output the accessory condition device information in S977 (S977: YES), the condition device number in S980 is acquired (S980) without performing the interim processing.

Subsequently, the condition device lower information (lower digit information) is set (S981), and it is determined whether or not the condition device lower information is being output (S982). Further, if the condition device lower information is not output (S982: NO), the condition device upper information (upper digit information) is set (S983), and the condition device information is generated (S984). Then, the condition device information is output (S985), the register is restored (S986), the stack pointer is restored (S987), and the process is terminated.

In the above S972, when the replay state identification information flag is ON (S972: YES), and in the above S974, when the condition device information is not output (S974: NO), interim processing is performed. Instead, the condition device information of S985 is output (S985). If the condition device lower information is output in S982 (S982: YES), the condition device information generation process of S984 is performed without performing 983 (S984).
<Insert / payout sensor error set>

Next, the above-mentioned processing of the insertion / withdrawal sensor abnormality set related to error detection of insertion / withdrawal of game medals will be described. In the processing of this input / payout sensor abnormality set, a display request for the corresponding error is made according to the error detection flag.

More specifically, as shown in FIG. 36, the stack pointer is saved (S991) and the stack pointer (outside the used area) is set (S992). Further, the register is saved (S993), and a CH error display request is set (S994). Further, it is determined whether or not a CH error is detected (S995), and if it is not detected (S995: NO), the error display request is cleared (S996).

Subsequently, the error display request data is saved (S997), the register is restored (S998), the stack pointer is restored (S999), and the process is terminated. If a CH error is detected in S995 (S995: YES), the error display request clearing process of S996 is not performed, and the error display request data of S997 is saved.
<Clear input / payout sensor abnormality>

Next, the process of clearing the insertion / withdrawal sensor abnormality related to the process at the time of displaying the error of the insertion / withdrawal of the game medal will be described. In the process of clearing the input / payout sensor abnormality, when an error display request is made, the detection flag of the corresponding error and the related data are cleared. More specifically, as shown in FIG. 37, the stack pointer is saved (S1011), and the stack pointer (outside the used area) is set (S1012).

Further, the register is saved (S1013) and the error detection flag is set (S1014). Further, it is determined whether or not there is a CH error display request (S1015), and if there is a display request (S1015: YES), the CH error detection flag is cleared (S1016). Then, the register is restored (S1017) and the stack pointer is restored (S1018) to end the process. If there is no display request in S1015 (S1015: NO), the register restoration process in S1017 is performed without performing S1016.
<Error check>

Next, the error check process used in the above-mentioned error management process (see FIG. 20) and the like will be described. In this error check process, various error check processes are performed. More specifically, as shown in FIG. 38, the stack pointer is saved (S1021), the area outside the used area of the stack pointer is set (S1022), and the predetermined register is saved (S1023).

Further, in the error check processing, the set value error check processing (S1024), the built-in random number check processing (S1025), the timer measurement 2 processing (S1026), the game medal insertion check processing (S1027), and the game medal passing The status update process (S1028), the input / payout sensor abnormality check process (S1029), and the error display request data clear process (S1030) are performed in order, and these processes will be described later. Then, after the error display request data clear processing (S1030), the register is restored (S1031), the stack pointer is restored (S1032), and the processing is completed.
<Setting value error check>

Next, the set value error check process (S1024) used in the above error check process (see FIG. 38) will be described. In this set value error check process, it is checked whether the setting stage is in the normal range, and if it is not in the normal range, the process proceeds to the unrecoverable error process 2.

More specifically, as shown in FIG. 39, an E6 error, which is one of the unrecoverable errors, is set (S1036), and it is determined whether or not the set value is less than the maximum value (6 in this case). (S1037). Further, in S1037, if the set value is less than the maximum value (S1037: YES), the process is completed, and if the set value is not less than the maximum value (S1037: NO), the process proceeds to the unrecoverable error process 2. This non-recoverable error processing 2 will be described later (see FIG. 49).
<Built-in random number check>

Next, the built-in random number check process (S1025) used in the above-mentioned error check process (see FIG. 38) will be described. In this built-in random number check process, if an abnormality related to the built-in random number update is detected, the process proceeds to the non-recoverable error process 2, and if not detected, an 8-bit random number is checked.

More specifically, as shown in FIG. 40, an E7 error, which is one of the unrecoverable errors, is set (S1041), and the built-in information register data is acquired (S1042). Further, it is determined whether or not the built-in random number update-related abnormality has occurred (S1043), and if it has not occurred (S1043: NO), the 8-bit random number maximum inspection table is set (S1044). Then, the RS0 soft latch random number value register address is set (S1045), the 8-bit random number inspection process is performed four times (S1046 to S1049), and the process is completed.

Further, in the process of determining whether or not the built-in random number update-related abnormality has occurred in S1043, if an abnormality has occurred (S1043: YES), the process proceeds to the non-recoverable error process 2. This non-recoverable error processing 2 will be described later (see FIG. 63). Here, the reason why the 8-bit random number inspection process is performed four times in S1046 to S1049 is that there are four corresponding registers and the four registers are checked in order.
<Timer measurement 2>

Next, the timer measurement 2 process (S1026) used in the above-mentioned error check process (see FIG. 38) will be described. In the process of this timer measurement 2, the timer RWM1 used in the error check is subtracted (0 is set if it is less than 0).

More specifically, as shown in FIG. 41, the measurement start timer address is set (S1051), and the number of 1-byte timers is set to 2 (S1052). Further, the 1-byte timer value is updated (S1053), and the next timer address is set (S1054). Further, it is determined whether or not the measurement of the 1-byte timer is completed (S1055), and if it is completed (S1055: YES), the process is completed. If the measurement of the 1-byte timer is not completed in S1055 (S1055: NO), the process returns to the process of updating the 1-byte timer value in S1053.
<Check for inserting game medals>

Next, the game medal insertion check (S1027) used in the above-mentioned error check process (see FIG. 38) will be described. In this game medal insertion check process, when the medal insertion inspection flag is ON or the blocker signal is ON, the insertion sensors 1 and 2 signals are inspected, and when a passing abnormality is detected, a display request for each error is made. Then, when the insertion sensor 1 passage check time or the insertion sensor 2 passage check time is exceeded, a CE error display request is made, and when the game medal is illegally passed, a CP error display request is made. Further, if the input monitoring counter is not within the normal range, a C1 error display request is made.

More specifically, as shown in FIG. 42, the blocker signal data is set last time (S1061), and the blocker signal data is generated (S1062). Further, the blocker signal data is generated this time (S1063), and the blocker signal data is generated (S1064). Further, it is determined whether or not the riser of the blocker signal is detected (S1065), and if it is detected (S1065: YES), the input monitoring counter is cleared (S1066).

Further, it is determined whether or not the medal insertion inspection flag is ON (S1067), and if it is not ON (S1067: NO), it is determined whether or not the blocker signal is ON (S1068). Further, when the blocker signal is ON (S1068: YES), the data of the previous game medal passing state is acquired (S1069). Then, it is determined whether or not the insertion sensor signal is ON (S1070), and if it is ON (S1070: YES), the medal insertion inspection flag is set (S1071).

If the rising edge of the blocker signal is not detected in S1065 (S1065: NO), S1066 is not performed and it is determined whether or not the medal insertion inspection flag is ON (S1067). Further, in S1067, when the medal insertion inspection flag is ON (S1067: YES), the interim processing is not performed, and it is determined in S1070 whether or not the insertion sensor signal is ON. If the blocker signal is not ON in S1068 (S1068: NO), the process ends.

After the above S1071, it is determined whether or not the input sensor 1 signal is ON (S1072), and if it is ON (S1072: YES), a CP error is set (S1073). Further, it is determined whether or not the situation was the previous game medal passing state 1 or 3 (S1).
074), if a negative determination is made (S1074: NO), it is determined whether or not the previous game medal passing state was 0 (S1075).

If an affirmative judgment is made in S1075 (S1075: YES), the input sensor 1 pass check time is set (S1076), and the CE error is set (1077). Then, it is determined whether or not the passing time of the closing sensor 1 has been exceeded (S1078), and if it has not exceeded (S1078: NO), the process ends. If a negative determination is made in S1075 (S1075: NO), the CE error of S1077 is set without performing S1076 (1077).

In the above S1072, when the input sensor 1 signal is not ON (S1072: NO), as shown in S1079 in FIG. 42, it is determined whether or not the signals of the input sensors 1 and 2 are ON. .. Further, when the input sensors 1 and 2 signals are ON (S1079: YES), a CP error is set (S1080), and it is determined whether or not the previous game medal passing state is 0 or 1. (S1081).

Then, if it was not the situation of the previous game medal passing state 0 or 1, it is determined whether or not it is the situation of the previous game medal passing state 2 (S1082), and in the case of an affirmative judgment (S1082: YES). ), Set the input sensor 2 passage check time (S1083). In addition, a CE error is set (S1084), and it is determined whether or not the closing sensor 2 passing time has been exceeded (S1085).

In the above S1085, when the closing sensor 2 passing time has not been exceeded (S1085: NO), it is determined whether or not the closing sensor 1 passing time has been exceeded (S1085), and when it has not been exceeded. (S1086: NO) ends the process. In S1082, if the situation was not the previous game medal passing state 2 (S1082: NO), S1083 is not performed, and the CE error set in S1084 is performed (S1084).

If the input sensors 1 and 2 signals are not ON in S1079 (S1079: NO), the CP error of S1087 is set as shown in FIG. 43. Further, it is determined whether or not the previous game medal passing state was 0 or 2 (S1088), and in the case of a negative judgment (S1088: NO), a CE error is set (S1089), and the insertion sensor 2 is passed. It is determined whether or not the time has been exceeded (S1090). Then, when the passing time of the closing sensor 2 is exceeded (S1090: NO), the process is completed.

In the above 1070 shown in FIG. 42, when the insertion sensor signal is not ON (S1070: NO), the process proceeds to S1091 shown in FIG. 43, and the medal insertion inspection flag is cleared. Further, the data of the insertion sensor 1 passage check time and the input sensor 2 passage check time are cleared (S1092), and it is determined whether or not the previous game medal passage state is 0 (S1093).

Then, if it is not the situation of the previous game medal passing state 0 (S1093: NO), it is determined whether or not it is the situation of the previous game medal passing state 2 (S1094), and if a negative judgment is made (S1094: NO). ), Set the CP error (S1095). If the previous game medal passing state was 0 in S1093 (S1093: YES), or if the previous game medal passing state 2 was in S1094 (S1094: YES), the process ends. To do.

After the above S1095, it is determined whether or not the situation is the state of passing the game medal last time (S1096), and if a positive judgment is made (S1096: YES), the input monitoring counter is set to -1 (S1096).
S1097), it is determined whether or not the value of the input monitoring counter is within the normal range (S1098). Further, if the input monitoring counter is not in the normal range (S1098: NO), the error display request data is saved (S1099), and the process ends.

In the above S1096, when it is not the situation of the previous game medal passing state 1 (S1096: NO), or in each of the above S1074, S1078, S1081, S1086, and the above S1088, S1090 shown in FIG. If a YES determination is made), the process proceeds to S1099 and the error display request data is saved (S1099). Further, in S1098, if the input monitoring counter is within the normal range (S1098: YES), the process ends.
<Updated game medal passing status>

Next, the game medal passing state update process (S1028) used in the above-mentioned error check process (see FIG. 38) will be described. In this game medal insertion check process, as shown in FIG. 44, the game medal passing state is updated in response to the insertion sensor signal. More specifically, as shown in FIG. 44, the input sensor signal information is acquired (S1106), the game medal passing state is updated (S1107), and the process is completed.
<Check for abnormalities in input / payout sensors>

Next, the input / payout sensor abnormality check process (S1029) used in the above-mentioned error check process (see FIG. 38) will be described. In this game medal insertion check process, an input abnormality of the insertion sensor, an input abnormality of the payout sensor, and a passage abnormality of the selector passage sensor are monitored.

More specifically, as shown in FIG. 45, the previous error detection flag is updated (S1111), and it is determined whether or not the fall of the blocker signal is detected (here, whether or not it is turned off). (S1112). Further, when the fall of the blocker signal is detected (S1112: YES), the input sensor abnormality input detection start time is set (S1113), and it is determined whether or not it is an input-related error (S1114). ..

If the fall of the blocker signal is not detected in S1112 (S1112: NO), whether or not it is an input-related error without setting the input sensor abnormality input detection start time (S1113). The determination is made (S1114). Further, if it is determined in S1114 that it is not the time of the input-related error (S1114: NO), the blocker signal ON is inspected (S1115), and the effective inspection of the input sensor abnormality input detection start time is performed (S1116). ..

Further, it is determined whether or not there is an abnormality detection inspection of the closing sensor (S1117), and if the result is a positive judgment (S1117: YES), it is determined whether or not there is an abnormality detection of the closing sensor 2 (S1118). ). Then, when an abnormality is detected in the closing sensor 2 (S1118: YES), the C0 error detection flag is set (S1119), and it is determined whether or not the rise of the selector passage sensor signal is detected (S1120). ).

In S1117, when it is determined that there is no input sensor abnormality detection inspection (S1117: NO), or in S1118, it is determined that there is no abnormality detection related to the input sensor 2 (S1118: NO), C0. Without setting the error detection flag (S1119), it is determined whether or not the rise of the selector passage sensor signal is detected (here, whether or not it is turned ON) (S1120).

When the rise of the selector passage sensor signal is detected in S1120 (S1120).
: YES), the input monitoring counter is incremented by 1 (S1121), and the selector passage sensor residence time is set (S1122). Then, it is determined whether or not the selector passage sensor is ON (whether or not there is a delinquent goods) (S1123), and if it is ON (if there is a delinquent goods) (S1123: YES), the selector passage residence time Is determined (S1124).

If the selector passage residence time has elapsed in S1124 (S1124: YES), the CH error detection flag is set (S1125), and it is determined whether or not an HP error has occurred (S1126). Further, in S1124 above, if the selector passage residence time has not elapsed (S1124: NO), it is determined whether or not an HP error has occurred without setting the CH error detection flag (S1125) (S1126). ).

In the above S1126, if it is not the time of HP error (S1126: NO), the RWM address of the payout sensor abnormality detection 1 data is set (S1127), and the RWM address of the payout sensor abnormality detection 2 data is set (S1128). If an HP error occurs in S1126 (S1126: YES), the process ends.

Following the above S1128, the payout sensor 1 and 2 mask data and the payout sensor 2 bit data are set (S1129). Further, it is determined whether or not the hopper motor drive signal is ON (S1130), and if it is not ON (S1130: NO), the payout sensor check data is generated (S1131). Further, it is determined whether or not only the payout sensor 2 is ON (S1132), and when only the payout sensor 2 is ON (S1132: YES), the payout sensor abnormality detection 1 data and the payout sensor abnormality detection 2 data are performed. Is cleared (S1133), and the process is completed.

In S1114, when it is determined that the error is related to input (S1114: YES), in S1120, when the rise of the selector passage sensor signal is not detected (S1120: NO), the selector passage sensor is ON in S1123. If not (S1123: NO), the process proceeds to S1126 described above without performing processing between the two, and it is determined whether or not an HP error has occurred.

When ON of only the payout sensor 2 is not detected in S1132 (S1132: NO), the payout sensor 1 mask data and the payout sensor 1 bit are set as shown in FIG. 46 (S1134). Further, the payout sensor check data is generated (S1135), and the abnormality detection data clear data is set (S1136).

In the above S1130 (see FIG. 45), when the hopper motor drive signal is ON (S1130: YES), the payout sensor check data generation process (S1135) shown in FIG. 46 is performed without performing the intervening process. Do.

Subsequently, the payout sensor abnormality detection 3 data is cleared (S1137), and the payout sensor abnormality detection data that is not checked is cleared (S1138). Further, it is determined whether or not an abnormality of the payout sensor 1 or 2 is detected (S1139), and if an abnormality is detected (S1139: YES), the payout sensor abnormality detection time is measured (S1140) and processed. To finish. If the abnormality of the payout sensor 1 or 2 is not detected in S1139 (S1139: NO), the process ends without measuring the payout sensor abnormality detection time (S1140).
<Clear error display request data>

Next, the error display request data clearing process (S1030) used in the above-mentioned error checking process (see FIG. 38) will be described. In the process of clearing the error display request data, the error display request data is cleared when the error is displayed.

More specifically, as shown in FIG. 47, it is determined whether or not an error is displayed (S1146), and if an error is displayed (S1146: YES), the error display request data is cleared. (S1147), the process ends. If the error is not displayed in S1146 (S1146: NO), the process ends without clearing the error display request data (S1147).
<< 8-bit random number test >>

Next, the 8-bit random number check processing (S1046 to S1049) used in the above-mentioned built-in random number check processing (see FIG. 40) will be described. In this 8-bit random number inspection process, 8-bit random number inspection is performed, and when the 8-bit random number value is equal to or greater than the random number maximum inspection data and the random number maximum value is set, or when the acquired maximum 3 8-bit random number values are all. If they match, the process proceeds to the non-recoverable error processing 2.

More specifically, as shown in FIG. 48, an 8-bit random number value is acquired (S1151), and it is determined whether or not the random number value is smaller than the random number maximum inspection data (S1152). Further, when the random number value is not smaller than the random number maximum inspection data (S1152: NO), it is determined whether or not the random number maximum value is set (S1153), and when the random number maximum value is not set, it is determined. (S1153: NO), the 8-bit random number value is reacquired (S1154).

In the above S1152, when the random number value is smaller than the random number maximum inspection data (S1152: YES), the 8-bit random number value is reacquired without performing the determination process (S1153) related to the random number maximum value setting (S1152). S1154). If the maximum random number is set in S1153 (S1153: YES), the process proceeds to the non-recoverable error processing 2 (see FIG. 49) described later.

After the above S1154, it is determined whether or not the random numbers match (S1155), and if they match (S1155: YES), the 8-bit random number values are reacquired (S1156). Further, it is determined whether or not all the acquired three random number values match (S1157), and if they do not match (S1157: NO), the 8-bit random number maximum value inspection table is updated (S1158). Then, the 8-bit random number soft latch random number value register address is updated (S1159), and the process ends.

If the random numbers do not match in S1155 (S1155: N), the 8-bit random number maximum value inspection table in S1158 is updated without performing the intervening processing. Further, when all the three acquired random number values match in S1157 (S1157: YES), the process proceeds to the non-recoverable error processing 2 (see FIG. 49) described later.
<< Unrecoverable error processing 2 >>

Next, the non-recoverable error process 2 used in the above-mentioned set value error check process (see FIG. 39), built-in random number check process (see FIG. 40), 8-bit random number check process (see FIG. 48), and the like. explain. In this non-recoverable error processing 2, processing is performed when a non-recoverable error is detected.

More specifically, as shown in FIG. 49, the error display data of the lower digit is set (S1171), and the error display data of the upper digit is set (S1172). Further, the clear output port address and the number of ports are set (S1173), and the output ports (0 to 6) are turned off (S1174).

Further, the next output port address is set (S1175), it is determined whether or not the output is completed (S1176), and if the output is completed (S1176: YES), an error display for the output ports 3 and 4 is displayed. Output is performed (S1177). Then, the upper digit and the lower digit are switched (S1178), and the process returns to the process of the clear output port address and the number of ports set in S1173. If the output is not completed in S1176 (S1176: NO), the process returns to the process of turning off the output port (0 to 6) in S1174.
<Effects of the invention relating to medal insertion>

As described above, according to the slot machine 10 of the present embodiment, since the game medal selector 44 is provided with the insertion sensor 45 and the selector passage sensor 46, both the insertion sensor 45 and the selector passage sensor 46 are detected. The result can be used to determine the status of the game medal. Therefore, it is possible to take more robust measures against fraud as compared with the case where only the input sensor 45 is used, for example. Further, since the operation state related to the insertion of the game medal can be monitored by using the insertion sensor 45 and the selector passage sensor 46, error monitoring and operation control of the blocker 47 are appropriately executed based on various control modes as described above. It becomes possible to do. Then, the selector passage sensor 46 can be provided with various functions other than detecting the presence or absence of fraud, and the selector passage sensor 46 can be effectively used. Further, the stop of the game executed after the abnormality is detected can also be executed at an appropriate timing in relation to other processes.

Further, according to this embodiment, the test signal output process (S762) is executed in the error management process (see FIGS. 18 and 20) related to the timer interrupt process (see FIG. 18), and the test is performed for each timer interrupt process. Executes signal output processing. Then, the test signal output process (S762) sets a test signal corresponding to the combination determination result (combination lottery result), and the combination determination result can be output as a test signal. Further, the main control board 61 having the main CPU 81, which is an arithmetic processing means, is not provided with the emergency connector used for connection with the test apparatus at the product development stage, but is not provided for disposing the emergency connector. The mounting area 183 remains. Therefore, it is possible to provide the product under the same conditions as at the time of the test, and it is possible to reduce the risk of illegally acquiring inside information from the test signal.

Further, in the process at the time of turning on the power (see FIG. 12), the initial setting process is first executed based on the fact that the power is turned on. Then, as this initial setting process, after initializing the register (S1), although not shown, the initial value is set in the register, and the interrupt type is set. Further, when such an initial setting process is completed, the RWM checksum is calculated (S3), and it is determined whether or not the designated switches (here, the door switch, the setting door switch, and the setting key switch) are operated. (S9), if not operated (S9: NO), the power failure recovery process (see FIG. 21) is executed.

Therefore, when the power is turned on, the initial value can be set in the register at an early stage, and the process at the time of power-on is always in the same state without being affected by the data remaining in the register at the time of the previous power-off (FIG. 12). It becomes possible to execute most of the processes (S2 to S13) of (see).

Further, in the process at the time of power-on, after the initial value is set in the register, the process shifts to the setting change device process (see FIG. 13), and in the setting change device process, the set value is within a predetermined range (here, from "1"). Check whether it is in "6") (S30 in FIG. 13), if the set value is not within the predetermined range (S30: NO), correct the set value (S31), and then set. A set value display process for displaying the value on the game information display means is performed (S32). Further, in the display process, the information indicating that the setting is being changed and the stored setting value are output to the display device (here, the setting display LED 66 (see FIG. 4)) (S32), and are set according to the operation of the setting switch. The value is updated (S33 to S34).

Therefore, the process for displaying the set value can be appropriately specified from the power-on, and the set value can be displayed accurately. Then, a series of processes from turning on the power to displaying the set value can be appropriately performed. Further, it is possible to prevent an abnormal display from being displayed on the setting display LED 66 (see FIG. 4), which is a display device for displaying the set value.

As the transition condition to the setting change device process (FIG. 13), for example, it is conceivable to adopt a condition based on the state of the built-in RWM (see FIG. 11). More specifically, the checksum is performed for the entire area of the target range of the built-in RWM, and the transition condition to the setting change device processing is that the checksum value (checksum data) is normal. It can be illustrated. It is also possible to adopt a control mode in which a checksum is performed, but the checksum result is not used for any judgment condition, and even if there is an abnormality in the checksum value, no special processing is performed due to the checksum value. ..

Further, the satisfaction of a plurality of conditions may be used as a transition condition to the setting change device processing. In that case, both the power off execution processing flag is normal and the checksum result is normal. Can be considered as a transition condition to the setting change device processing.

Further, according to this embodiment, when the setting change switch (setting key switch 68 in FIG. 4) is operated, the change of the switch signal (setting / reset button signal) is detected by the rising edge of the signal (FIG. 4). 13 S33). Further, according to the present embodiment, in the game progress main process (see FIG. 14), the presence or absence of a game medal is determined at the start of the game (S54), and when there is no game medal (when there is no bet number) (S54). : NO), as described above, the set value can be confirmed so that the currently set set value is visibly displayed on the display device (setting display LED66). Further, when there is a game medal (when there is a bet number) (S54: YES), the set value currently set is not displayed on the display device (setting display LED66), and the set value cannot be confirmed.

Then, in the display process (S55) when waiting for the game medal to be inserted, which is executed when the set value can be confirmed, the set value can be confirmed by operating the setting change switch (setting key switch 68). It becomes. Further, in the state where the set value can be confirmed, the blocker OFF data is set so that the game medal cannot be inserted, the stored set value is displayed, and the change of the switch signal is detected (fall detection). The process of displaying the set value is completed, and the process for setting the blocker ON data is executed.

Further, in the state where the set value can be confirmed, the process of advancing the game, such as from the game medal management (S56 in FIG. 14) to the game end check (S68 in FIG. 14), is not performed. Further, although not shown, in the set value confirmable state, an error related to a random number is detected, but other error monitoring is not performed. Further, the state in which the set value can be confirmed is shifted by detecting the change in the switch signal, while when the bet number is set (S54: YES), the change in the switch signal related to the bet number is detected. However, it does not shift to the setting confirmation state, but the game can proceed (see S56 and later).

By executing the process for making the set value unconfirmable in this way and setting a limit on the confirmation of the set value, it is possible to prevent the set value from being confirmed without following a predetermined procedure. It becomes. Then, it becomes possible to prevent fraudulent acts that try to confirm the set value by a method other than an appropriate method.

Further, according to the present embodiment, when the game medals are paid out based on the display determination (S66) of the game progress main process (see FIG. 14), the display process related to the number of paid out game medals is performed to perform the game. Every time one medal is paid out, the value displayed on the display device (here, the acquired number display unit) is updated. Then, the value corresponding to the number of sheets finally paid out is displayed until the next game medal is inserted or the above-mentioned game standby display start (when the game medal is not inserted even after a certain time has passed from the end of the game). Will be done. Further, even when the information related to the number of paid out game medals is being displayed, when an error occurs, the value corresponding to the displayed number of medals is changed to the display corresponding to the generated error.

Then, according to the present embodiment as described above, by setting the condition for turning off the display of the number of acquired medals, the display related to the number of game medals can be changed to another display mode at an appropriate timing. It is possible to prevent the result of the game from being misidentified as compared with the case where the switching is not performed or the timing of the switching is too late or too early.

Further, according to the present embodiment, in the game progress main process (see FIG. 14), a predetermined value (start address) is set in the stack pointer (S51). Then, the game medal management process (S56) and the start switch input confirmation process (S58) are performed. Further, the game medal management process (S56) and the start switch input confirmation process are repeated until the start switch is effectively accepted (S58). Therefore, the stack pointer can be cleared every time in the game progress main process (see FIG. 14) at the initial stage of the start, and when some abnormality occurs, it is possible to prevent the process from looping in the abnormal state.

Further, according to the present embodiment, in the game progress main process (see FIG. 14), the display determination (S66) is performed, and if the game medal is paid out, the process for paying out the game medal (S67) is performed. Then, when the payout of the game medals is completed, or when the payout of the game medals is not completed, a process according to the game state is performed by the game end check (S68 or the like).

Then, in the game end check process (S68, etc.), the RWM clear process of the condition device number other than the carry-over combination (clearing the condition device of the non-carry-over combination), turning off the re-game display LED, clearing the re-game operation flag, Set the game status such as bonus (BB in this case) and RT. Further, when the game end check (S68 or the like) is completed, a predetermined value (start address) is set in the stack pointer at the beginning of the game progress main process (see FIG. 14) (S51). Therefore, the stack pointer can be cleared every time after the game end check (S68 or the like), and if any abnormality occurs, it is possible to prevent the processing from looping in the abnormal state.

Further, according to the present embodiment, when the power is turned off, the value of the stack pointer is set in the built-in RWM area (F000H to F14AH) shown in FIG. 11 in the power off processing (see FIG. 19). Saved in an area (S568), check sum data is calculated for the storage area range (F000H to F3FFH) of the RWM including this work area, and the check sum value obtained by the calculation is the first predetermined value in the same work area. The storage area is stored in a second predetermined storage area (S574). Further, the above-mentioned first predetermined storage area and second predetermined storage area are set in areas other than the beginning and the end of the work area. Therefore, the value of the stack pointer and the value of the check sum data can be saved while avoiding the beginning and the end of the work area where the position can be easily specified, and it becomes difficult for a third party to identify the storage location of these values. This makes it possible to prevent fraud.

The present invention is not limited to the above-described embodiments, and various control modes as described below can be adopted.
<Control mode related to error notification>

First, a control mode related to error notification will be described. As a control mode related to error notification, in the error management process (see FIG. 20) following the timer interrupt process (see FIG. 18), the selector passage sensor 46 and the input sensor 45 are subjected to an error check (S754) related to the second control. Monitoring is performed (see FIG. 38), and when an error occurs, a main command is transmitted to the sub control board 31, and based on this main command, the sub control board 31 causes, for example, the effect unit 18 (see FIG. 1). It is conceivable to use it to notify an error. In other words, the error notification can be performed before the progress of the game is stopped (before the error display processing in each situation).

Further, when an error occurs after the operation of the start lever 25, that is, in the state where the blocker 47 is OFF (returnable state), for example, the effect is being performed by the effect unit 18 (see FIG. 1). It is conceivable to cancel (cancel) the effect and notify the effect unit 18 or the like that an error has occurred. Further, as another aspect, similarly, when the blocker 47 is in the OFF state (returnable state) and the effect is executed by, for example, the effect unit 18 (see FIG. 1), for example, while continuing the effect, for example. It is conceivable to display an error on a display device capable of performing an error notification (for example, an acquired number display LED) or to execute an error notification by voice using the speaker 50. Further, as another aspect, similarly, in the state where the blocker 47 is OFF (returnable state), for example, the effect unit 18 (see FIG. 1) has a high degree of expectation indicating that the degree of expectation of playing a role is high. If an error occurs while performing a specific effect such as an effect or a continuous effect that is performed continuously across multiple games, a notification to the effect that the error occurs is executed after the entire cylinder is stopped. It is conceivable to do. For example, when the sub control means (here, the sub control board 31) receives the main command based on the input error set processing (see FIG. 25), the sub control means (here, the sub control board 31) has a predetermined notification mode A (liquid crystal, first lamp, and). When an error is notified by an amplifier (speaker) notification mode) and a main command based on the error display process (see FIG. 24) is received, another notification mode B (liquid crystal, first lamp, second). (Notification mode using the lamp and the amplifier (speaker)) may be used for notification. At this time, the second lamp is a lamp that can navigate the operation order during the AT game (notification game) so that the player will not be disadvantaged in the game even if an error occurs. It is possible to control the second lamp.
<Control mode related to game stop>

Further, as a control mode related to the game stop, for example, in the timer interrupt processing, the selector passage sensor 46 and the input sensor 45 are monitored by error management (see FIG. 20) (see FIG. 38), and an error is detected. Then, instead of proceeding to the error display process (FIG. 24) and then performing the loop process according to S240 or S248 in FIG. 24 to stop the game, the game is immediately stopped within the error check (FIG. 38) (FIG. 38). For example, the blocker is turned off). Further, it is conceivable to execute error notification using the effect unit 18, the speaker 50, or the like under the control of the sub control board 31 in synchronization with the timing of the game stop.
<Other control modes related to error detection>

Further, the blocker 47 is in the ON state (passable state), and an error based on the closing sensor 45 is detected by an error check (FIG. 38) in the error management process (FIG. 20) from the timer interrupt process (see FIG. 18). If this is the case, it is possible to shift to a process of immediately stopping the game (for example, a blocker OFF process) within the error check (FIG. 38) without waiting for the error display process (FIG. 24). Conceivable.

Further, when an error based on the input sensor 45 or the like is detected by various processes in the game progress main process (see FIG. 14), the selector passage sensor 46 is monitored by the timer interrupt process and the input sensor 45 is monitored. It is possible not to execute the processing for. Further, as described above, while the processing for monitoring the selector passage sensor 46 and the monitoring of the input sensor 45 by the timer interrupt processing is not executed, the payout provided in the game medal payout device 63 (see FIG. 2) is not executed. The sensor (not shown) is monitored based on the timer interrupt cycle, and when an abnormality such as retention or backflow of a game medal is detected by the payout sensor, a command set that sends an error command associated with the abnormality to the sub. It is conceivable to execute the process for.

Further, when the above-mentioned door (front door portion 11) is open (when the door switch is in the open state), an error notification related to door opening is performed using the LED or the speaker 50. However, although the main control board 61 recognizes the occurrence of an error related to the opening of the door, it does not recognize it as an error corresponding to stopping the game, and transmits a command related to the occurrence of this error to the sub control board 31. To do. Then, the sub control board 31 executes the error notification of opening the door. Therefore, even if the front door portion 11 is opened, it is possible to play a game accompanied by reel control. Further, when the front door portion 11 is closed in the situation where the door opening error notification is being performed, the sub control board 31 determines that the door opening error canceling condition is satisfied, and the door is opened by the LED or the speaker 50. End error notification. The sub-control board 31 may wait for a predetermined time (for example, about several seconds) to elapse after closing the front door portion 11 to end the door opening error notification.
<Various aspects related to management of minimum game time>

In this embodiment, as described above, the management of the minimum game time is performed in various modes depending on the situation. In the following, first, the basic functions and management modes related to the minimum game time will be described, and then, various management modes of the minimum game time during normal times and when a predetermined error occurs are shown in FIGS. 50 to 53. It will be explained based on.
<< Basic functions and management modes related to the minimum game time >>

First, as described above, the minimum game time does not start the rotation of the rotation in the current game unless a predetermined time (4.1 seconds in this case) has elapsed from the start of the rotation of the rotation in the previous game. It is for doing so. Then, as described above, the timer measurement of the time (game time) related to the minimum game time is based on the timer measurement process (S551) in the timer interrupt process (see FIG. 18). Here, in the timer measurement process (S551), counting (subtraction here) of all timers is executed. Then, in the timer measurement process (S551), the 1-byte timer and the 2-byte timer are measured as described above, but the minimum game time is counted by using the 2-byte timer.

Further, when the time required for one game exceeds the minimum game time, a bet setting (bet) for a game medal is made, and when the start lever 25 (see FIG. 1) is operated, the above-mentioned rotation cylinders 51L to 51 The rotation waiting period (weight period) in which the rotation of the cylinder is not performed does not occur, and the rotation cylinders 51L to 51 start to rotate. Here, in this embodiment, the period of one game is the period from the start of rotation to the stop of rotation of the rotating cylinders 51L to 51.

On the other hand, if the bet of the game medal is set (bet) and the start lever 25 (see FIG. 1) is operated, but the minimum game time set at the time of the previous game has not yet passed, Until the minimum game time elapses, the rotating cylinder rotation waiting period (weight period) in which the rotating cylinders 51L to 51 are not rotated is set. Further, even if the above-mentioned stop buttons 24L to 24R are operated during the rotating cylinder rotation standby period (weight period), these operations are not accepted.

In the following, after the operation of the start lever 25 is detected after the rotation of the rotating cylinder in the previous game is stopped, the period during which the rotation of the rotating cylinder in the current game is not started is waited for the rotation of the rotating cylinder to start after the rotation is stopped. It is referred to as a "weight period" which is a period, and is distinguished from the above-mentioned "4.1 second weight" corresponding to the minimum game time. Further, the above-mentioned "weight period" count can be performed by using a timer included in the "other game standby measurement timer" in the timer measurement process (see S551 in FIG. 18).

As described above, the check of whether or not the minimum game time has elapsed and the set of the timer related to the minimum game time (hereinafter, may be referred to as "minimum game time timer") are the game progress main processes (FIG. 13). It is executed in the rotation start standby of the rotating cylinder, which is used in the internal lottery start processing (S60) of (see). That is, the time lapse check and timer set related to the minimum game time are performed not by interrupt processing but by processing executed according to the progress of the game. Further, the timer measurement of the time related to the minimum game time may be performed in a mode of counting down the timer value, or may be performed in a mode of counting up.
<< Management mode during normal operation >>

FIG. 50A shows a management mode of the minimum game time in a normal time. Here, in the present embodiment, the "normal time" can be broadly defined as a normal state in which a game is possible. Then, in this embodiment, for example, a situation in which a recoverable error or a recoverable error as described later occurs (see FIGS. 50B and 51A) and a situation in which the set value is confirmed (FIG. (See 52 (B)) and the like can be excluded from this “normal time”.

Further, in a narrow sense, the above-mentioned "normal time" is defined in the present embodiment as, for example, at the time of clearing or inserting a game medal described later (see FIGS. 51 (B) and 52 (A)). It is possible to exclude situations in which the management mode of the minimum game time is explained. The situation at the time of clearing or inserting the game medal (see FIGS. 65 (B) and 66 (A)) is also included in the "normal time", and for example, the "normal time" shown in FIG. 50 (A) is "basic". It is also possible to refer to "normal time" or "general normal time", and to refer to the situation at the time of settlement or insertion of the game medals shown in FIGS. 51 (B) and 52 (A) as "specific normal time". ..

(A) to (g) in FIG. 64 (A) show the minimum game time timer, the rotation start permission state, the lever operation, the first cylinder, the second cylinder, the third cylinder, and the display determination. Each timing related to is roughly shown. Further, the 1st cylinder, the 2nd cylinder, and the 3rd cylinder in the drawing are the above-mentioned 1st cylinder 51L, 2nd cylinder 51C, and 3rd cylinder 51R (see FIG. 1). It corresponds.

Of the (a) to (g) in FIG. 50 (A), at the minimum game time of (a) shown at the top, the rising edge of the chart as shown in the timing T1 is the timer measurement related to the minimum game time. Corresponds to the start of. As described above, this minimum game time is set so that the current rotation of the cylinder is not started until a predetermined time (4.1 seconds in this case) has elapsed from the start of the rotation of the cylinder in the previous game. Is for. Then, as described above, the timer measurement related to the minimum game time timer is performed by the timer measurement process (S551) in the timer interrupt process (see FIG. 18).

Further, in FIG. 50 (A), in the minimum game time timer of (a), it is shown that the count of the minimum game time timer is continued during the period when the chart is up (the period from T1 to T2). , The falling edge of the chart shown at the timing T2 indicates that the count of the minimum game time timer has stopped. Then, in the normal time shown in FIG. 50 (A), the timer measurement related to the minimum game time timer is continued for 4.1 seconds, which is the period during which the rotation of the rotating cylinder related to the next game cannot be started. It stops as time passes, and the count of the minimum game time timer ends.

Subsequently, regarding the state of permission to start rotating the rotating cylinder shown in FIG. 50 (A), the period during which the chart is standing is the above-mentioned 1st cylinder 51L, 2nd cylinder 51C, and 3rd cylinder. It shows that 51R (see FIG. 1) is a period during which rotation can be started. That is, (b) in FIG. 50 (A) shows a state in which the rotating cylinders 51L to 51R cannot start rotation (start not permitted) while the time related to the minimum gaming time shown in (a) is being measured. State), and while the time related to the minimum game time is not measured, it is shown that each rotation cylinder 51L to 51R is in a state where rotation can be started (start permission state).

Then, in (b) in FIG. 50 (A), as shown at the left end of the chart, the chart is started from the situation where the rotation of the rotating cylinder can be started (the situation before timing T1), and (a). ) When the measurement of the time related to the minimum gaming time is started (timing T1), the rotation of the rotating cylinder cannot be started. Further, when the measurement of the time related to the minimum game time is stopped (timing T2), the rotation of the rotating cylinder can be started, and when the measurement of the time related to the minimum gaming time is started again, the rotation of the rotating cylinder is started. (Timing T3).

Subsequently, with respect to the lever operation shown in (c) in FIG. 50 (A), the rising edge of the chart shown at the timing T4 indicates that the above-mentioned operation of the start lever 25 has been detected. Further, (d) to (f) in FIG. 50 (A) show the states of the first cylinder (51L), the second cylinder (51C), and the third cylinder (51R), respectively. There is. The rise of the chart in (d) to (f) in the figure indicates the start of rotation of each cylinder (51L to 51C), and the fall of the chart indicates the stop of rotation of each cylinder (51L to 51C). Shown.

As shown in the left end portion in (b) in FIG. 50 (A), in a situation where the rotation of the rotating cylinder can be started (a situation before timing T1), when there is a lever operation as shown in FIG. (Timing T4), the first cylinder (51L), the second cylinder (51C), and the third cylinder (51R) start rotating (timing T1). At this time, the timer measurement is started for the minimum game time timer in the figure (a), and the rotation cannot be started for the rotation cylinder rotation start permission in the figure (b).

Then, when each of the above-mentioned stop buttons 24L to 24R (see FIG. 1) is operated in the order of the first stop button 24L, the second stop button 24C, and the third stop button 24R (so-called forward push), it is shown in the figure. As shown, the first cylinder (51L) and the second cylinder (51C) stop in order, and finally the third cylinder (51R) stops as shown at timing 5 in the figure. Here, among the above-mentioned round cylinders (51L to 51R), the game in which the third cylinder (51R) finally stops at the timing T5 will be described below as the N (N is a natural number of 1 or more) th game. ..

Further, here, in order not to complicate the explanation and illustration, each stop button 24L to 24R is pushed forward, and each rotation cylinder is stopped by the first cylinder (51L), the second cylinder (51C), and the third cylinder. The case of stopping in the order of the body (51R) is described. However, the stopping order of each rotating cylinder (51L to 51R) is not limited to this, and any of the six types of left middle right, left and right middle, middle left and right, middle right left, right left middle, and right middle left can be used. There may be.

As shown in the timing T5 in FIG. 50 (A), when the last rotation cylinder (here, the third cylinder 51R) is stopped, as shown by the rising edge of the chart at the timing T5 in the figure (g). A display determination (see S66 in FIG. 14) is performed.

Here, even if the final rotation stop (here, the stop of the third body 51R) is performed (timing T5), the measurement by the minimum game time timer in FIG. 50 (A) (a) must be completed. For example, as shown in the timing T6 in the figure (c), even if there is a lever operation for the next game (N + 1th game), the rotation of the rotating cylinder is not started immediately. Then, as shown by the timing T2 in the figure, when the minimum game time elapses, the rotation of each rotating cylinder (51L to 51R) is started based on the lever operation at the timing T6 (timing T3).

Then, when the respective stop buttons 24L to 24R are operated by pressing forward again, as shown in (d) to (f) in the figure, the first cylinder (51L) and the second cylinder ( The rotating cylinder is stopped in the order of 51C) and the third cylinder (51R), and the display determination related to the N + 1th game is performed as shown in the timing T7 in the figure (g).

It should be noted that various modes can be adopted for the mode of starting the rotation of each rotating cylinder (51L to 51C) shown in the timing T1 and the timing T3 in FIG. 50 (A). For example, as shown in the figure, an embodiment in which three rotating cylinders are started to rotate at the same time, a mode in which a time difference is provided at the timing of starting rotation of each rotating cylinder, and the like can be exemplified. Further, as a method of providing a time difference in the timing of starting the rotation of each reel, for example, after the rotation of the two reels of the first reel and the next reel is started, the measurement of the time related to the minimum gaming time is started. An embodiment in which the remaining (last) reels are then rotated can be illustrated. It is also possible to consider an embodiment in which the measurement of the time related to the minimum gaming time is started after the start of rotation of the first reel, and then the two remaining reels are sequentially started to rotate.

In addition to the above-mentioned ones, for example, when the lever is operated, if the minimum game time set at the start of the rotation of the reel in the previous game has not elapsed, the timing of starting the rotation of each reel is set. , For example, the remaining time (weight period) is divided into three equal parts, and when one-third of the time elapses, the first (first) reel starts rotating, and when two-thirds of the time elapses. There is also a mode in which the second (second) reel is started to rotate, and the third (last) reel is started to rotate when the remaining 1/3 of the time elapses and the minimum game time elapses. It can be exemplified.
<< Management mode at the time of recoverable error >>

Next, a mode of managing the minimum game time when a recoverable error (recoverable abnormality) occurs will be described with reference to FIG. 50 (B). The same parts as those in the normal state shown in FIG. 50 (A) will be illustrated in the same manner, and the description thereof will be omitted as appropriate.

In FIG. 50 (B), (a) to (g) show the minimum game time timer, the rotation start permission of the rotating cylinder, the lever operation, the first cylinder (51L), as in the normal time of FIG. 50 (A). The charts of the 2nd cylinder (51C), the 3rd cylinder (51R), and the display determination are shown. Here, when the game from the start of rotation to the stop of rotation of the rotating cylinders 51R to 51L shown on the left side in the figure is the Nth game as described above, as shown on the right side in the figure, each rotating cylinder The next rotation and stop games of 51R to 51L are the N + 1th games as described above.

Further, (h) to (j) in FIG. 50 (B) show charts of recoverable error, abnormal state, and abnormal release. As described above, in the slot machine 10 of this embodiment, there is an error that can be returned to the normal state by canceling the error (recoverable error), and it is impossible to return to the normal state only by canceling the error. There is an error (unrecoverable error).

Of these, the recoverable error is an error that can be cleared without starting the above-mentioned setting change device process (see FIG. 13) and performing the setting change device process. On the other hand, the unrecoverable error can be cleared by turning on the setting key, turning on the power, and starting the setting change device process (see FIG. 13) after the power is cut off after the error occurs. This is an error in which the setting change state is exited by turning off the setting key and the normal state (the state in which the game is possible) is restored. Then, (h) in FIG. 50 (B) shows the detection (occurrence) of the recoverable error among these errors by the rising edge of the chart (timing T11).

As described above, this recoverable error is an error related to the payout of game medals, H.
There are E error, HP error, HQ error, FE error, and CP error, C0 error, C1 error, CH error, and CE error, which are errors related to the insertion of game medals. Of these, the HE error is an error when it is determined that the game medal in the game medal payout device 63 is empty, and the HP error is a judgment that the game medal exit in the game medal payout device 63 is clogged with the game medal. This is a case error.

Further, the HQ error is an error when it is determined that the payout sensor (not shown) has an abnormal input, and the FE error is an error when it is determined that the game medal auxiliary storage 71 is full. Further, the CP error is an error when it is determined that the inserted game medal has passed illegally, and the C0 error is when it is determined that the insertion sensor (here, the insertion sensor 2) has an abnormal input as described above. Error.

Further, the C1 error is an error when it is determined that there is an abnormality in the portion of the medal passage 105 where the insertion sensor 45 and the selector passage sensor 46 are provided, and the CH error is a game in the selector passage sensor 46 as described above. This is an error when it is determined that the medals have accumulated. Further, the CE error is an error when it is determined that the game medal has accumulated in the portion where the insertion sensor 1 (115) or the insertion sensor 2 (116) is provided.

The error release condition related to these errors is that a release operation for changing the signal of the setting / reset button 69 (setting / reset button signal) from OFF to ON is performed with the cause removed. Further, when the door switch signal related to the door switch 60 and the setting door switch signal related to the setting door switch 67 are ON, the above-mentioned release operation becomes effective.

Regarding (h) in FIG. 50 (B), when a recoverable error is detected (timing T11), an abnormal state occurs as shown by the rising edge of the chart (timing T11) in FIG. 50 (i). Here, the recovery error detection timing (T11) is the timing after all the rotating cylinders (51L to 51R) have stopped.

Further, when the recoverable error is canceled and the cancellation of the abnormal state is detected (timing T2 in this case) as shown by the rising edge of the chart in the figure (j), the above-mentioned abnormal state ends (timing T12). ). In FIG. 50 (B), the timing of releasing the abnormality in (j) is shown so as to coincide with the end timing (timing T2) of the measurement by the minimum game time timer in (a). Is just an example, and the timings of the two do not always match.

Further, in this embodiment, as shown in (h) to (j) in FIG. 50 (B), even in a situation where a recoverable error occurs (see timing T11 or later), it is shown in (a) in the figure. As described above, the measurement (counting) of the time related to the minimum game time is continued. Then, when 4.1 seconds have elapsed from the start of the measurement of the time related to the minimum game time, the measurement of the time related to the minimum game time is stopped (timing T2). At this time, if the error state continues as shown in (i) of the figure, as shown in (a) and (b) of the figure, even if the measurement by the minimum game time timer is completed, the rotating cylinder The rotation cannot be started.

That is, in the example shown in FIG. 50 (B), as shown in (a) and (b) in the figure, even if the minimum game time set in the RWM elapses in the Nth game (timing T2). ), It will not be possible to rotate the cylinder immediately. Then, when the abnormal state ends as shown in (i) in the figure (timing T12), the start of the rotating cylinder rotation is permitted as shown in (b) in the figure (timing T12).

Further, after that, as shown in (c) in the figure, if there is a lever operation in the N + 1th game (timing T6), the first body (51L), the second body (51C), and the third time. The rotation of the body (51R) is started, the timer set related to the count of the minimum game time timer is performed, and as shown in the figure (a), the measurement of the time related to the minimum game time is started. Along with this, as shown in (b) in the figure, the start of rotation of the rotating cylinder is not permitted.

Then, when the stop buttons 24L to 24R are operated, the cylinders 51L to 51R are stopped based on the operation timing and the operation order of the stop buttons 24L to 24R. Here, in the example of FIG. 50 (B), as in the case of FIG. 50 (A), the stop buttons 24L to 24R are in order for both the Nth game and the N + 1th game. It is operated by pushing.

The management mode at the time of this recoverable error can also be explained as follows. That is, the measurement (counting) of the time related to the minimum game time is continued while the game is stopped due to the returnable error. Then, in the Nth game, the period during which the game was performed before the returnable error occurred (the period from the start of the game until the returnable error occurred) and the period during which the recoverable error occurred (recoverable). If the total (error duration) exceeds the minimum game time (4.1 seconds), the N + 1th game can be started without a weight period. On the other hand, if the total of the period in which the game before the returnable error occurred and the period in which the returnable error occurs is less than the minimum game time (4.1 seconds), the N + 1th game is performed. , Can be started after a weight period.

According to the management mode at the time of the recoverable error as described above, when the recoverable error occurs, by continuing the measurement of the time related to the minimum game time, the passage of the minimum game time is not hindered as much as possible. It is possible to control the game machine. Further, the time related to the minimum gaming time can be counted regardless of the state of the gaming machine (slot machine 10 in this case) or the gaming state. Then, the game can proceed smoothly, and it is possible to secure the maximum number of games per predetermined time (for example, the game time by one player or the business hours for one day of the game field). Become.

That is, as described above, the period related to the minimum game time is the period during which the next rotation of the cylinder cannot be started, and by stopping the measurement of the time related to the minimum game time, the next rotation of the cylinder cannot be started. The period will be extended. For this reason, in order to secure as many games as possible and have the players enjoy the games, it is desirable not to increase the period during which the rotation of the body cannot be started beyond the minimum required period (4.1 seconds). .. Then, according to the slot machine 10 of the present embodiment, it is possible to prevent the period during which the game cannot be progressed from increasing beyond the predetermined time (4.1 seconds) as much as possible, and under the limitation of the minimum game time. However, it is possible to secure as many games as possible.
<< Management mode in case of unrecoverable error >>

Next, a management mode of the minimum game time when a non-recoverable error (non-recoverable abnormality) occurs will be described with reference to FIG. 51 (A). The same parts as those at the time of the recoverable error shown in FIG. 50B will be illustrated in the same manner, and the description thereof will be omitted as appropriate.

In FIG. 51 (A), (a) to (f) show the minimum game time timer, the rotating cylinder rotation startable, the operation lever, and the first cylinder (1st cylinder), as in the case of the recoverable error shown in FIG. 51L), the 2nd cylinder (51C), and the 3rd cylinder (51R) are shown. Further, (g) in FIG. 51 (A) shows the state of the power supply, and indicates that the power supply is ON during the period when the chart is up.

Further, (h) in FIG. 51 (A) indicates the detection (occurrence) of the unrecoverable error by the rising edge of the chart (timing T16). As described above, this non-recoverable error is an error that cannot be cleared unless the setting change device process (see FIG. 13) is executed. Therefore, when an unrecoverable error occurs, a game clerk or the like temporarily turns off the power of the slot machine 10 (timing T17), and then turns on the setting key switch 68 (see FIG. 4) in order to clear the error. In this state, it is necessary to turn on the power again to start up (timing T18) and operate the setting changing device (timing T19).

As the unrecoverable error, as described above, there are an E1 error, an E5 error, an E6 error, and an E7 error. Of these, the E1 error is an error when the power supply is cut off and restored normally, and the E5 error is an error when the combination display of the symbols when the cylinder is stopped all the time is abnormal. The details of this E5 error will be described later. Further, the E6 error is an error when the set value is out of the range, and the E7 error is a frequency abnormality of the clock input to the RCK terminal (not shown) for updating the random number in the main CPU 81, or a built-in random number (16 bits). This is an error when an abnormal update status (random number) is detected.

The E5 error among the various non-recoverable errors described above is when the combination display of symbols is abnormal as a result of performing the display determination in the display determination (S66) in the game progress main process (see FIG. 14) described above. Occur.

Subsequently, the non-recoverable error processing will be described with reference to FIG. 29. In the non-recoverable error processing shown in FIG. 29, interrupts are prohibited (S411), and error display data is set in the order of the lower digit and the upper digit of the error display (S412, S413). Further, the clear output port address and the number of output ports are set (S414), the output port (0 to 6 in this case) is turned off (S415), and the next output port address is set (S416).

Then, if the output end is determined (S417) and all the outputs for the output ports (0 to 6) are completed (S417: YES), the error display processing (S418) is performed to the output ports 3 and 4. Output for error display. Then, switching between the upper digit and the lower digit is performed (S419), and the process returns to the above-mentioned set processing of the clear output port address and the number of output ports (S414).

On the other hand, in the above-mentioned output end determination process (S417), if the output is not completed (S417: NO), the process returns to the output port OFF process (S415). Then, the process of turning off the output port (S415) and setting the next output port address (S416) is repeated until all the outputs of the output ports (0 to 6) are completed. Further, after all the outputs of the output ports (0 to 6) are completed (S417: YES), the process proceeds to the above-mentioned error display process (S418).

As described above, the detection (occurrence) of the non-recoverable error as described by taking the E5 error as an example causes an abnormal state (timing T16) as shown by the rising edge of the chart in (i) in FIG. 51 (A). Then, for example, the amusement park clerk temporarily turns off the power switch 72 (see FIG. 4) (timing T17) in order to activate the setting change device to cancel the unrecoverable error, and then, as described above. With the setting key turned on, the power switch 72 is turned on to turn on the power (timing T18). Then, as shown by the rising edge of the chart in (j) in the figure (timing T19), the setting change device is activated, and the abnormal state due to the unrecoverable error is resolved (similarly, timing T19).

Further, in the present embodiment, in the situation where the non-recoverable error occurs, the measurement of the time related to the minimum game time is stopped (timing T16) as shown in (a) in FIG. 51 (A).
).

When the error is cleared as shown in (j) in FIG. 51 (A) (timing T19), the rotation of the rotating cylinder can be started as shown in (b) in the figure (timing T2). .. Further, after that, if there is a lever operation as shown in (c) in the figure (timing T6), the first cylinder (51L) and the second cylinder (51C) related to the N + 1th game as described above are performed. ), The rotation of the third body (51R) is started, and the measurement of the time related to the minimum gaming time is started as shown in (a) in the figure (timing T3).

The management mode at the time of this unrecoverable error can also be explained as follows. That is, the measurement (count) of the time related to the minimum game time is stopped while the game is stopped due to an unrecoverable error. The unrecoverable error is an abnormality that cannot be cleared unless the setting change device process (see FIG. 13) is started as described above. Then, when the setting change device processing is performed, the internal numerical values and flags handled by the main CPU 81 are cleared. Therefore, the numerical value of the count associated with the time measurement is also cleared. That is, when the unrecoverable error is cleared, the value of the counter set before that is cleared, so that the wait period does not occur when the start lever 25 is operated after the unrecoverable error is cleared. The reel will start rotating.

According to the management mode at the time of the non-recoverable error as described above, when the non-recoverable error occurs, the load related to the program processing can be reduced by stopping the measurement of the time related to the minimum game time. become. That is, since the non-recoverable error is an error that cannot be canceled unless the installation change device is operated (initialization operation), there is no measure for canceling the error other than this initialization operation. Therefore, if the measurement of the time related to the minimum game time is continued when an unrecoverable error occurs, the program processing for continuing the measurement is wasted. Therefore, as described above, by stopping the measurement of the time related to the minimum game time when a non-recoverable error occurs, it is possible to prevent unnecessary program processing from being executed and reduce the processing load. Become.
<< Management mode at the time of game medal settlement >>

Next, a management mode of the minimum game time in the case of clearing the game medal will be described with reference to FIG. 51 (B). The same parts as those at the time of the recoverable error shown in FIG. 51 (B) are shown in the same manner, and the description thereof will be omitted as appropriate.

In FIG. 51 (B), (a) to (g) show the minimum game time timer, the rotation of the rotating cylinder, the operation lever, and the first cylinder (as in the case of the recoverable error shown in FIG. 50 (B). 51L), the second cylinder (51C), the third cylinder (51R), and the display determination charts are shown. Further, (h) in FIG. 51 (B) shows the state of medal clearing, and the game medal is cleared according to the rising period of the chart (the period after the timing T26). Represents.

Such clearing of game medals is based on the above-mentioned game medal clearing process (see FIG. 28), and the game medal management process (S56 and FIG. 26 in FIG. 14) related to the game progress main process (see FIG. 14). This is executed when the clearing button is ON (S325: YES in FIG. 26). Then, in the game medal clearing process (see FIG. 28), as described above, it is determined whether or not the game is a re-game (S371, S372), and the bet (bet) game medal is set according to the determination result. The processing based on (S373 to S380, etc.) and the processing based on the stored game medals (S383 to S390, etc.) are executed.

Further, in the present embodiment, the game medal can be cleared as described above by operating the clearing button even during the period from the end of the game to before the lever operation at the start of the next game. And, the settlement of this game medal is an operation that is possible even during the minimum game time.

Further, in the present embodiment, even in the situation where the game medals are settled in this way, the measurement of the time related to the minimum game time is continued as shown in (a) in FIG. 51 (B). .. Then, when 4.1 seconds have passed since the measurement of the time related to the minimum game time was started, the measurement of the time related to the minimum game time was stopped, and as shown in (b) in the figure, the next time (N + 1). It becomes possible to start the rotation of the rotating cylinder (timing T2).

The start timing (T26) of the settlement of the game medals is between the Nth game and the N + 1th game if there are bet game medals and stored game medals. It can occur at various timings based on the will of the person.

The management mode at the time of clearing the game medal can also be explained as follows. That is, the measurement (counting) of the time related to the minimum game time is continued while the game is stopped due to the settlement of the game medal. Then, in the Nth game, the period during which the game was performed before the game medal was cleared (the period from the start of the game to the start of the game medal clearing) and the period during which the game medal was cleared (game medal clearing). If the total of (duration period) exceeds the minimum game time (4.1 seconds), the rotation of the barrel in the N + 1th game can be started without a weight period. On the other hand, if the total of the period in which the game before the game medal is cleared and the period in which the game medal is cleared is less than the minimum game time (4.1 seconds), the number of times in the N + 1th game The body rotation can be started after a weight period.

According to the management mode at the time of clearing the game medals as described above, by continuing the measurement of the time related to the minimum game time, as in the case of the above-mentioned recoverable error (see FIG. 50 (B)), It is possible to control the game machine without hindering the passage of the minimum game time as much as possible. Further, the time related to the minimum game time can be counted regardless of the game state. Then, the game can proceed smoothly, and it is possible to secure the maximum number of games per predetermined time (for example, the game time by one player or the business hours for one day of the game field). Become.
<< Management mode when inserting game medals >>

Next, a management mode of the minimum game time in the case of inserting a game medal will be described with reference to FIG. 52 (A). The same parts as those at the time of the returnable error shown in FIG. 50 (B) and the time of clearing the game medal shown in FIG. 51 (B) are shown in the same manner, and the description thereof will be omitted as appropriate.

In FIG. 52 (A), (a) to (g) are the minimum game time timers and times, as in the case of the recoverable error shown in FIG. 50 (B) and the game medal clearing shown in FIG. 51 (B). Each chart of the body rotation startable, the operation lever, the first body (51L), the second body (51C), the third body (51R), and the display determination is shown. Further, (h) in FIG. 52 (A) shows a medal insertion state, and is a situation in which game medals are inserted depending on the rising period of the chart (the period from timing T5 to T6). It represents that.

In addition, in the "medal insertion" referred to here, the game medal is inserted into the game medal insertion slot 21, and the stored (credit) game medal is set (bet) by operating various bet buttons. In addition, when the result of the winning combination lottery in the previous game (previous game) is a re-game, automatic insertion (automatic betting) is performed.

When such a game medal is inserted, as described above, as a result of the check (S54) relating to the presence or absence of the game medal in the game progress main process (see FIG. 14), it is determined that the game medal has been inserted. (S54: YES), the process proceeds to the above-mentioned game medal management process (see S56 and FIG. 26). Then, in the game medal clearing process (see FIG. 28), as described above, it is determined whether or not the game is a re-game (S371, S372), and the bet (bet) game medal is set according to the determination result. The processing based on (S373 to S380, etc.) and the processing based on the stored game medals (S383 to S390, etc.) are executed.

Further, in the present embodiment, the game medals as described above can be inserted even during the period (weight period) from the end of the game due to the rotation stop to the lever operation at the start of the next game. .. That is, even during the weight period, the next game can be started by inserting medals from the game medal insertion slot 21 (see FIG. 1) or by operating the three-card insertion button or the one-card insertion button in the main input unit 26 described above. You can place bets (bet settings) on the game medals required for. In addition, when the result of the combination lottery in the previous game is a re-game, automatic insertion can be executed.

Further, in this embodiment, even in the situation where the game medals are inserted in this way, as shown in (a) in FIG. 52 (A), the measurement of the time related to the minimum game time is continued. There is. Then, when 4.1 seconds have passed since the measurement of the time related to the minimum game time was started, the measurement of the time related to the minimum game time was stopped, and as shown in (b) in the figure, the next time (N + 1). It becomes possible to start the rotation of the rotating cylinder (timing T2).

In addition, although it is shown here that the insertion of the game medal is started at the same time as the rise of the display determination chart in the Nth game (timing T5) (timing T5), it is limited to this. Instead, the game medals are inserted at various timings based on the player's will to play the N + 1th game after the stop (timing T5) of all the round cylinders (51L to 51R) in the Nth game. It can be done in.

The management mode at the time of inserting the game medal can also be explained as follows. That is, the time measurement (counting) related to the minimum game time is continued while the game is stopped due to the insertion of the game medal. Then, in the Nth game, the period during which the game was performed before the game medal was inserted (the period from the start of the game to the start of the game medal insertion) and the period during which the game medal was inserted (game medal insertion). If the total of (duration period) exceeds the minimum game time (4.1 seconds), the N + 1th game can be started without a weight period. On the other hand, if the total of the period in which the game is played before the game medal is inserted and the period in which the game medal is inserted is less than the minimum game time (4.1 seconds), the N + 1th game is performed. It can be started after a weight period.

According to the management mode at the time of inserting the game medal as described above, by continuing the measurement of the time related to the minimum game time, in the case of the above-mentioned returnable error (see FIG. 50 (B)), and in the game. Similar to the case of medal clearing (see FIG. 51 (B)), the game machine can be controlled without hindering the passage of the minimum game time as much as possible. Further, the time related to the minimum game time can be counted regardless of the game state. Then, the game can proceed smoothly, and it is possible to secure the maximum number of games per predetermined time (for example, the game time by one player or the business hours for one day of the game field). Become.
<< Management mode when checking set values >>

Next, a management mode of the minimum game time when the set value is confirmed will be described with reference to FIG. 52 (B). The same parts as those at the time of the recoverable error shown in FIG. 50 (B) and the case of the non-recoverable error shown in FIG. 51 (A) are shown in the same manner, and the description thereof will be omitted as appropriate.

In FIG. 52 (B), (a) to (g) show the minimum game time timer, the rotation of the rotating cylinder, the operation lever, and the first cylinder (as in the case of the recoverable error shown in FIG. 50 (B). 51L), the second cylinder (51C), the third cylinder (51R), and the display determination charts are shown. Further, (h) in FIG. 52 (B) shows a state of confirming the set value, and indicates that the set value is confirmed by the rising edge of the chart (timing T31).

In the confirmation of the set value shown in (h) in FIG. 52 (B), the presence or absence of a game medal is checked in the above-mentioned game progress main process (see FIG. 14) (S54), and the display when waiting for the game medal to be inserted is displayed. This can be performed when the process shifts to the process (S55) (S54: NO) and the set value can be confirmed. Further, in a state where the set value can be confirmed, the progress of the game (see S56 and later) is possible.

Further, as described above, the setting value is confirmed by operating the setting key so that the setting key switch 68 is turned on when the power of the slot machine 10 is turned on, and the setting changing device is activated. Will be. Then, for confirmation of the set value, the set value (here, any one of "1" to "6") is displayed on the setting display LED 66 (see FIG. 4) mounted on the main control board 61 (see FIG. 4). This displayed set value can be visually recognized by a game clerk or the like through the transparent main board case 65. In the set value confirmable state in which the set value can be confirmed in this way, the set value does not change even if the setting / reset button 69 is operated.

Further, in the present embodiment, even in the situation where the set value is confirmed in this way, the measurement of the time related to the minimum game time is continued as shown in (a) in FIG. 52 (B). Then, when 4.1 seconds have passed since the measurement of the time related to the minimum game time was started, the measurement of the time related to the minimum game time was stopped, and as shown in the figure (b), the next time (N + 1th time). ) Is ready to start rotating (timing T2).

The management mode at the time of confirming the set value can also be described as follows. That is, the measurement (count) of the time related to the minimum game time is continued while the game is stopped by confirming the set value. Then, in the Nth game, the period during which the game was performed before the set value was confirmed (the period from the start of the game to the start of the set value confirmation) and the operator such as the game clerk confirmed the set value. When the total of the period (the duration of confirmation of the set value) exceeds the minimum game time (4.1 seconds), the N + 1th game can start the rotation of the body without a weight period. On the other hand, if the total of the period in which the game before the set value is confirmed and the period in which the set value is confirmed is less than the minimum game time (4.1 seconds), the N + 1th game is performed. Rotation can be started after a weight period.

According to the management mode at the time of confirming the set value as described above, by continuing the measurement of the time related to the minimum game time, at the time of the above-mentioned returnable error (see FIG. 50 (B)) and at the time of medal clearing (Fig. As in the case of 51 (B)) and when the medal is inserted (see FIG. 52 (A)), the game machine can be controlled without hindering the passage of the minimum game time as much as possible. Further, the time related to the minimum gaming time can be counted regardless of the state of the gaming machine (slot machine 10 in this case) or the gaming state. Then, the game can proceed smoothly, and it is possible to secure the maximum number of games per predetermined time (for example, the game time by one player or the business hours for one day of the game field). Become.
<< Processing mode during measurement of time related to minimum game time >>

Next, another aspect of the minimum game time management in the slot machine 10 of this embodiment will be described. First, in this embodiment, a process not related to the minimum game time is not performed between the determination of the passage of time related to the minimum game time after the start of the next game and the process of the minimum game time set. ..

That is, for example, using the normal time shown in FIG. 50 (A) as an example, in the Nth game as described above, the measurement result of the time related to the minimum game time set at the start of the rotation of the rotating cylinder is the timing. Starting from T1, until the timing T2 when the measured value becomes 0 arrives, the rotation of the rotating cylinder related to the N + 1th game cannot be started. Then, until the measurement result of the time related to the minimum game time becomes 0 or less, it is checked whether the measurement result of the time related to the minimum game time becomes 0 or less (whether the minimum game time has elapsed) (whether or not the minimum game time has elapsed). The process of determination related to (progress check) loops.

As described above, the loop process related to the elapse check of the minimum game time can be performed during the above-mentioned rotating cylinder rotation start standby process used in the game progress main process (see FIG. 14). Further, the process of checking the passage of time related to the minimum game time loops until the measurement result becomes 0 or less, and when the measurement result becomes 0 or less, the loop of the process related to the progress check ends (S521). Then, in this embodiment, other processes are not executed from the start of the process related to the progress check until the measurement result becomes 0 or less and the loop ends.

Then, if it is determined by the process related to the progress check of the minimum game time that the measurement result is 0 or less, the value of the minimum game time related to the N + 1th game (next game) is set as described above. During the game progress main process (see FIG. 14), the rotation start standby process is set in the area of the minimum game time timer in the RWM (S522), and the rotation start of the rotation is possible. Further, when the minimum game time set here elapses, the rotation of the rotating cylinder in the N + 2nd game can be started.

Here, in the above-mentioned "after the start of the next game" in the management mode related to the minimum game time, more specifically, in the game progress main process (see FIG. 14) related to the N + 1th game, the rotation of the cylinder is It can be said that it was after the start (S51). Further, it can be said that the above-mentioned "minimum game time lapse determination" is to check the lapse of time related to the minimum game time after the start of rotation of the rotating cylinder during the N + 1th game while repeating the loop process. .. Further, it can be said that the above-mentioned "processing of the minimum game time set" is a process of setting the value of the minimum game time in the RWM at the start of the second N + second rotation of the rotating cylinder.

Considering these relationships as the starting point of the Nth game, in the game progress main process (see FIG. 14) related to the Nth game, the minimum game is performed after the rotation of the body is started (S51). Processing that is not related to the minimum game time until the time is set, the progress check of the minimum game time is performed by loop processing, and the value of the minimum game time is set in RWM at the start of the N + 1th rotation of the cylinder. It can also be said that it is something that is not done.

Further, it is conceivable that power interruption occurs even during the measurement of the minimum game time as described above, but the power supply cut processing related to the power interruption in this case is changed to "processing not related to the minimum game time". Can be not applicable.

According to such a management mode of the minimum game time, it is possible to measure the time related to the minimum game time without interruption as much as possible. Then, the time related to the minimum game time can be counted accurately and quickly by the continuous measurement. Also, by this, it is possible to prevent the period during which the game cannot be progressed from increasing beyond the predetermined time (4.1 seconds), and as much as possible even under the limit of the minimum game time. The number of games can be secured.
<< Management mode related to the relationship with the test signal output >>

Next, a management mode of the minimum game time related to the relationship with the test signal output described above will be described. In this embodiment, the test signal output process (S762) is executed in the error management process (see FIG. 20) related to the timer interrupt process (see FIG. 18), and the test signal output process is executed for each timer interrupt process. .. Further, as described above, in the test signal output process (S762), a process of outputting the test signal to a predetermined output port is performed.

Further, the output of the test signal is performed using one or a plurality of pulses, and the first output timing of the pulse representing the output content is determined based on the measurement result of the test signal output timer that measures the timing of the test signal output. Will be done. Then, every time the measurement result of the test signal output timer reaches a predetermined time (4.1 seconds or more in this case), the output of the test signal is started. Here, the content of the test signal includes one represented by one pulse (singular pulse) and one represented by a plurality of pulses (multiple pulses), but the timing of starting the pulse output is the pulse. It will be the same regardless of the number.

Further, in the present embodiment, the above-mentioned test signal output timer is set immediately after the above-mentioned minimum game time timer is set. That is, in the present embodiment, as described above, the minimum game time timer is set during the rotation start standby process related to the game progress main process (see FIG. 14), but the test signal output timer is set. Is executed as the next process of the set of the minimum game time timer without any other process. Therefore, the setting of the minimum game time, the test signal output, the end of the minimum game time, and the context of the next test signal output are always kept constant.

Further, FIG. 53 shows the relationship between the measurement period of the time related to the minimum game time and the test signal output start timing by a timing chart. In FIG. 53, "measurement start" represents the timing of measurement start of the time related to the minimum game time, and "measurement end" in the figure is from "measurement start" of the time related to the minimum game time. It represents the timing of measurement after 1 second has passed. Further, "test signal output start" in the figure indicates the timing at which the above-mentioned test signal output is started.

Here, the test signal includes a plurality of pulses and a single pulse as described above, and the timing of ending the test signal output differs depending on the number of pulses and the like. Therefore, in FIG. 53, an example of the plurality of pulses is shown. And an example of a single pulse are shown, and the description of the timing of stopping the test signal output is omitted.

As described above, in the present embodiment, the set of the test signal output timer is executed as the next process of the set of the minimum game time timer without any other process. Therefore, as shown in FIG. 53, the start timing of the test signal output is immediately after the measurement start timing of the time related to the minimum game time. Then, in the test stage, by confirming that the time interval between the start timing of the test signal output at one time and the start timing of the next test signal output is 4.1 seconds or more, it is 4.1 seconds. It is possible to estimate that the minimum game time is guaranteed.

As described above, in the present embodiment, the measurement start timing of the test signal output timer is generated at intervals of the minimum game time (4.1 seconds) or more. Therefore, in the test stage where the test signal is monitored, the interval between the output start timing of the test signal output first and the output start timing of the test signal output after that (test signal output start interval) is set. If it is possible to monitor and confirm that the start interval for the test signal output before and after is secured for 4.1 seconds or more, this indirectly guarantees the minimum game time of 4.1 seconds. You can confirm that you are there.
<< Management mode related to the relationship with the power failure judgment >>

Next, a management mode of the minimum game time related to the above-mentioned power off processing (see S543 in FIG. 18 and FIG. 19) will be described. In this embodiment, as described above, the power interruption determination is performed by the power interruption processing (S543) in the timer interrupt processing (see FIG. 18) and the determination of the presence or absence of the power interruption detection signal (S561 in FIG. 19). As described above, in the determination of the presence / absence of the power failure detection signal (S561), when the power failure detection signal is detected (S561: YES), the subsequent processing (see FIG. 19) is executed.

If the power off detection signal is not detected (S561: NO), the power off processing is terminated and the interrupt counter value update processing (S544 in FIG. 18) is executed. In this interrupt counter value update process (S544), the timer interrupt is generated by updating the value in a predetermined range (here, "0" to "255") by "1" for each timer interrupt process. It is possible to confirm that it has occurred. After that, as described above, the timer measurement process (S551) related to the measurement of the time related to the minimum game time is performed.

That is, in this embodiment, the timer measurement process (S551) is executed as a process after the power cutoff process (S543) in the timer interrupt process (see FIG. 18) as in the power supply cutoff process (S543). Then, the power failure determination is performed before the subtraction of the minimum game time timer. Therefore, it is possible to prevent the time subtracted in the timer interrupt processing at that time from being not used for the game due to the power interruption generated after the subtraction of the minimum game time timer, and the minimum game time is ensured only by the game time. Can be secured to. The counting mode of the timer is not limited to the one that performs subtraction (countdown), and may be, for example, one that performs addition (countup).
<< Relationship between payout of game medals and weight period >>

Next, the relationship between the payout of game medals and the weight period will be described. First, in the slot machine 10 of the present embodiment, a display determination is made at the end of the game (S66 in FIG. 14), and the symbol combination corresponding to the predetermined combination to be paid out the game medal (with a payout) is stopped. If it is displayed, the number of game medals corresponding to the payout is paid out (S67). Then, these processes are executed even during the weight period. Therefore, even if the start lever 25 is operated after the bet is set and the rotation of the rotating cylinders 51L to 51R is not started, the game medal may be paid out.

The present invention is not limited to the above-described embodiments, and various modifications can be made. For example, it is set at the time of normal or returnable error shown in FIGS. 50 (A) and 50 (B), at the time of clearing the game medal shown in FIG. 51 (B), and at the time of inserting the game medal shown in FIGS. Not only when the value is confirmed, but also in other situations, the measurement of the time related to the minimum game time may be continued without being stopped.
<Correspondence to non-regular operation in setting change work>

Next, while the setting is being changed using the setting unit 62 (see FIG. 4), a non-regular operation (non-regular operation) is performed, and a situation such as a power failure (power failure) or an error occurs. The measures to be taken when it occurs will be described. In the following, first, the procedure for changing the normal setting in the slot machine 10 of this embodiment and the processing mode of the setting value data (setting value data) will be described, and then the non-normal operation related to the setting change. A specific example of the above, and various correspondence patterns when a power failure or an error occurs during setting change due to non-regular operation will be described.
<< Procedure for changing regular settings >>

In the slot machine 10 of this embodiment, the normal operation for changing the setting of the setting unit 62 (see FIG. 4) described above is performed as follows. First, for example, a game hall clerk or the like opens the front door portion 11 of the slot machine 10 in the power-off state (see FIGS. 1 and 2). When opening the front door portion 11, a predetermined key is inserted into the lock portion 23 (see FIG. 1) of the front door portion 11 locked in the closed state, and the key is unlocked in the unlocking direction. Rotate (eg counterclockwise).

Further, the setting door provided in the setting unit 62 shown in FIG. 4 is opened so that the setting key cylinder into which the setting key is inserted can be accessed, although not shown. Further, the setting key is inserted into the setting key cylinder, and the setting key is rotated (ON operation) in the ON direction (for example, clockwise direction). Then, the power switch 72 described above is turned on to supply power to the slot machine 10.

Since both the front door portion 11 and the setting door (not shown) are in the open state when the power is turned on, both the above-mentioned door switch 60 and the setting door switch 67 are turned on. Further, since the setting key is rotated in the ON direction, the setting key switch 68 is also turned ON. The door switch 60, the setting door switch 67, and the setting key switch 68 constitute a designated switch (see S9 in FIG. 12) as described above. Therefore, an affirmative determination is performed in the determination process (S9) of whether or not the designated switch is ON in the process when the power is turned on (see FIG. 12) (S9: YES).

Then, when an affirmative determination is made in the above-mentioned determination process (S9), the operation start state is set so that the setting change device process (see FIG. 13) can be executed by satisfying other conditions. In this embodiment, such a state is referred to as a state of "setting change device operation". As for the above-mentioned "other conditions" that enable the execution of the setting change device process, in this embodiment, the power off / return data is abnormal (S10: YES), or the setting change impossibility flag is ON. It is not (S11: NO).

Further, as described above, when power is supplied to the slot machine 10, the set value is displayed on the above-mentioned setting display LED 66 mounted on the main control board 61 (see FIG. 4). A so-called 7-segment display is used for the setting display LED 66. Further, in the present embodiment, the setting display LED 66 displays any one of the setting values (here, six of "1" to "6") which are integer values in a predetermined range, and the displayed setting. The value becomes visible through the transparent main board case 65.

Here, the setting value displayed on the setting display LED 66 when the setting is changed is a setting value that has been fixed at the time of the latest power off after the normal setting change operation. Further, as described for the setting change device processing (see FIG. 13) described above, at the start of the setting change, the set value data indicates a value within a normal predetermined range (here, “1” to “6”). If not (S29: NO), the displayed set value is "1", which has the lowest degree of advantage for the player.

When the above-mentioned setting / reset button 69 (see FIG. 4) is pressed in the above-described setting changing device operation status, the display of the set value changes. In this embodiment, each time the setting / reset button 69 is pressed, the display of the set value is incremented by one step. For example, when the power of the slot machine 10 is turned on with the setting 1 (the setting value is 1) and the setting / reset button 69 is operated once, the setting 2 is obtained. After that, each time the setting / reset button 69 is pressed, the display of the set value changes in ascending order to "2", "3", ....

Further, when the setting / reset button 69 is operated once with the setting value 6 which is the maximum setting value, the setting 1 which is the minimum setting value is obtained. Then, in a situation where the value displayed on the setting display LED 66 is the set value to be selected, a game clerk or the like operates the above-mentioned start lever 25 (see FIG. 1) to press the start switch (not shown). By turning it on, the set value is fixed.

As described above, the mode of change related to the display of the set value when the setting / reset button 69 is pressed is not limited to the one in which the display of the set value is incremented step by step, for example, the display of the set value. May be decremented step by step and change in descending order. Further, the range of the set value that can be changed by the setting change device process (see FIG. 13) is not limited to the 6 stages of "1" to "6", and is, for example, 4 stages of "1" to "4". You may.

Subsequently, the setting key is rotated in the OFF direction (for example, counterclockwise direction) (OFF operation), the setting door provided in the setting unit 62 is closed, the normal setting change operation is completed, and the game is possible. (Normal state).

Further, in this embodiment, the situation after the above-mentioned "setting change device operation" situation is reached and the setting / reset button 69 operation is enabled is defined as the "setting value changeable" situation. Refer to. This "setting value can be changed" is a situation in which the setting value can be changed (selected) by operating the setting / reset button 69.

Further, in this embodiment, the state in which the set value is confirmed by the operation of the start lever 25 (lever operation) after "the set value can be changed" is referred to as the "set value determination" situation. Then, when the set value is changed, the setting / reset button 69 is operated as described above in "setting value can be changed", and the start lever 25 is operated in a state where the target set value is reached. Then, the status of "setting value confirmed" is reached. Then, in the "set value confirmed" situation, the display of the set value does not change even if the setting / reset button 69 is operated.

Further, in this embodiment, the state of waiting for the setting key to be turned off after the above-mentioned "setting value determination" is referred to as a "setting value determination waiting" situation. Even in this "waiting for determination of set value" situation, it is impossible to change the set value by operating the setting / reset button 69. Further, in this embodiment, the state in the setting change work (the state related to the setting change in the setting unit 62) can be divided into a first state and a second state. Then, when the power is turned on while the setting key is turned on, the state shifts to the first state, and when the start lever 25 is operated thereafter, the state shifts from the first state to the second state. Further, when the setting key is turned off in this second state, the second state ends.

As the display mode of the set value in the above-mentioned situations such as "setting value can be changed", "set value confirmed", and "waiting for setting value determination", the setting value is turned on, blinks repeatedly, or the set value is displayed. An example of a dot display on the side (near the lower right) can be exemplified. Then, it is possible to make the display mode of the set value in each situation different from the display mode of the setting in other situations so that it is possible to distinguish which situation it is in.

Further, as the display mode of the set value after "determination of the set value", it is possible to display a number other than the number representing the set value. Further, as the display other than the number representing the set value, an integer value (for example, "0") outside the range of the settable value, a predetermined character, a figure, a symbol other than the number, and the like can be exemplified. Furthermore, after the operation of the setting / reset button 69 is started, a display mode is adopted in which the same numbers, characters, figures, symbols, etc. other than the numbers indicating the set values are continuously displayed no matter how many times the selection operation is performed. It is possible. Further, it is also possible to adopt a display mode in which a number other than the number indicating the set value is changed each time the setting / reset button 69 is operated.

After that, in the above-mentioned "waiting for setting value determination" situation, by rotating (OFF operation) the setting key in the OFF direction (for example, counterclockwise direction) and returning it, the operation of the changing device is completed, which is normal. The situation is such that the game can be started (sometimes referred to as "normal state" or "normal game state"). In this "normal state", the state of changing the setting has already been completed, and the setting value is not displayed on the setting display LED 66 or the display indicating that the setting is being changed is not performed. ing.
<< Data processing mode related to setting change >>

Next, the setting value data and other data processing modes when the setting change operation is performed will be described. First, the set value data immediately after the power is turned on is backed up when the power is turned off most recently and becomes effective when the power is turned on. That is, when the power is turned off, the set value data at that time is stored in a predetermined area in the RWM area that is the target of data backup. Here, the RWM area to be backed up can be referred to as, for example, a "power failure storage means" or a "power failure storage area", and in particular, a power failure in which set value data is stored. The time storage area can be referred to as a "power-off storage area for set value data".

Then, at the time of the subsequent power failure recovery (when the power supply is cut off), the backed up setting value data is used as the setting value data related to the setting value (operation start value) at the start of operation of the slot machine 10, and the power is cut off. The return is performed. The above-mentioned operation start value is stored in a part of the storage area in the power failure storage area to be backed up. As described above, among the set value data, the power failure storage area for the set value data which is the operation start value can be referred to as the “operation start value storage area”.

Further, in the period from when the power is turned on until the first operation of the setting / reset button 69 is performed (the period before the start of selecting the setting value), the setting value is displayed on the setting display LED 66 by the above-mentioned operation. The set value data stored in the start value storage area is referenced.

Further, after the setting / reset button 69 is operated to start the selection of the set value, the set value data related to the selected set value (selected set value) is stored in the predetermined temporary storage means of the main control board 61. It is stored in a storage area (a predetermined temporary storage area). Then, in displaying the set value on the setting display LED 66 after the start of selection, the set value data (set value data related to the selected set value) stored in the predetermined temporary storage area is referred to.

Here, examples of the above-mentioned "predetermined temporary storage means" and "predetermined temporary storage area" include a predetermined area of the RWM and a predetermined register. The "predetermined temporary storage means" and "predetermined temporary storage area" can be referred to as, for example, "set value temporary storage means" or "set value temporary storage area".

Further, as described above, when displaying the set value on the setting display LED 66 during the setting change work, various processing modes related to the reference of the setting value data can be adopted. First, as the first processing mode, an example may be exemplified in which the above-mentioned set value temporary storage area is provided as an RWM area for temporarily storing the set value data (here, referred to as a “temporary storage RWM area”). Then, the set value data is read directly from the temporary storage RWM area, and the numerical value indicated by the set value data is displayed on the setting display LED 66.

Further, as a second processing mode relating to the reference of the set value data, for example, both a register and the above-mentioned temporary storage RWM area are provided as the set value temporary storage area, and the set value of the temporary storage RWM area is stored in the register. Later, it can be illustrated that the set value is displayed by referring to the register. Further, as the third processing mode, even if a register serving as a temporary storage area is provided, the setting value data can be directly read from the temporary storage RWM area as in the first mode described above.

Here, in this embodiment, the first processing mode relating to the reference of the above-mentioned set value data is adopted. Further, the present invention is not limited to this, and the above-mentioned second processing mode and third processing mode can be adopted. For example, when the second processing mode is adopted, the setting / reset button 69 is operated to set a set value. Each time the selection is made, the set value data can be transferred from the temporary storage RWM area to the register, and the set value can be displayed on the setting display LED 66.

Further, in this embodiment, as other data related to the setting change, data indicating the state of the setting key (setting key state data) can be mentioned. Examples of the setting key state data include data acquired based on the monitoring result by monitoring a signal indicating the state of the setting key, and data of a flag indicating the state of the setting key.

Further, among these, as the data acquired based on the monitoring result of the signal indicating the state of the setting key, the signal level (ON level or OFF level) is determined, and the data acquired based on this signal level is exemplified. it can.

Further, unlike this, the edge when the signal indicating the state of the setting key changes from OFF to ON is acquired as the setting key state data indicating the change to ON, and the signal indicating the state of the setting key is obtained. It is conceivable to acquire the edge when changing from ON to OFF as setting key state data indicating the change to OFF.

Further, when the setting change work is completed, the state of the setting key is switched from ON to OFF as described above, so that the setting value data held in the above-mentioned temporary storage area of the setting value (setting related to the selected value) is completed. The value data) is written to the above-mentioned power failure storage area to be backed up. In this embodiment, the set value data at the end of the setting change work is stored in the operation start value storage area described above. Further, the setting value data at the start of the setting change work at that time is stored in the operation start value storage area before the setting value data at the end of the setting change work is written and overwritten. Here, the data stored in the power failure storage area may be directly acquired from the power failure storage area at the time of subsequent power failure recovery, or may be temporarily stored in a predetermined storage area at the time of power failure recovery. It may be acquired after being stored.

Further, in this embodiment, the set value data at the beginning of the setting change work when the power is turned on in the state where the setting key is turned on and the state shifts to the above-mentioned first state is referred to as "first set value data". The set value data related to the set value selected in the first state can be referred to as "second set value data". Further, the set value data when the start lever 25 is operated to shift from the first state to the above-mentioned second state is referred to as "third set value data", and the above-mentioned first set value data and second set value data are used. It is possible to distinguish from. Then, from these first set value data to the third set value data, when a non-regular operation as described later is performed, the above-mentioned electric power is used at a predetermined timing according to various corresponding patterns also described later. It is possible to store in the break storage area. Further, it is also possible to use the second set value data or the third set value data as the set value data at the beginning of the setting change work according to various corresponding patterns.
<< Specific example of non-regular operation related to setting change >>

Next, a non-regular operation (non-regular operation) related to the setting change will be described. First, as non-regular operations that can be performed during the setting change, it is possible to exemplify turning off the power during the setting change, inserting a game medal during the setting change, and causing the game medal to stay. Then, due to these non-regular operations, a process related to power failure and a process related to an error are executed.

In addition, among these emergency situations, it is assumed that the power failure during the setting change is mistakenly performed by a game hall clerk or the like, or intentionally performed by a fraudulent person. In addition to the above-mentioned human operations, there are also power outages that occur without human intervention, such as power outages and momentary power outages. There are also two types of power supply recovery (also referred to as power failure recovery and power recovery), one is by human operation and the other is automatic by recovering the power supply after a power failure or a momentary power failure.

In addition, the timing of the power failure during the setting change is the timing before or after the selection of the set value by the operation of the setting / reset button 69, or after the start lever operation after the selection of the set value (after the setting value is confirmed). ) Timing can be illustrated. Further, when the power is turned on after the power is cut off, it can be assumed that the power is turned on with the setting key turned on, or the power is turned on after the setting key is turned off.

Further, as the error during the setting change, more specifically, the above-mentioned error related to the insertion of the game medal (CP error, C0 error, C1 error, CH error, and CE error) and the payout of the technique medal. Such errors (HE error, HP error, HQ error, and FE error) can be exemplified. In addition to this, communication errors between the main control board 61 and the sub control board 31 and random number abnormalities can be mentioned.
<< First response when power failure occurs (Pattern 1 related to power failure when the setting key is ON) >>

Subsequently, various patterns will be described for dealing with the above-mentioned emergency situation during the setting change work. In the following, first, regarding the first response when a power failure occurs during the setting change (hereinafter, referred to as "pattern 1 related to power failure" or "pattern 1 related to power failure when the setting key is ON"). This will be described with reference to FIG. 54 (a). The pattern 1 related to this power failure returns the state of the set value to the state at the start of the setting change work when the power failure is restored. Further, in the pattern 1 related to the power failure, if the setting key is ON, the set value data at the time of recovery from the power failure will be the same even if the situation at the time of the power failure is different.

Further, (a1) and (a2) in FIG. 54 (a) show the pattern 1 related to the power failure in separate charts based on the difference in the situation at the time of the power failure. Of these, FIG. 54 (a1) shows a case where a power failure occurs without an operation of confirming the set value by operating the start lever (hereinafter, referred to as “no setting value confirmed”), and FIG. 54 (a2). ) Indicates a case where a power failure occurs while the set value is confirmed by operating the start lever (hereinafter, referred to as “set value confirmed”). Further, the pattern 1 related to this power interruption is adopted in the slot machine 10 of this embodiment.

Further, FIGS. 54 (a1) and 54 (a2) show various situations in the work of changing the settings from the upper row to the lower row in the order of occurrence (see the "order" column and the "situation" column). Further, in FIGS. 54 (a1) and 54 (a2), the ON / OFF state of the setting key in each situation (orders 1 to 7) is shown in the "setting key" column, and the "setting value" is shown. In the column of, the setting value data in each situation is shown. Further, the "setting value display" column in the figure shows the display contents of the setting display LED 66 in each situation, and the "stack contents" column described at the right end in the figure shows each of them. In the situation, the return destination address (return destination data) stored in the stack pointer is shown.

When the setting change work is performed, as shown at the top of the "Status" column in FIG. 54 (a1), the slot machine 10 is powered on (order 1), and the "setting key" on the right side of the figure is turned on. As shown in the column, the state of the setting key at this time is ON. Further, in FIG. 54 (a1), the "set value" described as "a" is the set value at the time of the latest power failure, and the "set value" is set according to the set value at the time of the power failure. Indicates that the contents of "" are different. That is, the "power-on" in order 1 is the power-on performed after the power is turned off after the work of changing the settings is completed by the regular procedure, and the "set value" at the time of this power-on is the above. It is a set value (one of "1" to "6") backed up when the power is turned off.

In addition, the display content of the setting display LED 66 shown in the "setting display" column is blank at this stage because the power has just been turned on for the setting change and the display has not started yet. Indicates that there is no such thing. Further, the fact that the "stack content" is "n" indicates that non-constant return destination data is stored in the stack pointer according to the situation at the time of the previous power failure.

After such a power-on situation, the above-mentioned "setting change device operation" situation (order 2) is obtained. Then, in this "setting change device operation", as shown in FIG. 54 (a1), the "setting key", the "setting value", and the "stack content" indicate the "power on" status (order 1). ) No change. However, the "setting display" which is the display content of the setting display LED 66 becomes "a" based on the setting value data.

Subsequently, when the status of "setting value can be changed" (order 3) is reached, the "setting key" remains ON, but when the setting / reset button 69 is operated, FIG. 54 (a1) ), The "set value" changes to "b", which is a new selected value, unlike the previous "a". Further, the "setting display" is also "b" corresponding to the "setting value", and the "stack content" remains "n".

Then, in the case of "setting value not confirmed" shown in FIG. 54 (a1), when the power is cut off while "setting value can be changed" (order 4), the setting value data of "setting value" is "b". Until then, the "stack content" is the data of the return destination in the status (order 3) of the immediately preceding "setting value can be changed". That is, when a power failure occurs, the return destination address after the power failure is restored is set (saved) in the stack pointer (see S568 in FIG. 19). Then, in the example of FIG. 54 (a1), the return destination data related to "setting changeable" is set in the stack pointer, but in the figure, in order to indicate this, the "stack content" when the power is turned off is set. "," Order 3 "is described.

Further, as shown in FIG. 54 (a1), when the power is turned on while the setting key is ON (order 5), in the subsequent "setting change device operation" situation (order 6), the "set value" is set. "Returns to the same" a "as before the power failure occurred, and the" setting display "also becomes" a ". Further, even in the situation of "setting value can be changed" (order 7), "setting value" and "setting display" remain "a".

For example, in the situation of "setting change device operation" in order 2, it is possible to start blinking display of the set value on the setting display LED 66. Then, in this case, after the "power on" in the order 5 is performed and the "setting change device is activated" in the order 6, the setting value is blinked and displayed by the setting display LED 66, and the power is restored. Is possible.

Next, the case of “setting value confirmed” shown in FIG. 54 (a2) will be described. The same part as in the case where the set value is not fixed is not described as appropriate. When the set value is confirmed, the "set value can be changed" shown in the order 3 and then the "set value confirmed" shown in the order 4 are performed. At this time, there is no change in the "setting key", "setting value", and "setting display", and they are "ON", "b", and "b", respectively, as in the case of "setting value can be changed" in order 3. ..

Further, as shown in the order 5 in FIG. 54 (a2), the situation of the above-mentioned "waiting for setting value determination" is obtained, but the "setting key", "setting value", and "setting display" at this time also change. Is not, and remains "ON", "b", and "b", respectively. Then, when the power is cut off in this state (order 6), there is no change in the "setting key", "setting value", and "setting display". In addition, since the power failure occurred before the "setting key" was turned off, it means that the setting change work was not performed in the normal procedure. Therefore, the setting value data "b" at this time is It is not stored in the above-mentioned power failure storage area (here, the above-mentioned operation start value storage area). Then, "a" is still stored as the set value data in the power failure storage area.

Subsequently, when the power is turned on (order 7) and the status of "setting change device operation" (order 8) is reached, a power failure occurs before the "setting key" is turned off, and the selected setting value is reached. Since "b" is not stored in the storage area at the time of power failure and is not backed up, the "setting value" is "a" before the selection operation is performed, and the "setting display" is also based on the setting value data. It becomes "a".

That is, in the situation (order 5) of "waiting for setting value determination" after "setting value confirmation" shown in FIG. 54 (a2), if a power failure occurs while the "setting key" is ON, the "stack contents" is displayed. The return address is not set and the "stack content" remains empty. Then, when the power is turned on after that, the state of the setting key (which remains ON here) is referred to and the subsequent processing is executed, so that the state after the power failure is restored is "setting change device operation".

Here, for example, in the situation of "setting change device operation" in order 2, when the blinking display of the set value is started on the setting display LED 66 and the operation of "determine the set value" in order 4 is performed, the set value blinks. It is also possible to end the display and switch to the lighting display. Then, in this case, when the "power on" of the order 7 is performed and the "setting change device is activated" of the order 8, the setting value is blinked by the setting display LED 66 and the power is restored. Is possible.

Further, in the pattern 1 related to the power failure shown in FIG. 54 (a), either the case where the set value is not confirmed (see FIG. 54 (a1)) or the case where the set value is confirmed (see FIG. 54 (a2)). Although not shown, if the setting key is turned off when the setting change work is normally completed, the set value data is backed up from the above-mentioned temporary storage area (for example, a register) when the power is cut off. The data is transferred to a predetermined area of the storage area (here, the operation start value storage area).

As described above, in the pattern 1 related to the power failure, the correspondence when the power is cut off in the state where the setting key is not turned off after the setting value is selected by the operation of the setting / reset button 69 is defined. Further, in the pattern 1 related to the power failure, the data processing mode when the power failure occurs in the situation where the set value has not been confirmed and the data processing when the power failure occurs in the situation where the set value has been confirmed. Aspects are defined.

Then, in the pattern 1 related to this power failure, the selected setting is performed in both the case where the set value is not confirmed and the case where the set value is confirmed until the setting key is turned off after the set value is selected. The value is not written in the storage area at the time of power failure, and the selected set value is not inherited and the power is restored. Then, in the pattern 1 related to the power failure, the power failure recovery is performed using the set value data (operation start value) in the state of "setting change device operation" before the power failure occurs. Further, according to the pattern 1 related to this power failure, if the power is cut by an irregular procedure during the setting change, the set value data is not backed up.

From these facts, according to the pattern 1 relating to the power failure, when the power is cut off in the middle of the setting change work, the setting change work can be performed again from the same setting value data state. Further, it is possible to prevent the setting value from being changed when the setting change work is performed by a non-regular procedure other than the regular procedure related to the setting change as described above. Then, when the setting is changed by a procedure other than the normal procedure, it is possible to prevent an unexpected disadvantage from occurring by inheriting the set value data at the time of the power failure when the power failure is restored.

Here, as the work of changing the setting in a procedure other than the regular procedure, for example, a setting value having a high degree of advantage is selected, and the work is intentionally performed in the middle stage before the work in the regular procedure related to the setting change is completed. It is possible to exemplify a form of fraud such as turning the power off and then on again. Then, even if there is such a fraudulent act, according to the above-mentioned pattern 1 related to the power failure, the setting is prevented from being illegally changed by returning the selected setting value without inheriting the power failure. it can.

In pattern 1 related to power failure, the set value is selected by the setting / reset button 69 and the set value is confirmed by the start lever 25, but the present invention is not limited to this, and the reset button is used, for example. A dedicated setting button may be provided to select the set value instead of the combined use of. Further, for example, the set value may be determined by using other existing buttons such as a button provided on the sub input unit 27 (see FIG. 1). Further, a dedicated button for determining the set value may be provided in the housing portion 12, for example, in the setting unit 62.

Further, in the above-mentioned pattern 1 related to the power failure, the processing at the time of recovery from the power failure is performed using the data of the "stack contents" (for example, when the set value is not fixed as shown in FIG. 54 (a1)). Not limited to this, it is also possible to perform processing at the time of power failure recovery without using the data of "stack contents". Then, as a processing mode for performing the processing at the time of recovery from power failure without using the data of "stack contents", a state setting mode using a predetermined flag can be considered.

Further, as a mode of state setting using the above-mentioned predetermined flag, for example, when the setting key is turned on and the power is turned on, the "setting change flag" is turned on and the setting key is switched off while the power is turned on. As a result, the above-mentioned "setting change flag" is turned off, but even if the setting key is turned off during the power failure, the setting change flag remains on. When such a state setting mode is adopted, the state after the power failure is restored can be set by referring to the setting change flag, and if the setting change flag is ON, even if the setting key is OFF, even if the setting key is OFF. It is possible to execute the subsequent processing in the setting change state (the state in which the change of the setting value made in advance is effective).
<< Second response when power failure occurs (Pattern 2 related to power failure when the setting key is ON) >>

Next, as another embodiment of the response pattern related to the occurrence of power failure, the second response when the power failure occurs during the setting change (hereinafter, "pattern 2 related to power failure" or "electricity when the setting key is ON" A pattern 2 related to disconnection) will be described with reference to FIG. 54 (b). The same parts as those of the above-mentioned pattern 1 (see FIG. 54 (a)) related to the above-mentioned power failure are shown in the same manner, and the description of the overlapping parts will be omitted as appropriate.

In pattern 2 related to this power failure, if a power failure occurs in a situation where the set value is not confirmed while "setting value can be changed", the power failure is restored as in pattern 1 related to the above-mentioned power failure. Occasionally, the state of the set value is returned to the state at the time of the power failure. However, if a power failure occurs in a situation where the set value is confirmed while "the set value can be changed", unlike the pattern 1 related to the above-mentioned power failure, the state of the set value is changed to the power when the power failure is restored. It will be the state at the time of disconnection.

That is, (b1) in FIG. 54 (b) shows the case where the power failure occurs without the operation of confirming the set value by the start lever operation, as in FIG. 54 (a1) of the pattern 1 related to the power failure. Correspondence is shown, and FIG. 54 (b2) shows a case where the power failure occurs in a state where the set value is confirmed by the start lever operation, as in FIG. 54 (a2) of the pattern 1 related to the power failure. It shows the correspondence.

Then, when the set value is not fixed in the pattern 2 related to the power failure, as shown in FIG. 54 (b1), the set value selection operation is performed while "the set value can be changed", and the set value "b" is performed. "Is selected and the power is cut off when there is no operation to confirm the set value (order 4), the set value data of the" set value "at this time is the selection operation as in the case of pattern 1 related to the power cut. It is the later value "b". Further, the "stack content" is the return destination data indicating the status (order 3) of the immediately preceding "setting value can be changed". However, the set value data "b" at this time is still stored in the temporary storage area and is not stored in the power failure storage area, and the set value data in the power failure storage area starts the setting change work. It remains the "a" of time.

Further, when the power is turned on while the setting key is ON (order 5), in the subsequent "setting change device operation" situation (order 6), the "set value" is the setting of the storage area at the time of power failure. Based on the value data, it returns to the same "a" as before the power failure, and the "setting display" also becomes "a". Further, even in the status of "setting change device operation" (order 7), the "setting value" and the "setting display" remain "a".

On the other hand, in the case where the set value of the pattern 2 related to the power failure is confirmed (see FIG. 54 (b2)), the “set value can be changed” shown in the order 3 is followed by the “set value confirmed” shown in the order 4. Will be done. At this time, there is no change in the "setting key", "setting value", and "setting display", and they are "ON", "b", and "b", respectively, as in "setting value can be changed". However, based on the fact that the "set value is confirmed", the set value data "b" at this time is also stored in the power failure storage area, and the set value data in the power failure storage area is used for setting change work. It becomes the selected "b" after the start of.

Further, as shown in the order 5 in the figure, the above-mentioned "waiting for setting value determination" situation occurs, but there is no change in the "setting key", "setting value", and "setting display" at this time, respectively. It remains "ON", "b", and "b". Then, when the power is cut off in this state (order 6), the "setting key", "setting value", and "setting display" do not change, but when the power is turned on after that (order 7), the above-mentioned power is turned on. Unlike the pattern 1 related to disconnection (see FIG. 54 (a2)), both the “set value” and the “setting display” are “b”.

That is, in the pattern 2 related to this power failure, when the set value is confirmed by operating the start lever or the like, the set value data held in the predetermined temporary storage area is the backup target at the time of the power failure. It is written in a predetermined area of the storage area (storage area at the time of power failure for set value data). Then, the set value data is backed up when a power failure occurs (order 6), and is restored when the power is turned on (order 7) thereafter. Then, in the situation of "setting change device operation" (order 8), the "setting value" and the "setting display" become "b" based on the restored setting value data. It should be noted that the power failure storage area for the set value data when the set value confirmation operation is performed as described above can also be referred to as a “power failure storage area for the fixed set value data”. ..

According to the pattern 2 related to the power failure as described above, when the work of changing the setting is performed by a non-regular procedure for generating the power failure before the set value is confirmed, the pattern 1 related to the above-mentioned power failure (Pattern 1 related to the power failure described above Similar to FIG. 54 (a)), the power failure recovery is performed without inheriting the set value data. On the other hand, when the set value is confirmed, the set value data is inherited, and the power failure recovery is performed based on the set value data in the situation where the set value confirmation operation is performed.

Therefore, when a power failure occurs in a situation where the set value has not been determined (see FIG. 54 (b1)), the same action and effect as in the above-mentioned pattern 1 can be obtained, and when the power failure is restored, the power is generated. By inheriting the set value data at the time of disconnection, it is possible to prevent unexpected disadvantages from occurring. If a power failure occurs in a situation where the set value is confirmed (see FIG. 54 (b2)), the power failure occurs even if the remaining work such as setting key OFF related to the setting change is not completed. It is possible to finish the setting change at times, and the setting change work can be simplified as compared with the case where the setting value is not fixed as shown in FIG. 54 (b1), for example.

In other words, when the set value is not confirmed (see FIG. 54 (b1)), the set value changed before the power failure is not inherited after the power failure, so the setting change work is often repeated after the power is turned on. Therefore, the setting change work may become complicated. However, as in the case where the set value is confirmed as shown in FIG. 54 (b2), the set value is inherited even if the setting change work is not completed, so that the work until the set value is confirmed after the power is turned on can be omitted. It is possible to simplify the work of changing settings.

In the pattern 2 related to power failure, when the operation of determining the set value is performed, the set value data is stored in the storage area at the time of power failure, but the present invention is not limited to this. For example, whether or not the setting value confirmation operation has been performed is indicated by predetermined data (setting value confirmation data), and this setting value confirmation data is set as a backup target each time the setting value confirmation operation is performed. It is possible to store in a predetermined area (the storage area at the time of power failure for the set value confirmation data) of the storage area at the time of power failure.

Further, as a power failure storage area for the set value data, it is possible to provide an area (selected value storage area) for storing the set value data selected each time the set value selection operation is performed. Then, it is determined whether or not the set value confirmed data is stored at the time of recovery from the power failure, and if the set value confirmed data is not stored, the set value stored in the operation start value storage area as described above. It is possible to adopt a process such as performing a power failure recovery using the data and performing a power failure recovery using the set value data of the above-mentioned selection value storage area when the set value confirmation data is stored. Is. Further, the above-mentioned set value confirmation data may be a set value confirmation flag.
<< Third response when a power failure occurs (Pattern 3 related to power failure when the setting key is ON) >>

Next, as another embodiment of the response pattern related to the occurrence of power failure, the third response when a power failure occurs during the setting change (hereinafter, "pattern 3 related to power failure" or "electricity when the setting key is ON" A pattern 3 related to disconnection) will be described with reference to FIG. 54 (c). The same parts as those of the above-mentioned pattern 1 (see FIG. 54 (a)) related to the above-mentioned power failure are shown in the same manner, and the description of the overlapping parts will be omitted as appropriate.

(C1) in FIG. 54 (c) shows the response when a power failure occurs without the operation of confirming the set value, and (c2) in FIG. 54 (c) shows the response when the set value is confirmed. It shows the response when a power failure occurs while there is an operation. In the pattern 3 related to this power failure, as shown in FIG. 54 (c1), when a power failure occurs in the "setting changeable" situation (order 4), when the power is turned on (order 5), the "setting" is performed. The "value" and "setting display" are "b". Then, even in the subsequent "setting change device operation" and "setting value changeable", the "set value" and "setting display" are maintained as "b".

That is, in the pattern 3 related to this power failure, unlike the various patterns described above, the set value data is set every time the set value is selected even in a situation where the set value is not fixed by operating the start lever or the like. Is written from the temporary storage area to the above-mentioned power failure storage area. Then, the set value data is saved when a power failure occurs (order 4), and is restored and referenced when the power is turned on (order 5) thereafter.

Further, even in the status of "setting change device operation" (order 6) and the status of "setting value changeable" (order 7), the "setting value" and "setting display" are based on the restored setting value data. It becomes "b". Here, in the case where the set value is confirmed in the pattern 3 related to the power interruption (see FIG. 54 (c2)), the “set value is confirmed” in the above-mentioned pattern 2 related to the power interruption shown in FIG. 54 (b2). It is the same as the case of.

According to the pattern 3 related to the power interruption as described above, the set value data is inherited both before the set value is confirmed and after the set value is confirmed, and the power is restored based on the set value data. Therefore, regardless of whether or not the set value is fixed, the setting change can be completed when the power failure occurs without completing the remaining work such as setting key OFF related to the setting change. Then, the setting change work can be further simplified as compared with the pattern 2 related to the power failure.

Further, according to the pattern 3 related to this power failure, the set value data is written to the power failure storage area to be backed up each time the set value is selected, so that the set value data is set in a temporary storage area such as a register, for example. It is not necessary to store the value data and transfer the set value data to the RWM to be backed up and write it when the set value is determined. Therefore, a temporary storage area for temporarily storing the set value data before being stored in the storage area at the time of power failure becomes unnecessary, and it is possible to reduce the memory capacity and the processing.

According to the pattern 3 related to this power failure, the setting value change work is completed without going through the two-step procedure of setting value selection and setting value confirmation, for example, without performing the setting value confirmation work. You will be able to let. Therefore, even in the procedure of the regular setting change work, it is possible to further reduce the work load on the person who performs the setting change work.
<< Fourth response when power failure occurs (Pattern 1 related to setting key OFF during power failure) >>

Next, as another correspondence form when a power failure occurs during the setting change work, a correspondence pattern when the setting key is turned off during the power failure is based on FIGS. 55 (a) to 55 (d2). explain. In the following, first, regarding the fourth response when a power failure occurs during the setting change (hereinafter, referred to as "pattern 4 related to power failure" or "pattern 1 related to setting key OFF during power failure"). This will be described with reference to FIG. 55 (a). The same parts as those of the above-mentioned corresponding patterns will be illustrated in the same manner, and the description of the overlapping parts will be omitted as appropriate.

In the pattern 4 related to the power failure shown in FIG. 55 (a) (pattern 1 related to the setting key OFF during the power failure), the order 1 to the order 4 are the above-mentioned power failure shown in FIG. 54 (a1). This is the same as the pattern 1 (pattern 1 related to power interruption when the setting key is ON). First, the slot machine 10 is powered on (order 1), and as shown in the "setting key" column on the right side of the figure, the state of the setting key at this time is ON. Further, the "set value" and the "stack content" at the time of turning on the power are "a" and "n" as in the above-mentioned pattern 1 related to the power failure (see FIG. 54 (a1)).

After the power-on status (order 1) described above, the status of "setting change device operation" (order 2) is set. The "setting key", "setting value", and "stack content" are the same as the "power on" status (order 1), but the "setting display" which is the display content of the setting display LED66. "Is" a "based on the set value data.

Subsequently, when the status of "setting value can be changed" (order 3) is reached, the "setting key" remains ON, but when the setting / reset button 69 is operated, FIG. 54 (a1) ), The "set value" changes to "b", which is different from the previous "a". Further, the "setting display" is also "b" corresponding to the "setting value", and the "stack content" remains "n".

Then, if the operation of confirming the set value is not performed and the power is cut off in the situation of "setting value can be changed" (order 4), the set value data of the "set value" remains "b", but " The "stack content" is the data whose return destination is the status (order 3) of the immediately preceding "setting value can be changed". Further, when the setting key is turned off and the power is turned on while the setting key is turned off as shown in order 5 in FIG. 55 (a), the "set value" at this time is "b" after the selection operation. , And the "stack content" returns to the data of the return destination address in the situation of order 3. Then, in the subsequent "setting change device operation" status (order 6), the setting key remains OFF, and the "setting value" and "setting display" are in the order 3 "setting change device operation". Similarly, both are "b".

That is, in the pattern 4 related to this power failure, even in a situation where there is no operation for confirming the set value, each time the set value is selected, the set value data of the "set value" and the return destination of the "stack content" are returned. The data is written to the above-mentioned power failure storage area. Then, the set value data and the return destination data are saved when a power failure occurs (order 4), and when the power is turned on thereafter (order 5), a determination process of whether or not the setting key is OFF is executed. , The set value data and the return destination data are restored on condition that the setting key is OFF.

Further, in order to recognize that the setting change work is in progress even if the setting key is OFF when the power is turned on, for example, it is possible to use the return destination data of the "stack contents" when the power is turned on. Then, in this case, if the return destination data at the time of turning on the power indicates the processing during the setting change work, the state at the time of returning from the power failure can be set as the state during the setting change work. ..

Further, in the pattern 4 related to this power failure, the "setting value" and the "setting display" are also displayed in the "setting change device operation" status (order 6) and the "setting value changeable" status (order 7). Is "b" based on the restored set value data. Here, even when the set value is fixed, the set value data may be written in the above-mentioned power failure storage area.

According to the pattern 4 related to the power failure as described above (pattern 1 related to the setting key OFF during the power failure), the power failure occurs during "the setting value can be changed", and the setting key is pressed when the power is turned on thereafter. If it is OFF, the set value data and the "stack contents" are inherited, and the power failure recovery is performed in the state of "setting value can be changed". Then, if the setting change work is performed by a non-regular procedure of turning off the setting key during the power cut without confirming the set value, the setting key is turned off. In spite of this, the power is restored in the state of "setting value can be changed".

That is, when the setting change work is performed by a normal procedure, the setting key is in the ON state in the situation of "setting value can be changed". However, when the work of the non-regular procedure as described above is performed, the case where the "setting key" is OFF and the "setting value can be changed" is performed. Can generate situations that never happen.

Therefore, it is possible to notify the hall personnel that the setting change work has been performed by an illegal procedure due to the difference in the situation from the normal work. Then, by providing such a function, it becomes easy to detect fraud. In addition, it is possible to exert a deterrent against fraudulent activities and prevent unauthorized setting changes.

Here, in other words, the pattern 4 related to the above-mentioned power failure (pattern 1 related to the setting key OFF during the power failure) is the case where the setting change work is not performed by the regular procedure. It can be said that it leaves a trace. Further, as another mode of the process for leaving such a trace, a process of detecting the combination of the state of the setting key and the situation during the setting change is executed, and the process of determining the suitability of the detection result is executed, and the setting key is turned off. An error notification may be performed when an irregular combination of situations such as "setting value can be changed" is detected.

It should be noted that the confirmation that the setting key is OFF may be performed by detecting the rising (or falling) edge when the signal indicating the state of the setting key changes from ON to OFF. Further, it may be performed by detecting whether the level of the signal indicating the state of the setting key is ON or OFF.

Further, in the pattern 4 related to the power failure, if the state of the setting key is ON even when the power is turned on, the pattern 2 related to the above-mentioned power failure (see FIG. 54 (b)) or the power failure It is possible to perform processing in the same pattern as the pattern 3 (see FIG. 54 (c)).
<< Fifth response when power failure occurs (Pattern 2 related to setting key OFF during power failure) >>

Next, regarding the fifth response when a power failure occurs during the setting change (hereinafter referred to as "pattern 5 related to power failure" or "pattern 2 related to setting key OFF during power failure"), FIG. 55 ( This will be described based on b). The same parts as the pattern 4 related to the above-mentioned power failure (pattern 1 related to the setting key OFF during power failure) shown in FIG. 55 (a) are shown in the same manner, and the description of the overlapping parts is omitted as appropriate. To do.

Pattern 5 related to this power interruption assumes a case where the set value is fixed while "the set value can be changed". That is, as shown in FIG. 55 (b), the order 1 to 3 is the same as the pattern 4 related to the above-mentioned power failure (see FIG. 55 (a)), but the setting value can be changed. When the set value is selected and there is an operation for confirming the set value (order 4), the "set value", "setting display", and "stack content" become "b", "0", and "n", respectively. Here, the fact that the "setting display" is "0" indicates that the set value has been confirmed by the operation of confirming the set value for the purpose of explaining the situation thereafter.

Then, in the "waiting for setting value determination" situation of waiting for the setting key to be turned off (order 5), the "setting value", "setting display", and "stack content" are the same "b" and "0" as before. , "N", but if a power failure occurs here (order 6), the "stack content" becomes the return destination data in the "waiting for setting value determination" status (order 5).

Further, when the setting key is turned off and the power is turned on with the setting key turned off as shown in the order 7 in FIG. 55 (b), the "set value" at this time is the "set value" after the above selection. b ”, and the“ stack contents ”returns to the data indicating the return destination address in the situation of order 5. Then, in the subsequent "waiting for setting value determination" situation (order 8), the setting key remains OFF, and the "setting value" and "setting display" are in the order 5 "setting change device operation". Similarly, it becomes "b" and "0".

In pattern 5 related to this power failure (pattern 2 related to setting key OFF during power failure), power failure occurs in the "waiting for setting value determination" status (order 5) after the set value is confirmed, and the power supply thereafter. If the setting key is OFF at the time of inputting (order 6), the set value data and the "stack contents" are inherited, and the power failure recovery is performed in the "waiting for setting value determination" state. Then, if the setting change work is performed by a non-regular procedure of turning off the setting key without turning off the setting key and turning off the setting key during the power cut, the setting key is turned off. In spite of this, the power is restored in the "waiting for setting value determination" state.

That is, when the setting change work is performed by the regular procedure, the setting key is in the ON state in the "waiting for setting value determination" situation, but the work of the non-regular procedure as described above is performed. When it is done, it is possible to generate a situation different from the case where the regular work is performed, as in the case of the above-mentioned pattern 4 related to the power failure (pattern 1 related to the setting key OFF during the power failure). ..

Therefore, it is possible to notify the hall personnel that the setting change work has been performed by an illegal procedure due to the difference in the situation from the normal work. And, by providing such a function, fraud detection becomes easy. In addition, it is possible to exert a deterrent against fraudulent activities and prevent unauthorized setting changes.

Here, in other words, the pattern 5 related to this power failure (pattern 2 related to the setting key OFF during power failure) is the pattern 4 related to the above-mentioned power failure (setting key during power failure). Similar to the pattern 1) related to OFF, it can be said that a trace remains when the setting change work is not performed by the regular procedure. Further, similarly to the above-mentioned pattern 4 related to the power failure (pattern 1 related to the setting key OFF during the power failure), an irregular combination of the state of the setting key and the state of "waiting for setting value determination" is detected. An error notification may be performed based on the detection result.

The pattern 5 related to the power failure (pattern 2 related to the setting key OFF during the power failure) is applied to the slot machine 10 in combination with the above-mentioned pattern 4 related to the power failure (see FIG. 55 (a)). It is possible. Further, in the pattern 5 related to the power failure, if the state of the setting key is ON even when the power is turned on, the above-mentioned pattern 2 related to the power failure (see FIG. 54 (b)) or the power failure It is possible to perform the process in the same pattern as the pattern 3 (see FIG. 54 (c)) according to the above.
<< 6th response when power failure occurs (Pattern 3 related to setting key OFF during power failure) >>

Next, regarding the sixth response when a power failure occurs during the setting change (hereinafter referred to as "pattern 6 related to power failure" or "pattern 3 related to setting key OFF during power failure"), FIG. 55 ( This will be described based on c). The same parts as those of the above-mentioned pattern 5 (see FIG. 55 (b)) and the like related to the power interruption will be illustrated in the same manner, and the description of the overlapping parts will be omitted as appropriate.

The pattern 6 related to the power failure shown in FIG. 55 (c) is set to "setting value can be changed" in the same manner as the pattern 5 related to the power failure (pattern 2 related to the setting key OFF during the power failure). It is assumed that the confirmation will be made. That is, as shown in FIG. 55 (c), the order 1 to 6 is the same as in FIG. 55 (b). Then, due to the recovery from the power failure, the situation becomes the "normal state" as shown in the order 8. In this "normal state", the state of the setting key is OFF, and the setting value data is "b", but nothing is displayed as the "setting display".

That is, in the pattern 6 related to this power failure, if the setting key is ON at the time of recovery from the power failure, it is determined that the setting is being changed, the "stack contents" is referred to, and which state during the setting change is returned. To determine. On the other hand, if the setting key is OFF when the power is restored, it is determined to be in the normal state, and the normal state is set regardless of the "stack content". The above-mentioned "normal state" represents a state in which the normal game is possible after the work of changing the setting is completed. Then, in the "normal state", "b" whose set value has been determined before the occurrence of the power failure is used, and the state after the power failure is restored differs depending on the state of the setting key.

Further, in the pattern 6 related to this power failure, the set value is selected in the "setting changeable" in the order 3, and the power failure occurs before the "set value is confirmed" in the order 4 after that. When the power is turned on with the setting key ON (when the setting change work in the normal procedure is not completed), the return destination data of "Stack contents" is used to "Set" in order 3. It returns to the situation before the setting value selection of "changeable" is performed.

According to the pattern 6 related to the power failure as described above (pattern 3 related to the setting key OFF during the power failure), the power failure occurs in the situation of "setting value confirmed", and the setting key is pressed when the power is turned on thereafter. If it is OFF, the set value data is inherited, but the "stack contents" are not inherited, and the power failure recovery is performed in the "normal state". Then, when the setting change work was performed by a non-regular procedure of turning off the setting key without turning off the setting key and turning off the setting key during the power cut, the setting change work was not completed. In spite of this, the power will be restored in the "normal state".

That is, the same state occurs when the setting change work is completed by the regular procedure and when the non-regular procedure as described above is performed. Therefore, even if the work is performed by the non-regular procedure, if the setting value is confirmed by the regular procedure, the situation does not shift to a special situation. Then, for example, if the amusement park clerk who is in the process of changing the settings simply mistakenly makes a mistake in the work procedure, the setting change work can be completed as it is, and the work procedure is simplified. Is possible.
<< 7th response when power failure occurs (Pattern 4 related to setting key OFF during power failure) >>

Next, with respect to the seventh response (hereinafter referred to as "pattern 7 related to power failure" or "pattern 4 related to setting key OFF during power failure") when a power failure occurs during the setting change, FIG. 55 ( This will be described based on d1) and (d2). The same parts as those of patterns 4 to 6 related to the above-mentioned power failure shown in FIGS. 55 (a) to 55 (c) are shown in the same manner, and the description of the overlapping parts will be omitted as appropriate.

In the pattern 7 related to this power interruption, as shown in FIG. 55 (d1), the status of "power on" (order 1) and the status of "setting change device operation" while the "setting key" is ON. (Order 2), the status of "setting value can be changed" (order 3), and then "power off" (order 4). Then, the setting key is turned off, and as shown in the order 5 in FIG. 55 (d1), the power is turned on with the setting key turned off.

Further, while the "setting key" is OFF, the status of "setting value can be changed" (order 6) and the situation of "setting value confirmed" (order 7) proceed, but "setting value can be changed" In the situation (order 6), a new set value different from "b" has not been selected. Then, in the "waiting for setting value determination" status (order 8), the state of the "setting key" continues to be OFF from the previous status, but the power is cut off again in this "waiting for setting value determination" status. Occurs (order 9).

Then, the power is turned on again with the "setting key" turned off (order 10). At this time, the "set value" is "b", and the return destination based on the "stack content" is "waiting for setting value determination", which is the situation of order 8 (order 11).

On the other hand, FIG. 55 (d2) shows a corresponding pattern when the operation of confirming the set value is performed while the setting key is ON and then the power is cut off. In the example of FIG. 55 (d2), the same as in FIG. 55 (d1) described above up to "setting value can be changed" in order 3, but after that, "setting value confirmed" and "waiting for setting value determination". (Order 4 and Order 5), and the power is cut off during "Waiting for set value determination" (Order 6). Then, when the power is turned on (order 7) thereafter, the normal state is reached (order 8) regardless of the "stack content", as in the case of the pattern 6 related to the above-mentioned power failure.

That is, in the pattern 7 related to this power failure, when the power failure occurs after the "set value is confirmed", the state after the power failure is restored differs depending on the state of the setting key. Then, as shown in FIG. 55 (d1), if a power failure occurs when the setting key is "OFF" (see FIG. 55 (d1)) and the state of the setting key at the time of turning on the power is OFF, " Return to the status of "waiting for setting value determination". However, similarly, even if a power failure occurs after the "set value is confirmed", as shown in FIG. 55 (d2), the power failure occurs when the setting key is "ON", and when the power is turned on. When the state of the setting key of is OFF, the power is restored to the "normal state".

In this way, it is possible to make the power failure recovery destination different depending on the combination of situations before and after the power failure (or power on) by executing the following processing. For example, first, data indicating whether or not the set value has been confirmed (the above-mentioned set value confirmation data) and data indicating the state of the setting key at the time of power failure (setting key state data at the time of power failure) are input. , The storage area for the set value confirmation data and the storage area for the setting key state data of the power failure storage area to be backed up, respectively.

Then, when the power is turned on after the power failure, the state of the setting key at that time is confirmed, and the setting value confirmation data and the setting key status data stored before the power failure and the setting key when the power is restored are displayed. Refer to the data indicating the status (setting key status data when the power is turned on).

Furthermore, when the data of the current "setting key" is compared with the data of the "setting key" whose data has been restored, and the setting key is switched from OFF to ON when a power failure occurs and when the power is turned on, Alternatively, if the setting key remains ON and has not changed, it is determined that the setting key is ON. Further, when the setting key is switched from ON to OFF, or when the setting key remains OFF and does not change, it is determined that the setting key is OFF.

In the example shown in FIG. 55 (d1), the setting key is switched from ON to OFF and the set value is confirmed in the case of the power failure in the order 4 and the power on in the order 5. Therefore, the "set value" after the power is turned on is "b" selected in the "setting value can be changed" in the order 3, and the situation after the power failure is restored is the same as the order 3 according to the "stack contents". "Setting value can be changed" (order 6).

Further, in the example shown in FIG. 55 (d1), in the case of the power failure in the order 9 and the power on in the order 10, the set value is fixed unlike the above case (order 7). However, since the state of the setting key before and after the power failure (or power on) is OFF, the situation after the power failure is restored is the same as the order 8 according to the "stack contents" as in the above case. It becomes "waiting for setting value determination" (order 11).

On the other hand, in the example shown in FIG. 55 (d2), the set value is confirmed (order 4) before the power cut in order 6, and the setting key is turned ON before and after the power cut (or power on). Since it has been switched from to OFF, the "set value" after the power is turned on is "b" selected in the "setting value changeable" in order 3, and the status after the power failure is restored is "stack contents". Is not used, and the "normal state" is set (order 8).

In the pattern 7 related to the power failure, if the state of the setting key remains ON and the setting key remains ON, the above-mentioned pattern 2 related to the power failure (see FIG. 54B) or , It is possible to perform the process in the same pattern as the pattern 3 related to the power failure (see FIG. 54 (c)).

In the pattern 7 related to the power interruption as described above, in the case shown in FIG. 55 (d1), the normal procedure is followed in the same manner as the pattern 5 related to the power failure described above (see FIG. 55 (b)). A trace can be left when the setting change work is not performed. Then, by providing such a function, it becomes easy to detect fraud. In addition, it is possible to exert a deterrent against fraudulent activities and prevent unauthorized setting changes.

Further, in the pattern 7 related to the power failure, in the case shown in FIG. 55 (d2), it is set during the power failure as in the case of the pattern 6 related to the power failure described above (see FIG. 55 (c)). If the setting change work is performed by the non-regular procedure of turning off the key, the power failure will be restored in the "normal state" even though the setting change work has not been completed. Order 8).
Then, the same state occurs when the setting change work is performed by the regular procedure and when the non-regular procedure work as described above is performed.

Therefore, for example, if the amusement park clerk who is in the process of changing the settings simply mistakenly makes a mistake in the work procedure, the setting change work can be completed as it is, and the work procedure is simplified. It becomes possible to plan.

It can be said that the pattern 7 related to such a power failure changes the state after the power is restored depending on whether or not the setting key is switched ON / OFF before and after the power failure (or power on). .. Further, it can be said that the state after the power failure is restored is set by looking at the state after the setting key is switched.

Further, in the pattern 7 related to this power interruption, the state of the setting key can be determined based on the signal level as described above. However, the present invention is not limited to this, and the state of the setting key may be determined by detecting the signal edge as described above. That is, the state of the setting key can also be determined by detecting the rising (or falling) edge when the signal indicating the state of the setting key changes from ON to OFF. The edge detection of such a signal can be performed, for example, when the power is turned on (see order 5 and order 10 in FIG. 55 (d1) and order 7 in FIG. 55 (d2)).
<< First response when an error occurs (Pattern 1 related to the error) >>

Next, an error notification pattern at the time of error occurrence will be described as a response when an emergency situation other than power failure occurs. The same parts as those of the above-mentioned various patterns will be illustrated in the same manner, and the description of the overlapping parts will be omitted as appropriate. Then, in the following, first, the first response (hereinafter referred to as "pattern 1 related to an error") when a predetermined error occurs during the setting change will be described with reference to FIG. 56 (a).

In pattern 1 related to this error, when a predetermined operation that causes an error is performed after selecting a set value during the setting change work, the state of the setting key is turned off after the set value is confirmed by the start lever operation or the like. Then, the error notification is executed.

That is, conventionally, when an operation that causes an error is performed while changing the setting, the setting value is set to a value outside the specified range (here, a value other than "1" to "6") and the setting change operation is performed. There was something to ban. In addition, when the setting change operation is prohibited, the error notification may not be performed unless the power is cut off. Then, in these conventional correspondence patterns, it is not easy to smoothly implement the setting change and judge the occurrence of an error.

On the other hand, in the pattern 1 related to the error of the present embodiment, when an error occurs during the setting change, the error notification is performed after the operation of the post-setting change device is stopped after waiting for the end of the setting change. Then, during the operation of the setting change device, the setting change work can be continuously performed even if an error occurs. In addition, the selection result of the set value is also reflected each time the selection operation is performed, and the display of the set value data and the set value is switched.

More specifically, as shown in FIG. 56 (a), when the power is turned on with the setting key turned on (order 1), the state of "setting change device operation" occurs (order) as in the various patterns described above. 2), "Setting value can be changed" (order 3). In this situation, for example, even if an error (CE error) occurs when it is determined that the game medal is accumulated in the portion where the insertion sensor 1 (115) or the insertion sensor 2 (116) is provided, the "setting" is performed. "Value change is possible" continues (order 5), and after the set value is confirmed (order 6), the status becomes "waiting for setting value determination". Then, as shown in the figure, when the "setting key" is turned off, an "error state" is set (in order 8), and error notification is executed.

Here, the errors that occur during the "setting change device operation" include the selector passage sensor abnormal passage (C1 error), the coin passage sensor retention error (CE error), and the inserted game medal when the backflow of the game medal is detected. Error when is jammed (C1 error, CH error, CE error,) Error when the game medal to be paid out is jammed (HP error), Error when there is an abnormal input in the payout sensor (not shown) (HQ) An error), an error when the game medal auxiliary storage 71 is full (FE error), and the like can be exemplified. In addition to this, there are a communication error that occurs when a wire is disconnected between the main control board 61 and the sub control board 31, an error that occurs when an illegal payout of a game medal is detected, a random number abnormality, and the like. Then, in the pattern 1 related to this error, even if various errors occur such that if a normal game is possible, the error is treated as an error and the error is notified, the error state is such that the error is notified. Do not.

According to the pattern 1 related to the error as described above, when an error occurs during the setting change work, the error notification is performed after the setting change device is stopped, so that the error notification is performed without interfering with the setting change work. It becomes possible. As a result, the setting change work can be smoothly executed. For example, the priority of error notification may be set in advance based on the importance of the error, and the error notification during the setting change may be performed only when an error of a predetermined priority or higher is detected. ..
<< Second response when an error occurs (Pattern 2 related to the error) >>

Subsequently, as another embodiment of the response pattern relating to the occurrence of an error, FIG. 56 (b) relates to the second response (hereinafter referred to as “pattern 2 relating to the error”) when a predetermined error occurs during the setting change. ) Will be explained. The same parts as in pattern 1 related to the above-mentioned error will be illustrated in the same manner, and the description of the overlapping parts will be omitted as appropriate. In pattern 2 related to this error, when a predetermined operation that causes an error is performed after selecting the set value during the setting change work, the state of the setting key is turned off after the set value is confirmed by the start lever operation or the like. Even if it does, the error notification is not executed and the normal state is entered.

That is, in the pattern 2 related to the error, if an error occurs during the setting change, the error notification is not performed even after the setting change device has stopped operating, and the normal game can be performed after the setting changing device has stopped operating. It becomes a "normal state".

More specifically, as shown in FIG. 56 (b), for example, even if a CE error related to the retention of game medals occurs in the situation of "setting value can be changed" (order 3), the error is related. Similar to pattern 1 (see FIG. 56A), "setting value can be changed" continues (order 5), and after setting value is confirmed (order 6), the situation becomes "waiting for setting value determination". Then, as shown in the figure, when the "setting key" is turned off, the "normal state" is set (order 8), and the error notification is not executed.

According to the pattern 2 related to the error as described above, when an error occurs during the setting change work in which the error is treated as an error if the normal game is possible and the error is notified. By not performing error notification even after the setting change device has stopped operating, it is possible to suppress error notification in unnecessary situations and improve the efficiency of setting change work. As a result, the setting change work can be smoothly executed without interfering with the setting change work.

The present invention is not limited to the above-described embodiments, and various modifications can be made. For example, it is possible to adopt various modes of data processing related to power failure or error during setting change and various storage area configurations as long as the same processing is possible. is there. Further, the setting key switch 68 shown in FIG. 4 may be provided separately from the setting unit 62.
<Various measures in other complex situations>

Next, various measures that can be taken when a problem such as a power failure or a rotation failure occurs in the effect display or rotation control in the slot machine 10 will be described. The same reference numerals are given to the same ones as described above, and detailed description thereof will be omitted.
<(1) Countermeasures for defects in special status display (countermeasure pattern 1)>

The countermeasures when the effect display and various defects are combined will be described below. Here, a special state display is assumed as the effect display. Further, as a "special state display" assuming countermeasures against defects, consider, for example, a moving image displayed on an image display means such as the production unit 18 (FIG. 1) when a special state different from the normal state is reached. be able to. Here, the reason why the term "effect unit 18 or the like" is used is that a display device for displaying the effect can be provided in addition to the effect unit 18.

Furthermore, as special states, the above-mentioned bonuses such as BB and RB (main bonus), RT (replay time), AT (assist time), and ART (assist replay) in which replays and bells are established with a higher probability than usual The state of time) can be illustrated. Of these special states, bonuses such as BB and RB and RT are managed by the main control board 61. The AT or ART, which is a special state other than the above, may be managed by the sub control board 31 or may be managed by the main control board 61.

Further, as a special state, an advantageous section (advantageous gaming state) in which a player can perform an advantageous gaming state can be exemplified. As this advantageous section, a gaming state in which a game such as AT or ART can be performed by managing the main control board 61 can be exemplified. In this advantageous section, a game such as AT may or may not be performed. For example, when a predetermined lottery is won or a control for displaying a predetermined symbol combination is performed, AT is performed. Controls for games such as, etc. can be performed. Further, the advantageous section can be set to end in a predetermined period (such as a period of 1500 games). In addition, there may be a plurality of types of periods of this advantageous section.

Further, as a special state, a gaming state of a so-called additional special zone can be exemplified. This addition special zone is a period of the gaming state in which the number of games is easily added (the probability of addition is increased) for the previously determined games such as AT and ART. The period of this additional special zone may be one type or a plurality of types.

As the special state display related to such a special state, a series of displays can be considered by being divided into a plurality of divisions arranged in a time series. The display categories of the special state display include the start display of the special state (special state start display), the display during the special state (display during the special state), and the display of the end related to the special state (special state end display). It can be exemplified. As any of these displays, it is possible to exemplify a display in which a plurality of display data are used in a time series to form a series of display contents. Further, as the special state start display among these, it can be exemplified that the video display and the effect sound output are performed as an introduction effect of, for example, several seconds to several tens of seconds. The video display may include a moving image display, a still image display, or a combination thereof. For example, it is also possible to adopt a display mode such as displaying a predetermined still image or another predetermined moving image after displaying a predetermined moving image and shifting to the display during the special state described later as the special state start display. is there.

In addition to this, as the effect at the time of displaying the special state start, for example, a freeze (start freeze) effect that can be performed in various modes as described above by using the rotating cylinders 51L to 51R under the control of the main control board 61. And the one that executes the video display and the output of the effect sound by the management of the sub control board 31 can be exemplified.

Here, the relationship between the freeze effect, which is the effect managed by the main control board 61, and the effect such as video display (display effect related to the freeze effect) managed by the sub control board 31 can be variously determined. Is. For example, the freeze effect and the effect such as video display are started at the same timing, the effect such as image display is started before the freeze effect, or the effect such as video display is started after the freeze effect. It is possible to do it.

More specifically, when the freeze effect is started by the management of the main control board 61, the sub control board 31 can start the effect related to the freeze effect based on the command from the main control board 61. .. Further, before the start of the freeze effect, it is possible to send a command related to the freeze effect from the main control board 61 to the sub control board 31 to start the effect managed by the sub control board 31, and then start the freeze effect. is there. Further, after the freeze effect is started, it is possible to send a command related to the freeze effect from the main control board 61 to the sub control board 31 to start the effect managed by the sub control board 31.

Further, as the above-mentioned display in the special state, for example, the progress status such as the number of games (the number of elapsed games) and the number of game medals acquired in the special state is sub-controlled based on the command from the main control board 61. It is possible to exemplify what is displayed together with the effect by managing the substrate 31. The display in the special state can be said to be, for example, a "normal display in a special state" or a "normal screen in a special state".

In addition, as the above-mentioned special state end display, for example, by managing the sub-control board 31, the characters in the production (hero character, ally character, etc.) win or lose the enemy character in the battle production. It is possible to exemplify what is executed following the production in the special state. Further, as this special state end display, any part or all of the game results such as the number of games executed during the special state, the number of acquired game medals, and the number of continuous sets are displayed. A so-called ending effect, which is displayed based on a command from the main control board 61, can be exemplified. The above-mentioned "number of continuous sets" represents the degree of accumulation of special states by the number of sets in which a plurality of games (40 games, 70 games, 100 games, etc.) are set as one set.

In the ending production, the display of the game result in the special state such as the number of games, the number of acquired sheets, and the number of continuous sets may be, for example, the number of games, the number of acquired sheets, and the number of continuous sets added one by one in order. It is possible to switch and display them one by one. Further, it is also possible to perform the ending effect in a mode of displaying all the game results of a plurality of types such as the number of games, the number of acquired cards, and the number of continuous sets (collective result display).

Further, at the time of the ending effect, it is also possible to execute the freeze effect as described above by managing the main control board 61 as the end freeze effect. In addition, it is also possible to exemplify an effect mode in which the main character, a ally character, or the like executes a story effect that is defeated by an enemy character, and then executes the ending effect as described above.

Further, when the special state is continuous, for example, when shifting from ART to bonus, the special state end display related to the previous special state is displayed by managing the sub control board 31 based on the command from the main control board 61. Subsequently, the special state start display related to the later special state may be executed.

On the other hand, as a problem that occurs in the special state display situation, a power failure (power failure) determined by the main control board 61 can be mentioned. In the following, a control operation (basic operation) when a problem does not occur will be described, and then, a difference from the basic operation will be described in two cases where the timing of occurrence of power failure is different.
<< Basic operation related to special status display (basic operation related to countermeasure pattern 1) >>

In FIG. 58 (a), various operation states in the basic operation in which no trouble occurs are shown in chronological order from top to bottom with reference numerals G1 to G10. In this basic operation, first, the rotation cylinder stop operation (G1) detected under the control of the main control board 61 during a normal game is the starting point, and then, under the control of the sub control board 31, a special state is set. After the start status of the start display (G2), the status shifts to the start display progress waiting status (G3).

Of these, the rotation cylinder stop operation (G1) shown in the uppermost stage is for the rotation cylinder (third stop rotation cylinder) that is stopped last among the first cylinder 51L to the third cylinder 51R described above. It indicates that the operation of the stop button (any of the first stop button 24L to the third stop button 24R) is performed. Then, when a button operation (third stop) for stopping the third stop rotation cylinder is detected under the control of the main control board 61 (G1), the above-mentioned special state start by the management of the sub control board 31 is started. The status shifts to the display start status (G2).

As described above, the special state display can be considered in stages such as the special state start display, the special state middle display, and the special state end display. The execution time (not necessarily one) is determined in advance for the special state start display, the special state middle display, and the special state end display. Then, these times can be referred to as "start display time", "special state display time", "end display time", and the like.

Further, waiting for the elapse of these "start display time", "special state display time", and "end display time" is indicated by "start display elapsed wait", "special state display elapsed wait", and "special state display elapsed wait", respectively. , "Waiting for the end display to elapse", etc. can be called. Further, the times in these waiting states can be referred to as "start display elapsed waiting time", "special state display elapsed waiting time", "end display elapsed waiting time", and the like, respectively.

In the example of FIG. 58 (a), when the special state start display is started (G2), the start display progress waiting state is set, and the start display waiting progress is timed (G3). Then, during the time of waiting for the lapse of the start display, various effects can be considered, for example, as the effect to be executed by the effect unit 18 or the like. For example, when the above-mentioned freeze effect is performed by managing the main control board 61. Based on the command from the main control board 61 to the sub control board 31, it is possible to execute an effect display related to the freeze effect.

When the above-mentioned start display elapsed waiting time ends (G4), the special state start display ends (G5), and the state shifts to the special state display status (G6). Then, after the start of the special state display (G6), when a predetermined special state end condition (described later) is achieved (G7), the state shifts to the special state end display status (G8). Here, as the special state end condition of the G7, the number of game medals to be paid out reaches a predetermined number during the special state, the number of games played during the special state reaches a predetermined number, or a predetermined symbol It can be adopted that the combination is displayed. Then, any one of these can be set as a special state end condition, and a plurality of combinations can be set as a special state end condition.

Furthermore, when the special state end display is continued and the end display elapsed waiting time ends (G9),
The special state end display ends, and depending on the situation, the game state shifts to the subsequent game state (G10). In the example of FIG. 58 (a), when the end display elapsed waiting time ends (G9) and the special state end display ends, the normal medium state (also referred to as the normal state) different from the special state is started in the above G10. ing.
<< Power failure pattern 1 during special status display (Countermeasure pattern 1-1) >>

Subsequently, the first combination of the above-mentioned special state display and the power failure as a defect (power interruption pattern 1 during the special state display) will be described with reference to FIG. 58 (b). The same reference numerals are given to the situations similar to the basic operation shown in FIG. 58 (a), and the description thereof will be omitted. In the example of FIG. 58 (b), when the power is cut off (G17) in the situation from the start display elapsed waiting time (G3) to the end of the start display elapsed waiting time (G4). Is assumed. For example, as described above, if the freeze effect is executed during the waiting time for the start display to elapse, the power is cut off during the freeze effect.

In such a case, if the power is cut off (G16) after the start of the start display elapsed waiting time (G3) and then the power is turned off and restored (G17, hereinafter referred to as "power restoration"), it is mainly. Without receiving the command related to the special state start display from the control board 61, the effect unit 18 or the like starts the predetermined start / end wait display under the management of the sub control board 31 (G18). That is, in the sub control board 31, the sub main CPU 86 executes the start / end wait display (G18) as the effect display after the power is restored without receiving the command from the main control board 61.

Here, the display data (first display data) related to the special state start display when a power failure occurs is configured by executing, for example, a plurality of display data of display data A, display data B, and display data C in order. The display data (second display data) related to the start-end waiting display (G18) after the power is restored can be composed of a plurality of display data of the display data D and the display data E. Further, it is possible to set the second display data to the display during the special state, which is the general screen of the special state that shifts after the freeze is completed. As a result, when the power is cut off during the freeze and the power is restored, the player can be made aware that the power is in a special state, so that the player can feel reassured even if there is an accident such as a power off. Can be done.

It is also possible to configure the last few seconds of the special state start display by looping the display of predetermined display data. For example, the display data A is defined as 0 to 10 seconds, the display data B is defined as 10 seconds to 18 seconds, and the display data C is defined as 18 seconds to 20 seconds. Then, it is conceivable to loop the display by the display data C. At this time, as described above, the display data B is configured to sequentially display a plurality of types of game results such as the number of games, the number of acquired cards, and the number of continuous sets, and the display data C displays all the game results of the plurality of types (collective results). Display data of the mode to be displayed. In such an embodiment, the display data A and the display data B can be used as the first display data, and the display data C can be used as the second display data.

Further, the configurations of the first display data and the second display data may change depending on circumstances such as the timing of power failure. For example, if a power failure occurs while the display data B is being executed after the display data A, the display data up to the display data B becomes the first display data and is used for the display waiting for the start and end after the power is restored. The displayed display data D and the display data E constitute the second display data. Further, if a power failure occurs while the display data A is being executed, the display data up to the display data A becomes the first display data, and the display data D and the display data E become the second display data as in the above case. Will constitute.

Further, the configuration of the first display data may be such that the special state start display ends by executing up to the display data C when the power supply is not cut off. Further, in the configuration of the first display data, when the power is not cut off, other display data (for example, display data F, display data G, etc.) is executed after the display data C, and the special state start display ends. It may be like this.

The second display data may be composed of three or more display data. Further, the second display data is not limited to being composed of a plurality of display data, for example, the second display data is composed of only the above-mentioned display data E (or only display data D). There may be. Further, the second display data can be considered as a single display data by integrating the display data D and the display data E.

Further, if the freeze effect by the management of the main control board 61 is executed at the time of displaying the special state start, a command related to the freeze effect information such as indicating the remaining time of the freeze effect at the time of power recovery, for example. There is no transmission or reception. Therefore, in the sub-control board 31, the effect of the start-time end wait display (G18) using the second display data (here, display data D and display data E) is performed without the information related to the freeze effect. Run in parallel with.

The start / end wait display (G18) here is, for example, a display for a special state, a display during a game that is not in a special state (normal state), or a standby situation that is not in a game. Of the predetermined standby displays, any of the predetermined displays can be adopted. When the display for the special state is performed as the start / end wait display (G18) using the second display data, it is shown to the player that the special state is restarted after the power is restored. Can be done. In addition, as the start / end wait display (G18), a display during a game (normal state) that is not in a special state, or when the above-mentioned standby display is performed, if the display is performed, after the power is restored, It is possible to indicate to the player that the display control has been restarted.

As described above, the display content of the above-mentioned start-end waiting display (G18) is based on the second display data, and the second display data includes a plurality of display data (here, display data D and display data E). Can be configured using in chronological order.

More specifically, as the display of the display data D, for example, a moving image of the battle (fighting) scene is displayed, and as the display of the display data E, the display of the final phase of the battle is repeatedly displayed (loop display). Be done. In this case, the battle (fighting) scene shifts to the scene of the final stage of the battle, the player is expected to be in the special state, and then the special state display related to the special state is executed.

Further, it is also possible to exemplify the display contents such that a still image is used as the display data E, the still image is displayed after the moving image (display after the start), and then the display is shifted to the display in the special state.

It is also possible to execute the remaining effect of the effect interrupted by the power failure as the end wait display (G18) at the start. In this case, it is conceivable to manage the progress of the production by using a timer or the like, save the progress information when the power is turned off, and restart the production based on the saved information when the power is restored. ..

Further, as the above-mentioned "standby display", a demo display (demonstration display) for displaying the contents of the production or the game during the standby, a brand display for displaying the company name, the model name, etc. can be exemplified. Then, as the display data for these demo displays, brand displays, etc., it is possible to use the data displayed when the power of the slot machine 10 is turned on. Further, it is also possible to display the selection menu of the language (Japanese, Korean, Chinese, English, etc.) used for displaying the characters of the game explanation during the standby display. And the standby display like these
It can be composed of a plurality of display data (for example, display data D and display data E).

Here, in the example of FIG. 58B, the special state start display is not completed due to the power failure that occurs during the special state start display. Therefore, after the end of the above-mentioned start display elapsed waiting time (G4), the status of the special state start display end (G5) in the basic operation of FIG. 58 (a) does not occur, and the status of the special state display status. (G6). After that, as in the basic operation of FIG. 58 (a), the situation shifts to the situation after the start of the special state display (G6).

When the power is restored (G17), the sub control board 31 not only does not have information on the remaining time of the freeze effect, but also has a control mode in which information indicating the progress of the effect (status information of the effect) is not saved. Conceivable. When such a control mode is adopted, for example, at the end of the start display elapsed waiting time (G4) or at the start of the special state display (G5), the main control board 61 to the sub control board A command (command during start freeze) indicating that the freeze effect at the start of the special state is being performed is transmitted to 31. Then, on the sub-control board 31, the effect related to the freeze effect is executed based on the command during the start freeze, or one of the plurality of effects is selected and executed. Conceivable.

In addition, after the power is restored from the power off in the situation where the freeze effect and the special state start display are being performed, the display during the special state such as ART (for example, "ART normal display") is displayed from the start wait end display (G18). , Or “ART normal screen”), the following control modes can be considered.

First, as the first control mode (first control mode at the start) here, the sub control board 31 issues a command from the main control board 61 while executing the start wait end wait display (G18) after the power is restored. wait. At this time, the start-end wait display (G18) uses display data of contents related to the freeze effect at any timing (may be from the beginning). Further, the main control board 61 transmits a command for notifying the end of the freeze effect (a command to end the freeze effect at the start of the special state) to the sub control board 31 at the timing of the end of the freeze effect. Then, the sub-control board 31 recognizes that the freeze effect has ended based on the received freeze effect end command, ends the start wait end display (G18), and starts the above-mentioned ART normal screen display. ..

Subsequently, as a second control mode (second control mode at the start), the timer is counted (timed) on the main control board 61 during the freeze effect at the start of the special state, and the count value (freeze effect progress). The value of time) is notified to the sub control board 31. When the count value reaches a predetermined value (when the freeze effect end time arrives), the sub-control board 31 shifts the display content of the effect unit 18 and the like from the special state start display related to the freeze effect to the ART normal screen.

Then, when the power is turned off and returned from the power cut during the special state start display, the main control board 61 transmits the count value following the count value at the time of the power cut to the sub control board 31. In the sub control board 31, when the count value reaches a predetermined value, the display contents of the effect unit 18 and the like are shifted from the special state start display related to the freeze effect to the ART normal screen, as in the case where the power is not cut off.

Subsequently, as a third control mode (third control mode at the start), the main control board 61 transmits a state command (status command) indicating the state of the effect to the sub control board 31. For example, as state commands, a state command indicating that the game state is in the freeze effect, a command indicating that the game state is in the special state, a command indicating that the game state is in the normal state, and the like are provided. Then, when the sub-control board 31 receives the state command indicating that the freeze effect is in progress, the effect related to the freeze effect is started, and when the state command indicating that the special state is in progress is received, for example, the ART state command If it is received, the ART normal screen is displayed, and if the command in the bonus state is received, the effect during the special game such as the bonus normal screen is started. Further, during the freeze effect, the main control board 61 rotates the rotating cylinder at a predetermined timing during the freeze effect (rotating the rotating cylinder to align the seven symbols in a straight line, or rotating the rotating cylinder in the reverse direction, for example, at predetermined intervals. It sends a status command (standby command) indicating that it is the timing to rotate.

Further, when the power is turned off and returned from the power off during the special state start display, the sub control board 31 starts the start time end wait display (G18) based on the above-mentioned standby command. In this case, the standby command is provided with information indicating the progress status (progress stage) of the freeze effect, and when the power is turned off and restored, the display data is selected based on the received standby command and continues from the special state start display before the power is turned off. It is conceivable to make a sexual display. As described above, the second display data can be an ART normal screen.

As described above, when the power is cut off during the special state start display, by displaying the start wait end wait display (G18) when the power is restored, even if the power cut occurs during the special state start display, Unexpected operation can be prevented after the power is restored, and the special state start display standby status can be reliably terminated. Then, by executing the start / end wait display (G18) using the second display data, the display is not interrupted even if the main control board 61 does not send a command for designating the effect at the time of power recovery. , It is possible to smoothly wait for the elapsed waiting time at the start to end (G4).

Further, when the power is cut off in the situation where the freeze effect by the management of the main control board 61 is executed by displaying the end wait display (G18) at the start, the rotating cylinder is used when the power is restored. It is possible to prevent a situation in which only the freeze effect is performed and no effect display is performed by the effect unit 18 or the like.

For example, considering a case where a BB or the like managed by the main control board 61 is awarded to a special state and the special state start display and the freeze effect are executed together, the effect from the main control board 61 is performed when the power is restored. No command is sent to specify the display. Therefore, a situation may occur in which nothing is displayed on the effect unit 18 or the like. Further, as the start / end wait display (G18), it is conceivable to perform a game (normal state) that is not in a special state or the above-mentioned standby display. Then, in such a case, it is possible that the player may be anxious that the control is resumed but the prize is canceled due to the power failure.

However, when the start / end wait display (G18) is displayed when the power is restored and the above-mentioned special state is displayed as the start / end wait display, the player is given a special display even after the power is restored. It can be shown that the game in the state is guaranteed. Then, the control can be performed so as to give the player a sense of security without causing the player to feel uneasy due to the power failure.

Further, as the start / end wait display (G18) using the second display data, even when the player is in a game (normal state) which is not in a special state or when the above-mentioned standby display is performed, the player is notified. It can be shown that the game can be continued after that. Therefore, as compared with the case where nothing is displayed on the effect unit 18 or the like after the power is restored, it is possible to give the player a sense of security and a guideline regarding the subsequent operating state.

Further, by performing the start / end wait display (G18) by the standby display, it is possible to secure the preparation time for displaying the moving image on the effect unit 18 or the like. For example, in the case of displaying a real-time 3D moving image in which 3DCG (3D computer graphics) is drawn in real time, a considerable amount of time is required before the image display is started. However, by performing the standby display as described above as the start / end waiting ideogram (G18), the preparation time can be secured by using the video with a small amount of data and the processing load, and it is possible to support a highly realistic CG video. It will be easy.
<< Power failure pattern 2 during special status display (countermeasure pattern 1-2) >>

Subsequently, pattern 2 (countermeasure pattern 1-2) relating to the combination of the special state display and the power failure as a defect will be described with reference to FIG. 58 (c). The same reference numerals are given to the situations similar to the basic operation shown in FIG. 58 (a), and the description thereof will be omitted. In the example of FIG. 58 (c), it is assumed that the power is cut off in the situation from the state of the special state end display (G8) to the end of the elapsed waiting time at the time of end display (G9). ..

In such a case, if the power is cut off (G16) after the start of the special state end display (G8) using the first display data for the end, and then the power is restored (G17), the effect unit At 18 and the like, a predetermined end waiting display using the second display data for the end is started (G21).

The first display data for the end described above shall be composed of a plurality of display data (for example, display data K, display data L, display data M, etc.) like the first display data for the start. Can be done. Further, the power failure can occur even in a situation where any of the display data K, the display data L, and the display data M is being executed. The first display data for the end may be composed of two or four or more display data, or may be composed of a single display data.

Further, as the end waiting display (G21) at the end, for example, any of the above-mentioned normal state display and the above-mentioned standby display, which is predetermined, can be adopted. Further, as the display data of the end waiting display using the second display data for the end, a plurality of display data (for example, display data N) as in the start end waiting display (G21 in FIG. 58 (b)). , Display data O, etc.) can be provided. The second display data for the end may be composed of three or more or a single display data.

Here, in the example of FIG. 58 (c), the special state end display is not completed due to the power failure that occurs during the special state end display. Then, while executing the above-mentioned end wait display (G21) using the second display data, the end display elapsed waiting time of the above G9 is waited for to end, and when the end display elapsed waiting time ends (G9), The special state end display ends, and depending on the situation, the game state (here, the normal medium state) is entered (G10).

In this way, when there is a power failure during the special state end display using the first display data, the end wait display (G21) is displayed when the power is restored using the second display data, so that the special state is displayed. Even if the power is cut off during the end display, it is possible to prevent unexpected operation after the power is restored, and it is possible to reliably end the status (G9) waiting for the end display to elapse. Then, by executing the end wait display at the end of G21, it is possible to smoothly wait for the end display elapsed waiting time to end (G9) without interrupting the display.

Further, in addition to the special state end display, a freeze effect may be performed by managing the main control board 61. In such a case, as the freeze effect after the power is restored, an effect that continues from the effect when the power is cut off is executed. Further, as the end waiting display (G21) managed by the sub control board 31, the game result related to the special state such as the number of acquired game medals, the number of games, and the number of continuous sets is displayed. Aspects can be exemplified.

In addition, as a display of game results, instead of displaying a part of the number of game medals won, the number of games, the number of continuous sets, etc., all of them appear at once (final display). It is also possible to exemplify an effect mode such as performing. Then, the display data of such a batch result display is set as the above-mentioned display data O, and after displaying the display data N such as the defeat scene of the main character or the ally character, the batch result display is executed based on the display data O. It is also possible to do.

Further, when a power failure occurs while the freeze effect is being executed together with the special state end display, the main control board 61 is managed by not transmitting a command from the main control board 61 when the power is restored. It can be assumed that only the freeze effect is performed by the above, and no effect display is performed by the management of the sub control board 31. However, it is possible to prevent such a situation from occurring even if there is no command transmission from the main control board 61 by displaying the end wait display (G21) after the power is turned off and on.

Further, when the end waiting display (G21) is displayed during a game (normal state) that is not in the above-mentioned special state, or when the above-mentioned standby display is performed, the special state at that time ends for the player. Can be shown to do. Therefore, as compared with the case where nothing is displayed on the effect unit 18 or the like after the power is restored, it is possible to give the player a sense of security and a guideline regarding the subsequent operating state.

Further, at the end of the special state, when the freeze effect by the management of the main control board 61 and the special state end display by the management of the sub control board 31 are performed, the special state end display is changed to the subsequent gaming state. Various control modes related to the transmission and reception of commands can be considered. Then, as the gaming state after the special state end display, a normal medium state (G10) that is not a special state can be considered.

First, as the first control mode at the end of the special state (first control mode at the end), the main control board 61 sends a command (special) to notify the end of the freeze effect, as in the above-described first control mode at the start. The freeze effect end command) related to the end of the state is transmitted to the sub control board 31. More specifically, the sub control board 31 waits for a command from the main control board 61 while executing the end wait display (G21) after the power is restored after the power is turned off during the special state end display. At this time, the end waiting display (G21) uses the display data of the contents related to the freeze effect at any timing (may be from the beginning) (for example, the main character or the ally character battles). (Such as those that are defeated by). Further, at the final stage (may be from the beginning) of the end waiting display (G21) at the end, the above-mentioned ending effect (including the case of the batch display result) can be performed.

The main control board 61 transmits the freeze effect end command related to the above-mentioned special state end to the sub control board 31 at the timing of the end of the freeze effect. Then, the sub control board 31 recognizes that the freeze effect has ended based on the received freeze effect end command, terminates the end wait display (G21), and displays the above-mentioned normal medium state (G10). Start displaying the display using data (screen in normal state).

Subsequently, as the second control mode (second control mode at the end), the timer is counted on the main control board 61 during the freeze effect at the end of the special state, as in the second control mode at the start described above. (Timekeeping) is performed, and the count value (the value of the elapsed freeze effect time) is notified to the sub-control board 31. When the count value reaches a predetermined value (when the freeze effect end time arrives), the sub-control board 31 shifts the display content of the effect unit 18 and the like from the special state end display related to the freeze effect to the normal state middle screen.

Then, when the power is turned off and returned from the power cut during the special state end display, the main control board 61 transmits the count value following the count value at the time of the power cut to the sub control board 31. When the count value reaches a predetermined value, the sub-control board 31 shifts the display content of the effect unit 18 and the like from the special state end display related to the freeze effect to the normal state middle screen.

Subsequently, as a third control mode (third control mode at the end), a state command (a state command in which the main control board 61 indicates the state of the effect to the sub control board 31 as in the above-described third control mode at the start) Status command) is sent. Regarding the freeze effect, the main control board 61 transmits a state command indicating that the freeze effect is in progress to the sub control board 31 at the timing when the freeze effect is started. Further, the main control board 61, for example, at a predetermined timing during the freeze effect (rotating the rotating cylinder so that the seven symbols are not aligned in a straight line, or stopping the rotating rotating cylinder), for example, at predetermined intervals. Send a standby command indicating that it is time to rotate. When the sub-control board 31 receives the above-mentioned state command indicating that the freeze effect is in progress, the sub-control board 31 executes a special state end display related to the freeze effect, and indicates that the special state has ended and is in the normal state. When the command is received, the display state shifts to the display state related to the normal state (G10), and the display of the normal state screen is started.

Further, when the power is turned off and returned from the power off during the special state end display, the sub control board 31 starts the end wait display (G18) based on the above-mentioned standby command. In this case, the standby command is provided with information indicating the progress status (progress stage) of the freeze effect, and when the power is turned off and restored, the display data is selected based on the received standby command, and the display continues from the special state end display before the power is turned off. It is conceivable to make a sexual display. It is also possible to set a normal screen as the second display data. As a result, when the power is turned off during the end freeze and the power is restored, the normal screen can be displayed instead of the ART screen, so that the power restoration process can be performed without giving excessive expectations to the player.
<(2) Countermeasures against problems in rotating cylinder acceleration (countermeasure pattern 2)>
<< Overview of rotating speed control >>

Next, the relationship between the rotating cylinder acceleration and the defect will be described with reference to FIGS. 59 and 60. First, the term "rotating cylinder acceleration" as used herein means a period (acceleration period) in which the rotating cylinder is in an accelerating state in the acceleration state when the rotation speed of the rotating cylinder changes, as is schematically shown in FIG. 60 (a). It means the control state of. More specifically, as shown in the left end portion in FIG. 60A, the rotating cylinders 51L to 51R start rotating through a start lever operation (lever ON) and a combination drawing, and gradually increase the rotation speed. It reaches a constant speed, ends the acceleration period, and reaches the "constant speed" on the rotating cylinder control.

After that, when the corresponding stop button (any of the first stop button 24C to the third stop button 24L in this embodiment) is operated and there is a stop input (stop input), the rotation of the rotating cylinder is braked and the rotation is performed. The winning judgment is made as the rotation of the body stops. Here, the rotation speed mode shown in FIG. 60A shows a basic operation. For example, immediately after the lever is turned on or immediately after the stop input, the rotating cylinders 51L to 51R are operated for the effect of omitting the illustration. (The operation of freeze production) may be performed.

As described above, a four-phase rotating cylinder stepping motor (not shown) is used in the rotating cylinder rotating device 54 (see FIG. 4). More specifically, the control of the rotating cylinder rotating device 54 will be described in more detail. The control related to each rotating cylinder 51C to 51L is mainly performed by the above-mentioned rotating cylinder drive management process (S546 in FIG. 18). One step of the rotary cylinder stepping motor is about 1.071 °, and each rotary cylinder makes one rotation in 336 steps. Further, the number of symbols of the one-time cylinder is 21, and the number of steps of one symbol is 16. When the number of symbols of the one-time cylinder is, for example, 20, a symbol having 16 steps and a symbol having 17 steps are provided.
<< Start of rotation of the rotating cylinder >>

When the rotation of the rotating cylinders 51L to 51R is started, predetermined data is set in each RWM that controls the rotating cylinders 51C to 51L in order to start the acceleration of the rotating cylinders 51C to 51L. Specifically, for each of the rotating cylinders 51C to 51L, the rotating cylinder drive state number indicates 1 for the rotation start standby, the rotating cylinder drive pulse output counter indicates 1, and the number of times of rotating cylinder drive pulse switching (during acceleration) is 10. , The symbol number (for the passing position) is FFH indicating that the rotating cylinder sensor has not passed, the symbol number (for the stop position) is the FFH indicating that the symbol number has not been set, and the rotating cylinder rotation failure detection. 0 is set in the counter. Here, the description of the rotation start waiting process performed at the start of rotation of the rotating cylinder will be omitted.
<< Acceleration processing of the rotating cylinder >>

Subsequently, the operation in the acceleration process of the rotating cylinder will be described. The acceleration process is the same for each rotating cylinder. In the state where the rotating cylinder drive state number is 5 (accelerating), the rotating cylinder drive pulse output counter is subtracted by 1 for each interrupt, and when it becomes 0, the following processing is performed. First, the counter for searching the rotating cylinder drive pulse data is added by 1, and the excitation output is performed based on the data extracted from the rotating cylinder drive pulse table based on the lower 3 bit values (0 to 7), and the rotating cylinder is moved by one step. Let me. The number of rotation cylinder drive pulse switching during acceleration is subtracted by 1, and if it is not 0, data is taken out from the rotation cylinder rise pattern table based on the value and set in the rotation cylinder drive pulse output counter. Then, when the number of rotation cylinder drive pulse switching during acceleration becomes 0, the rotation cylinder drive state is set to 4 (during constant speed).

Regarding the acceleration time of the rotating cylinder, the excitation switching time from the start of the rotating cylinder rotation is defined according to the number of steps from the start of rotation. In this embodiment, the excitation switching time of the first step from the start of rotation is about 114 ms, which corresponds to 51 interrupts, about 70 ms, which corresponds to 31 interrupts in the second step, and about 9 ms, which corresponds to 4 interrupts in the third step. In the 4th to 7th steps, it is about 6.7ms corresponding to 3 interrupts, in the 8th step it is about 4.5ms corresponding to 2 interrupts, and in the 9th step when reaching a constant speed, it is about 2.2ms corresponding to 1 interrupt. ing. Further, the period of one interrupt is 2.235 ms as described above, and the total number of interrupts from the first step to the ninth step is 92 (= 51 + 31 + 4 + 3 + 2 + 1).
<< Constant speed processing of the rotating cylinder >>

Subsequently, the constant speed processing of the rotating cylinder will be described. Regarding the operation in the constant speed processing of the rotating cylinder, the following processing is performed for each interrupt in the state where the rotating cylinder drive state number is 4 (during constant speed). That is, the rotating cylinder drive pulse output counter is subtracted by 1, it is confirmed that the rotating cylinder drive pulse output counter is 0, and 1 is set in the rotating cylinder drive pulse output counter again. If the counter for searching the rotating cylinder drive pulse data is an even number, the rotating cylinder rotation failure detection counter is added by 1. Furthermore, the counter for searching the rotating cylinder drive pulse data is added by 1, and the excitation output is performed based on the data extracted from the rotating cylinder drive pulse table based on the lower 3 bit values (0 to 7), and the rotating cylinder is moved by one step. Let me. Then, when the rotating cylinder sensor signal changes from OFF to ON and the origin position (initial position) of the rotating cylinder is detected, the step number of one symbol is 4, the symbol number (for the passing position) is 0, and the rotating cylinder rotation failure detection counter. Set to 0.

When the origin position of the rotating cylinder cannot be detected (except when the rotating cylinder sensor signal changes from OFF to ON), the step number of one symbol is subtracted by 1 for each interrupt. If the result of subtracting the step number of one symbol is 0, the step number of one symbol is set to 16 and 1 is added to the symbol number (for the passing position). Further, when the result of adding 1 to the symbol number (for the passing position) exceeds 20, the symbol number (for the passing position) is set to 0.

Regarding the design of the rotation speed in the constant speed processing of the rotating cylinder, the time required for the rotating cylinder rotation in one round in the constant speed state is that the excitation switching for 336 steps is performed for each interrupt (2.235 ms) at the constant speed. Therefore, it is 750.96 ms. Therefore, the design rotation speed in the constant speed state is 79.90 rotations / minute.
<< Processing when the rotating cylinder has a rotation failure >>

Subsequently, the processing when the rotating cylinder has a poor rotation will be described. During the rotation of the cylinder, the passage of the initialization (index) that blocks the rotation sensor may be delayed due to the rotation failure of the cylinder. In such a state, the number of interrupts required for one rotation of the cylinder exceeds 336 times, and the accurate symbol position may not be detected. Therefore, a rotation failure detection counter is used to inspect the rotation failure.

The rotation failure detection counter is incremented by 1 when the rotating cylinder drive state number is 4 (during constant speed) and 1 is added when the rotating cylinder drive pulse data search counter is even, and is usually counted in the range of 0 to 167. However, if the passage of the initialization (index) that blocks the rotation sensor is not confirmed, the count exceeds 167 as it is. Here, the rotation of one round of the rotating cylinder is controlled by 336 steps, but in the slot machine 10, counting is performed every even number of steps, and the number of counts is a value of 0 to 167 as described above.

The following processing is performed to detect the rotation failure of the rotating cylinder. That is, when the rotation failure detection counter reaches 184 or more, it is determined that the rotation failure is defective. In order to re-accelerate the rotating cylinder, data is set in each RWM that controls the rotating cylinder. Specifically, for each rotating cylinder, the rotating cylinder drive status number indicates that acceleration is in progress 5, the rotating cylinder drive pulse output counter indicates 1, the number of times the rotating cylinder drive pulse is switched (during acceleration) is 10, and the symbol number ( FFH indicating that the rotating cylinder sensor has not passed (for the passing position), FFH indicating that the symbol number has not been set for the symbol number (for the stop position), and 0 for the rotating cylinder rotation failure detection counter. Is set.

Here, the reason why the value of the rotating cylinder rotation failure detection counter when determining that the rotating cylinder rotation is defective is 184 or more is as follows. That is, at the time of rotation failure, the value of the rotation failure detection counter becomes a value exceeding one round of the rotation cylinder (here, 167). However, if the threshold value for determining the rotation failure of the rotating cylinder is set to "167" and the period of non-detection of the index exceeds one lap, the judgment of the rotation failure of the rotating cylinder is excessively performed. It may be judged that the rotation of the rotating cylinder is poor. Further, if the threshold value of the counter value for determining the rotation failure of the rotation cylinder is set excessively large, the detection accuracy of the rotation failure of the rotation cylinder is lowered. Under these circumstances, the threshold value of the counter value for determining the rotation failure of the rotation cylinder is set to "184" so that the rotation failure of the rotation cylinder can be properly detected.
<< Deceleration processing of the rotating cylinder during normal game >>

Subsequently, the details of the deceleration process of the rotating cylinder during the normal game will be described. When the stop buttons 24C to 24L are received, the symbol number to be displayed is set to the symbol number (for the stop position), and 3 (deceleration start) is set to the rotating cylinder drive state number. In the deceleration start processing of the rotating cylinder during the normal game, when the rotating cylinder drive state number is 3 (deceleration start), the step number of one symbol is 13, and the symbol number (for the passing position) and the symbol number (stop). If the positions (for position) match, set 2 (during deceleration) to the rotating cylinder drive status number.

In the deceleration processing of the rotating cylinder during the normal game, when the rotating cylinder drive state number is 2 (during deceleration), the excitation output outputs 4-phase ON, and the value of the rotating cylinder drive pulse output counter is changed from 85. 1 is subtracted for each interrupt, and when the result of the subtraction is 0 and about 190 ms (= 85 x 2.235 ms) has elapsed, 0 (stopped here) is set in the rotating cylinder drive state number, and the excitation output is set. Turn off.
<< Basic operation related to rotation acceleration >>

The basic operation of the rotating cylinder by the rotating cylinder control as described above can be roughly shown as shown in FIG. 59 (a). Here, in FIG. 59 (a), a defect (rotational cylinder rotation failure) occurs during the constant speed state of the rotating cylinder, but the operation when the defect does not occur during the rotating cylinder acceleration is used as the basic operation. There is. As a basic operation, it is also possible to assume an operation in which the rotation failure does not occur even if the rotation failure is detected in the constant speed state.

In FIG. 59 (a), various situations in the basic operation are shown in order from top to bottom with reference numerals H1 to H9. In this basic operation, first, when the above-mentioned start lever 25 is operated in a state where the game can be started, the situation (H1) of the rotating cylinder start operation is set. The status of the rotating cylinder starting operation (H1) corresponds to a situation in which the rotating cylinder starting operation is detected by the main CPU 81 of the main control board 61. Further, the rotating cylinders 51L to 51R start to rotate and shift to the acceleration state (H2), and the acceleration state processing (acceleration state processing) as described above is performed (H3).

The control status of the main CPU 81 is also shown for the acceleration state (H2) of the rotating cylinder and the processing (H3) of the acceleration state. The acceleration state (H2) and the acceleration state processing (H3) of the rotating cylinder correspond to the processing in the situation where the rotating cylinder drive state number is “5” during acceleration. Then, the acceleration process for the predetermined period (here, 9 steps, 92 interrupts) described above performs the process for reaching the constant speed of the 9th step, and the acceleration state ends (H4).

When the acceleration state ends (H4), the constant speed state (constant rotation speed state) as described above is reached (H5). This constant speed state (H5) corresponds to the processing in the above-mentioned situation where the rotating cylinder drive state number is "4" during the constant speed. Then, the constant speed state is maintained (H6), and when a rotation failure occurs due to some factor in the constant speed state (H7), the rotation failure is detected in the rotation failure detection (H8), and re-acceleration is performed. It becomes a situation (H9). The processing here corresponds to the various processing described above as << processing when the rotating cylinder causes a rotation failure >>. The process for reacceleration may be the same as or different from the acceleration state process (H2 to H4).
<< Rotation failure pattern 1 during rotating cylinder acceleration (Countermeasure pattern 2-1 (other than power failure)) >>

Subsequently, the pattern 1 relating to the combination of the rotating cylinder acceleration and the rotation failure will be described with reference to FIG. 59 (b). The same reference numerals are given to the situations similar to the basic operation shown in FIG. 59 (a), and the description thereof will be omitted. In the example of FIG. 59 (b), it is assumed that a rotation failure (H7) occurs due to a factor other than a power failure between the acceleration state processing execution (H3) and the acceleration state processing end (H4). There is. As an embodiment of the rotation failure here, it can be exemplified that any of the rotating cylinders during acceleration cannot rotate in the expected acceleration state due to, for example, a step-out of the motor or other factors. The above-mentioned "other factors" include that the rotating cylinder comes into contact with the display window (rotating cylinder display panel 28) due to an error during assembly or deterioration over time, making it difficult to rotate, or the rotating cylinder stepping motor fails. You can exemplify what to do. It is also possible to assume fraud such as manually pressing the rotating cylinder as "other factors".

In such a case, in the situation where the rotation failure (H7) occurs, the rotation failure detection (rotation failure detection) is not performed, and the processing of the remaining acceleration state is continued (H11). The acceleration state processing (H11) at this time corresponds to the processing in the situation where the rotation cylinder drive state number is “5” during acceleration described above. Then, even if the rotating cylinder cannot be accelerated in the planned manner, the acceleration state processing is completed to the end (H4), and the constant speed state (rotating cylinder constant speed state) is the same as the basic operation shown in FIG. 59 (a). ), And the constant speed state is maintained (H6). The constant speed state at this time corresponds to the processing in the situation where the rotating cylinder drive state number is "4" during the constant speed, as in the basic operation. Further, in this situation, rotation failure detection (step-out detection processing) is performed (H8), and here, rotation failure is detected because rotation failure has occurred, and the situation of re-acceleration as described above Becomes (H9).

By doing so, even if a rotation failure occurs during the acceleration state, it is possible to prevent unexpected operation, and it is possible to reliably end the acceleration state. Then, it is possible to quickly shift to the constant speed state, and the shift to major situations such as the processing for notifying the result of the winning combination and the processing for paying out the game medals (including the processing for storing) is also quick. It becomes possible to do it.

Further, for example, when accelerating the rotating cylinder by repeating a predetermined number of interrupts as described above, the state of the rotating cylinder reaches a constant speed rotation without requiring all the normally required number of interrupts. A case can be assumed. That is, normally, for control purposes, even if a predetermined number of interrupts are repeated to accelerate to a constant speed, depending on the situation, the constant speed may be reached within a limited acceleration time after the power is restored. In that case, the rotation failure is not detected and the re-acceleration (H9) is not performed.

That is, when the power is restored, if the same number of interrupts as in the normal state is always executed for acceleration regardless of the actual state of the rotation speed of the rotating cylinder, a waste of time will occur. However, as described above, in the situation where the rotation failure (H7) occurs, the rotation failure detection (rotation failure detection) is not performed, the processing of the remaining acceleration state is continued (H11), and the mode is as planned. Even if the rotation cylinder cannot be accelerated, by completing the acceleration state processing to the end (H4), the rotation cylinder rotation control can be smoothly advanced without wasting unnecessary acceleration time.

Here, it is also possible to adopt the following as a control mode during the rotation acceleration. For example, regarding the processing of the main CPU 81, the processing at the time of accelerating the rotating cylinder is performed without interrupting the situation, and the processing at the time of stopping the rotating cylinder is performed in the situation where interrupts are prohibited for a part of the period. .. More specifically, when accelerating the rotating cylinder, even if some interruption occurs, the rotation of the rotating cylinder stepping motor is continued in terms of control. As a result, if there is no failure of the rotating cylinder stepping motor or contact between the rotating cylinder and the display window (rotating cylinder display panel 28), even if some interruption occurs, the rotating cylinder is at a considerable rate. Is expected to continue accelerating and reach a constant speed.

In contrast to this way of thinking when accelerating the cylinder, when the rotation is stopped, more precise and accurate control is required. Therefore, interrupts are prohibited, and the rotation control is affected by the interrupt, so that the rotation control is accurate. Prevents the interrupt from dropping. For example, when the number of steps of one symbol is 16, the symbol A and the symbol B are continuous, and the stop is accepted by the 8th step of the symbol A, the symbol A is stopped and the symbol B is stopped from the 9th step of the symbol A. It is assumed that the symbol B is stopped when the stop is accepted by the 8th step of the above. Here, when the rotation stop control process is performed without performing the interrupt prohibition process, the stop reception process is performed by some interrupt. Is delayed, the processing for stop reception is performed at a different timing, and if the stop reception is performed at the position after the 9th step, the stopped symbol will be stopped by one symbol. obtain. However, by prohibiting other interrupt processing only while the interrupt processing related to the stop reception is performed, it is possible to prevent the stop position of the symbol from shifting, and it is possible to perform accurate symbol stop.
<< Rotation failure pattern 2 during rotating cylinder acceleration (Countermeasure pattern 2-2 (power off)) >>

Subsequently, pattern 2 (countermeasure pattern 2-2) relating to the combination of rotation cylinder acceleration and rotation failure will be described with reference to FIG. 59 (c). The same reference numerals are given to the basic operations shown in FIG. 59 (a) and the same situations as the rotation failure pattern 1 (countermeasure pattern 2-1) during rotational rotation acceleration shown in FIG. 59 (b), and the description thereof will be described. Is omitted. In the example of FIG. 59 (c), it is assumed that a rotation failure due to a power failure (H16) occurs between the acceleration state processing execution (H3) and the acceleration state processing end (H4). There is.

In such a case, if the power is turned off (H16) after the acceleration state processing is executed (H3) and then the power is restored (H17), the rotating cylinder is stopped and the rotating cylinder rotation is poor (H18). ), But in this situation, the rotation failure is not detected (rotation failure detection), the rotation of the rotating cylinder is started, and the processing of the acceleration state is executed (H11). The acceleration state processing (H11) at this time corresponds to the processing in the situation where the rotation cylinder drive state number is “5” during acceleration described above. Further, as the execution mode of the acceleration processing here, a mode in which the processing in the acceleration state is executed from the beginning, a mode in which the processing in the acceleration state is executed only in the remaining time, and the like can be considered. Then, even if the rotating cylinder cannot be accelerated in the planned manner, the acceleration state processing is completed (H4), and the basic operation shown in FIG. 59 (a) and the countermeasure pattern 2-1 shown in FIG. 59 (b) are obtained. Similarly, it becomes a constant speed state (rotating cylinder constant speed state) (H5) and maintains a constant speed state (H6). As in the case of the countermeasure pattern 2-1 described above, depending on the situation, the constant speed may be reached within the limited acceleration time after the power is restored, so the acceleration process for the same period as the normal time is not performed again. By doing so, it is possible to smoothly advance the rotation control of the rotating cylinder without wasting unnecessary acceleration time. Further, rotation failure is detected in this situation (H8), and if rotation failure occurs, rotation failure is detected, resulting in the re-acceleration situation as described above (H9). If no rotation failure is detected in the above-mentioned rotation failure detection (H8), although not shown, normal rotation control of rotation is performed instead of reacceleration (H9).

By doing so, even if the power supply is cut off during the acceleration state, it is possible to obtain the same effect as the rotation failure pattern 1 (countermeasure pattern 2-1) during the rotation cylinder acceleration described above. Further, as soon as the power is restored, the remaining processing up to the constant speed state can be performed immediately.
<(3) Countermeasures for problems at stop reception (countermeasure pattern 3)>

Next, the relationship between the stop reception and the malfunction when the rotation cylinder is stopped will be described. First, the "stop reception" here means that it is detected that any of the first stop button 24L to the third stop button 24R has been operated in the situation where the stop reception is possible as described above. Means. And here, mainly, the relationship with the defect when there is a stop reception for two cylinders (two cylinders have already stopped) and there is a stop reception for the remaining one cylinder will be explained. As will be described later, the same measures can be taken for the first stop reception and the second stop reception.
<< Basic operation related to stop reception >>

FIG. 61A schematically shows the basic operation of stop reception when a winning combination such as a bell is won. In the example of FIG. 61 (a), as shown in the uppermost row, the rotation of the rotating cylinder is started (J2) in the situation where the winning combination is won (J1). In the slot machine 10 of the present embodiment, regardless of the order in which the first stop button 24L to the third stop button 24R are pressed, the first body 51L to the third body 51L to the third time are combined with the symbol combination corresponding to the winning winning combination. The body 51R can be stopped.

As described above, when each of the rotating cylinders 51L to 51R starts rotating, it shifts to a constant speed state through an acceleration state (J3). Then, each of the rotating cylinders 51L to 51R maintains a constant speed state (J4), and if the above-mentioned minimum game time has elapsed, it shifts to a stop receiving state (J5). Further, when the player presses any of the stop buttons (any of 24L to 24R), the stop reception is performed for the stop button (and the rotating cylinder) for which the first stop operation is performed. (J6).

Here, the stop reception related to the rotating cylinder that was first stopped is referred to as the "first cylinder stop reception", and the stop receptions related to the subsequent stop operations are referred to as "the second cylinder stop reception" and ". It is called "the 3rd body stop reception". In addition, the rotating cylinder related to the "1st body stop reception" is referred to as the "1st stop rotating body", and the rotating body related to the "2nd body stop reception" and the "3rd body stop reception" are referred to as "the first". It is referred to as "2 stop rotation cylinder" and "3rd stop rotation cylinder". Further, when the first cylinder stop reception is received, the processing of the main CPU 81 (FIG. 5A) shifts to the rotation cylinder stop state for stopping the first stop rotation cylinder, but in FIG. 61A, The illustration of the rotating cylinder stopped state is omitted.

In the example shown in FIG. 61A, since the winning combination is won, the symbols constituting the symbol combination of the winning combination are displayed for the above-mentioned first stop rotating cylinder (J7). Subsequently, the second stop reception (J8) displays the symbols constituting the winning combination of symbols after shifting to the rotation stop state (not shown) for the above-mentioned second stop rotation (J8). J9).

Further, after the third stop rotation reception (J10) shifts to the rotation stop state for the above-mentioned third stop rotation cylinder (J11), the symbols constituting the symbol combination of the winning combination are displayed (J12). Through these situations, the situation is such that all the medals are stopped (J13), and after the winning judgment, the payout (including storage) of the number of game medals according to the winning combination is started (J14). .. The "winning determination" referred to here can be performed in the display determination (S66) of the game progress main process (see FIG. 14).

Further, at the time of paying out the game medal (J14), a predetermined payout sound is output (payout sound output). Here, for each of the first stop rotation cylinder to the third stop rotation cylinder, the symbols constituting the symbol combination of the winning combination are displayed (J7, J9, J12), so the stop reception (J6, J8, J10) ) Is performed at the timing within the number of shifted frames (pull-in point) described above.
<< Rotation failure pattern 1 after stop reception (Countermeasure pattern 3-1 (power off)) >>

Subsequently, pattern 1 (countermeasure pattern 3-1) relating to the combination of stop reception and rotation failure will be described with reference to FIG. 61 (b). The same reference numerals are given to the situations similar to the basic operation shown in FIG. 61A, and the description thereof will be omitted. In the example of FIG. 61 (b), it is assumed that there is a third cylinder stop reception (J10) and a power failure occurs in a situation (J11) in which the rotation cylinder stop state is entered (J16).

In such a case, as shown in FIG. 61 (b), the rotating cylinder moves to the stop position (J17), and the main CPU 81 executes the above-mentioned power off processing (see FIG. 19) (J18). After that, when the power was restored (J19), a winning combination was displayed on the third cylinder (described later) (J12), and the entire cylinder stopped as in the above-mentioned basic operation (FIG. 61 (a)). In the situation of suspension of rotation (J13), the payout of the number of game medals according to the winning combination is started (J14).

That is, the slot machine 10 does not determine whether or not the symbol has stopped at a regular position (whether or not the actual result is correct) and pay out. Then, if the processing in the main CPU 81 proceeds normally without any abnormality, the processing proceeds assuming that the result is correct, the symbol does not stop at the normal position, and the stop position of the symbol is apparently deviated. Even if it does, the payout will be made as usual.

The above-mentioned "winning combination display" is a situation in which the above-mentioned backlight LED for the rotating cylinder is lit or blinking in a predetermined color to illuminate the symbol corresponding to the winning combination from behind. It means (the situation where the backlight is being produced). In addition, the "winning combination display" is not limited to driving the backlight LED for the rotating cylinder, for example, displaying a combination using the light source 18 or the like (such as displaying an image of a symbol indicating the winning combination), and the front door. It is possible to include the driving of the light source for the effect described above in the part 11.

In addition to displaying the winning combination, it is possible to output a sound effect for notifying the winning (winning sound output). As the winning sound output, the above-mentioned payout sound output can also be used and shared by any one of them. Further, the winning combination display and the winning sound output performed by the sub control board 31 can be comprehensively referred to as, for example, "directing related to winning combination" or "directing winning combination". In addition, there is also a display unit that is managed by the main control board 61, and examples of this type of display unit include each display unit (acquired number display unit, replay game display unit, etc.) of the operation unit 14 (FIG. 1) described above. be able to. Then, among the display units managed by the main control board 61, a notification is provided on the display unit used when there is some kind of winning in the winning combination, such as the re-game display unit or the winning lamp (so-called WIN lamp). However, it is also possible to include it in the above-mentioned "directing related to the winning combination" and "directing the winning combination".

By doing so, if a power failure occurs between the 3rd stop reception (J10) and the winning combination display (J12) of the 3rd stop, unexpected operation will occur after the power is restored. It is possible to prevent this from happening, and it is possible to reliably execute the winning combination display and payout related to the third stop rotation cylinder.

Note that FIG. 61B shows an example in which the power supply is cut off (J16) after the third body stop reception (J10) is performed. However, for example, the information of the third body stop reception may be updated between the detection of the power failure and the stop of the operation of the main CPU 81. Then, in this case, after the start of the power off processing (J18), there is a third body stop reception (J10), and the power is restored based on the information of the third body stop reception (J10) at this time. It is possible to assume a situation where later processing is performed.
<< Rotation failure pattern 2 after reception of stop (Countermeasure pattern 3-2 (other than power off)) >>

Subsequently, a pattern (countermeasure pattern 3-2) relating to the combination of the stop reception and the rotation failure will be described with reference to FIG. 61 (c). The same reference numerals are given to the situations similar to the basic operation shown in FIG. 61A, and the description thereof will be omitted. In the example of FIG. 61 (c), it is assumed that there is a third cylinder stop reception (J10) and a rotation failure occurs due to a factor other than a power failure in a situation (J11) in which the rotation cylinder stop state is entered. Yes (J21). As the mode of rotation failure here, as in the case of the rotation failure pattern 1 (countermeasure pattern 2-1) in which the rotation cylinder to be the third stop rotation cylinder is accelerating the rotation cylinder, the motor is out of step or other. It can be illustrated that the rotating cylinder cannot operate as planned due to a factor. In addition, as a mode of rotation failure when the rotation of this countermeasure pattern 3-2 is stopped, the rotation speed is not constant in a situation where the rotation of the rotating cylinder should be performed at a constant speed, or the control brake is not effective and normal. Examples include those that cannot decelerate.

In such a case, when a rotation failure of the rotating cylinder is detected (J21), the symbol to be stopped on the effective line is apparently (on the surface) unable to reach the target effective line (J22). ). 60 (b) and 60 (c) are for showing an example of a situation where a stopped symbol is displaced, and FIG. 60 (b) shows an operation (basic operation) in a normal case, and FIG. c) shows the operation when the design is displaced. Both FIGS. 60 (b) and 60 (c) show the operation when the symbol whose symbol number is "10" is stopped.

Then, in a normal case, as shown on the left side of FIG. 60 (b), when there is a third cylinder stop operation, stop control is performed for the rotating cylinder stepping motor, and the corresponding rotation speed of the rotating cylinder is fixed. After shifting from the constant speed of the rotating cylinder drive state number 4 which is the high speed state to the deceleration start state of the rotating cylinder drive state number 3 which is also the constant speed state and moving to the target position, the brake is applied. It shifts during deceleration of the rotating cylinder drive state number 2. At this time, for example, assuming that the position corresponding to the 8th step of the symbol whose symbol number is "10" is stopped on the effective line, the rotating cylinder is in a rotation position several steps before the 8th step. Brake control of the stepping motor (here, all four phases described above are turned on). Then, due to factors such as inertial force during rotation, the rotating cylinder stops when the eighth step is reached. When the rotating cylinder is stopped, the main CPU 81 holds information corresponding to the symbol of the symbol number "10" as the information of the stop symbol, and the stop symbol on the predetermined effective line seen by the player is also included. , The original symbol number "10" is used.

That is, as shown in FIG. 60 (b), when it is normal, the symbol recognized as being controlledly stopped by the main CPU 81 (here, the symbol with the symbol number "10") and on the predetermined effective line. There is no discrepancy with the symbol that is actually stopped (here, the symbol with symbol number "10"), and both are in agreement.

On the other hand, in the example in which the defect shown in FIG. 60 (c) occurs, the cause of the rotation failure has occurred, and the symbol whose symbol number is "10" has not reached the target stop position. The rotating cylinder is stopped. Then, in the example of FIG. 60 (c), the position corresponding to the symbol of the symbol number "9" (for example, the position corresponding to the 16th step of the symbol of the symbol number "9") stops on the effective line. It has become.

When the rotation failure occurs in this way, the symbol recognized as stopped by the main CPU 81 in terms of control is the symbol with the symbol number "10", but the symbol is apparently effective. It may not be possible to determine whether the symbol with symbol number "10" or the symbol other than the symbol with symbol number "10" (here, the symbol with symbol number "9") is stopped on the line. , The symbol with symbol number "9" may be stopped. Then, there is a discrepancy between the control stop symbol and the apparent stop symbol, and the two are inconsistent. In addition, although the symbol of symbol number "10" is generally located on the target effective line, it is considered that the symbol is displaced even if it is slightly deviated from the normal stop position. Can be done.

Then, in the countermeasure pattern 3-2 shown in FIG. 61 (c), the third stop rotation cylinder does not reach the planned rotation position (regular stop position) as in the example of FIG. 60 (c) described above. Even as it is (J23), the backlight LED for the rotating cylinder is driven to display the above-mentioned winning combination. Here, the winning combination display is not limited to the above-mentioned winning combination effect in a broader sense. Then, as in the above-mentioned basic operation shown in FIG. 61 (a), the situation (J13) in which all the medals are stopped is reached, and after that, the payout of the number of game medals according to the winning combination is started. Is done (J14).

That is, in the example of the countermeasure pattern 3-2 shown in FIG. 61 (c), even if the symbol related to the winning combination deviates from the original stop position, the winning combination is displayed as in the case where there is no rotation defect, and the game is played. It is designed to pay out medals. And this is the same even when the symbol to be stopped has passed the normal stop position.

By doing so, if a rotation failure occurs due to a factor other than power failure between the 3rd stop reception (J10) and the 3rd stop turn display (J12), an unexpected rotation failure occurs. It is possible to reliably display the winning combination related to the third stop rotation and pay out the game medal without performing any operation. Then, even if the winning combination is displayed in a state where the symbol combination is not properly configured and an inconsistency occurs in appearance (appearance or surface), control is performed so as not to be disadvantageous to the player. Is possible.

Here, the function of paying out when a problem occurs like the above-mentioned countermeasure pattern 3-1 and the above-mentioned countermeasure pattern 3-2 is more effective for a symbol combination having a pull-in rate of 100% (PB = 1). It is believed that there is. That is, in the slot machine 10, for the so-called common bell (bell that is established regardless of the push order) and replay (replay) symbol combination, the order of the first stop button 24L to the third stop button 24R or The symbol arrangement of each of the rotating cylinders 51L to 51R is determined so that the symbol combination is always displayed even if the button is pressed at the timing.

For this reason, even if the symbols do not stop at an apparently appropriate position due to a problem such as step-out or power failure, the symbols are properly aligned under the control of the CPU 81, for example, watermelon or cherry. It is more likely to occur than symbols and symbol associations for which PB = 1 is not set. Therefore, for the winning combination with PB = 1, the function of the countermeasure pattern 3-1 and the function of the countermeasure pattern 3-2 are even more effective than when the winning combination with PB = 1 is applied. It is thought that it can be used for.

The countermeasure pattern 3-1 and the countermeasure pattern 3-2 have been described by taking the third stop as an example, but the same processing can be performed for the first stop and the second stop. is there. That is, even if a rotation failure occurs at least one of the first stop and the second stop, and the symbols related to the first stop and the second stop do not stop at the normal positions, the winning combination is controlled. If is satisfied, it is conceivable to pay out.

Further, the countermeasures against the rotation failure at the time of receiving the stop are not limited to those exemplified as the countermeasure pattern 3-1 (FIG. 61 (b)) and the countermeasure pattern 3-2 (FIG. 61 (c)). It is also possible to adopt correspondence. For example, when the power is restored or when a rotation failure other than power failure is detected, the rotating cylinder (here, the third stop rotating cylinder) is rotated so that the initial position (initial position) related to the rotation of the rotating cylinder can be detected. , Based on the detected initial position information, it is also possible to stop the rotating cylinder at the planned original stop position (the position where the winning combination symbol is stopped on a predetermined effective line).

Further, for example, it is conceivable to adopt a control mode in which the number of shifted frames (pull-in point) described above does not become constant when the power is restored. For example, information on the predetermined number of shifted frames (here, 3 symbols) is held in the RWM, and using this information, the number of frames for a part of the shifted frames (here, 2 symbols) is used. Consider the situation where the pull-in is taking place.

When the power is cut off in this situation and the power is restored after that, the information about the number of frames (2 symbols) that have already been pulled in is not stored, and the above-mentioned number of shifted frames (3 symbols) is stored again. Is pulled in. As a result, a total of 5 symbols (2 symbols + 3 symbols) are pulled in before and after the power is turned off. In addition, if the power is cut off while one symbol is being pulled in, by pulling in three symbols again after the power is restored, a total of four symbols (1 symbol + 3) before and after the power is turned off. The number of symbols) will be pulled in. In this way, the symbol displayed as stopped after the power is restored may differ depending on the timing of the power off when the stop is accepted.
<Countermeasures for problems related to winning judgment (countermeasure pattern 4)>

Next, the relationship between the winning judgment and the defect will be described. First, the "winning determination" referred to here can be performed in the display determination (S66) of the game progress main process (see FIG. 14), as in the above-mentioned countermeasure pattern 3. Further, here, it is assumed that a small winning combination is established (here, a bell with PB = 1 is established) by "winning judgment". This "small winning combination" means that the winning combination is won by the combination lottery, and the combination of symbols corresponding to the winning combination is stopped on the valid line.

In addition to turning off the power, the "defect" illustrated here includes opening the door, operating the setting key, or inserting a game medal in a non-regular (non-regular) procedure. Of these, door opening means the above-mentioned door opening error (error related to door opening) in which the front door portion 11 is unlocked and opened.

Further, as a basic operation here, when a small winning combination is established (bell is established) and the stop button related to the above-mentioned third stop rotation cylinder is pressed, the game medal is paid out (including storage). Can be mentioned. Then, in this basic operation, when the game medal is paid out, the winning combination display (backlight effect) and the winning sound output are performed. Here, pressing the stop button related to the third stop rotating cylinder is hereinafter referred to as "third stop pressing". Further, releasing the stop button by releasing the finger from the stop button related to the third stop pressing is hereinafter referred to as "release" or "third stop pressing release".
<< Correspondence to payout across power interruptions (countermeasure pattern 4-1) >>

As a countermeasure pattern 4-1 related to countermeasures against defects in the winning judgment (countermeasure pattern 4), it is possible to consider a countermeasure against a situation in which the processing from the establishment of a small winning combination to the payout of a game medal is performed across a power failure. it can. Furthermore, some situations can be assumed as this countermeasure pattern 4-1.
<< Correspondence to power off and power recovery while pressing the 3rd stop (countermeasure pattern 4-1-1A) >>

For example, it is possible to consider a case where the power is turned off and the power is restored in the situation where the third stop is pressed when the bell is hit as a small role. Hereinafter, countermeasures against such a complex situation will be referred to as "countermeasure pattern 4-1-1A". In addition, as the situation where the third stop pressing is detected, the player releases the pressing operation in a short time (less than 0.5 seconds) by the normal pressing operation, and the player continues the pressing operation longer than usual. The situation where the third stop is pressed due to some kind of fraud (in the case of a short time and the case of a long time), and the stop button sensor 49 of the third stop button and the third stop button (Fig. The situation where the signal indicating the pressed state is continuously output due to the malfunction of 3) can be mentioned. FIG. 62A schematically shows the countermeasure pattern 4-1-1A. In FIG. 62A, the situations of the start lever operation, the first stop, the second stop, and the third stop are shown in order from the left end in the figure. Then, in the example of FIG. 62A, the power is cut off in the situation where the third stop (the third stop is pressed).

Further, the power is restored in a situation where the third stop pressing is continued without releasing the finger, for example, from the stop button, and the third stop pressing is continued even after the power is restored. After that, the third stop pressing release is performed, and the third stop pressing release is detected. Further, in the example of FIG. 62 (a), although not shown, the game medal is paid out with the release of the third stop pressing in the situation where the winning combination such as a bell is won. It is also conceivable that the power supply will be cut off while the third stop is continuously pressed. Then, in this case, it is possible to define a process such as executing both the winning combination display (backlight effect) and the winning sound output, executing either one, or not executing both.

By doing so, it is possible to give priority to the interests of the player with respect to the power failure in a very short time when the small winning combination is established. In addition, by not displaying the winning combination or outputting the winning sound, it is possible to distinguish the notification mode of the small winning combination from the normal mode (unusual mode), and if the power failure is intentional due to fraudulent activity. Even if there is, it is possible to give a chance to notice the cheating to the game clerk passing by and the players around.

Here, as described above, in the game progress main process (FIG. 14), the process of checking the stop of all rounds (S64) and the process of paying out the game medal by winning a prize (S67) are executed. Then, as described above, in the all-round body stop check process (S64), it is not in a state where any of the stop buttons 24L to 24R is continuously operated, and it is checked whether or not these operations are properly completed. Will be Then, the determination as to whether or not the above-mentioned third stop pressing is continued and whether or not it has been released can be performed in the all-time body stop check process (S64).

Regarding this countermeasure pattern 4-1-1A, it is possible to determine the relationship with the sound effect (third stop sound) for notifying the third stop. For example, when there is a third stop pressing release after the power is restored, it is possible to output the above-mentioned third stop sound (output the third stop sound).

Further, it is also possible to determine the relationship between the countermeasure pattern 4-1-1A and the display performed by, for example, the effect unit 18. More specifically, for example, in the case where the power is cut off during AT (assist time), the assist display indicating the stop button for which the third stop should be performed is displayed on the effect unit 18 or the like when the power is restored. It is conceivable to re-execute the display that eliminates.

Further, regarding this countermeasure pattern 4-1-1A, when the power is restored, the above-mentioned three-insertion button (MAX bet button) of the main input unit 26 is subjected to the process of making the internal LED emit light to illuminate the button. It is possible to perform processing such as not accepting the button operation of the three-sheet insertion button.

Further, regarding this countermeasure pattern 4-1-1A, even if there is a third stop pressing release after the power is restored, for example, other various buttons managed by the main CPU 81 (first stop) while the third stop pressing is continued. , 2nd stop, bet, start, etc.) Even if you press at least one of them and then release the 3rd stop press release, you can prevent the payout from being executed. That is, it is possible to set the payout condition that none of the various buttons of the main system is operated.

Not limited to this, even if any of the predetermined buttons is operated, it is conceivable to pay out if the other predetermined buttons are not operated. For example, when the power is restored, if one of the stop buttons is being pressed and the start lever is operated, the payout will not be performed as it is, but all the stop buttons will be released in this situation. For example, it is possible to pay out. It is also conceivable that when the start lever and one of the stop buttons are both in the ON state, the payout is performed when the stop button is released.

Further, regarding this countermeasure pattern 4-1-1A, it is conceivable that the game medal is paid out even if the third stop pressing release is not performed. Further, in this case, it is possible to define a process such that the winning combination display (backlight effect) and the winning sound output are not executed. More specifically, even if the third stop is being pressed when the power is restored, the game medal payout process (S67) by winning the game progress main process (FIG. 14) is performed after the power return process (FIG. 21). For example, it can be executed and paid out.

Further, when an error occurs, the cause of the error is removed, and even if the release operation of operating the error release button (here, the setting / reset button 69) is performed as described above, it is possible not to pay out. For example, consider the above-mentioned HE error (an error when it is determined that the game medal in the game medal payout device 63 is empty) as a situation that can be combined with the third stop pressing, the power off, and the payout of the game medal. Can be done. That is, when the power is cut off while the third stop is pressed, the third stop is pressed when the power is restored, and an HE error occurs in the situation where there is a payout, the game medal is replenished while the third stop is pressed. Even if the error factor is removed and the error release button (setting / reset button 69) is operated, the error is not released and the payout is not performed because the third stop is being pressed. Can be exemplified.
<< Correspondence to the release of pressing the third stop before the power is restored (countermeasure pattern 4-1-1B) >>

Subsequently, it is also possible to determine the processing for the case where the third stop pressing release occurs while the power is turned off. FIG. 62B shows a countermeasure pattern 4-1-1B when there is a third stop pressing release before the power is restored (during power off). In this countermeasure pattern 4-1-1B, the situations up to the operation of the start lever 25, the first stop, the second stop, the third stop (pressing the third stop), and the occurrence of power failure are shown in FIG. 62 (a). This is the same as the countermeasure pattern 4-1-1A. However, there is a third stop press release while the power is off, and then the power is restored (power restored). In this case, although not shown, it is conceivable that the payout will be executed when the power is restored.

Further, even when the third stop pressing release is performed while the power is turned off, it is possible to determine the relationship with the third stop sound or the like. More specifically, when there is a third stop pressing release while the power is off, it is possible to pay out when the power is turned on (when the power is restored) and output a third stop sound when the power is restored.

In the countermeasure patterns 4-1-1A and the countermeasure pattern 4-1-1B shown in FIGS. 61 (a) and 61 (b), the relationship between the third stop and the power off and power recovery has been described. Not limited to, for example, when there is a power off and power return between the start lever operation and the first stop, or between the first stop and the second stop (or between the second stop and the third stop). It is also possible to assume a case where the power is turned off and the power is restored. Then, in these cases, it is possible to set the same relationship as the relationship between the third stop and the power off / return.
<< Correspondence to pressing the third stop, turning off the power, and opening the door (countermeasure pattern 4-1-2) >>

Subsequently, as another pattern of the countermeasure pattern 4-1 can be considered as a countermeasure (countermeasure pattern 4-1-2) in which the third stop pressing and the power off are further combined with the door opening. More specifically, when the bell is hit as a small role, the power is turned off in the state of pressing the third stop, and when the power is restored in the state of pressing the third stop, the front door portion 11 is closed and the door opening is released. Can be considered when it is done. Also in this case, it is possible to define a process such that the payout is executed and the winning combination display and the winning sound output are not executed in the same manner as the above-mentioned countermeasure pattern 4-1.

By doing so, it is possible to obtain the same action and effect as the above-mentioned countermeasure pattern 4-1-1. Further, even if the power off is accompanied by an illegal door opening, if the front door portion 11 is closed, the notification mode is only changed to the unusual mode without hindering the progress of the game. It is possible to perform processing such as stopping at. Here, the door opening also occurs in the above-mentioned setting change and setting value confirmation.
<< Correspondence to power recovery and door opening after the release of pressing the 3rd stop (countermeasure pattern 4-1-3) >>

Next, as another pattern of the countermeasure pattern 4-1 (countermeasure pattern 4-1-3), consider a countermeasure in the case where the power is cut off and the third stop is released (released) and the power is cut off. Can be done. More specifically, in the above-mentioned countermeasure pattern 4-1-2, after the power is turned off in the situation of pressing the third stop, the stop button related to the pressing of the third stop is released instead of the situation of pressing the third stop. Then, it is possible to consider the case where the power is restored. In this case, as in the above-mentioned countermeasure pattern 4-1-2, even if the front door portion 11 is closed after the power is restored and the door opening is released, the payout is executed and the winning combination display and the winning sound output are displayed. It is possible to define processing such as not executing.

By doing so, processing assuming more situations will be performed. That is, when the power outage is resolved in a short time such as a momentary power outage, it is relatively easy to assume a situation in which the power is cut off and the power is restored while the third stop is pressed. However, in many cases, even if the power is cut off while the third stop is pressed, it is considered that the power is restored after the stop button is released. Therefore, by adopting this countermeasure pattern 4-1-3, it is possible to deal with more situations regardless of whether or not the door opening is due to fraudulent activity. << Correspondence to payout across set value confirmation (countermeasure pattern 4-2) >>

Next, it is possible to consider a countermeasure (countermeasure pattern 4-2) for payout that straddles the confirmation of the set value. This "payment across the set value confirmation" represents a situation in which the processing from the establishment of the small winning combination to the payout of the game medal is performed across the confirmation of the set value (confirmation of the set value). Further, as this countermeasure pattern 4-2, some situations can be assumed.
<< Correspondence to pressing the 3rd stop and turning on the setting key (countermeasure pattern 4-2-1) >>

First, as described above, the setting value confirmation is performed when the power of the slot machine 10 is ON, the door switch and the setting door switch are ON, and the setting key is not bet. By operating the setting key so that the switch 68 (FIG. 4) is turned on, the mode shifts to the setting confirmation mode (the setting value confirmation state). Then, as the first countermeasure (countermeasure pattern 4-2-1) in this countermeasure pattern 4-2, for example, when the bell is hit as a small role, the power is not turned off in the situation of pressing the third stop, and the setting is made. A situation where the key is turned on can be assumed.

Here, as a condition for enabling the setting value confirmation as described above, the setting door switch state is excluded, and the setting value can be confirmed if the two switches, the door switch and the setting key switch, are in the ON state. It may be in such a state.

Further, although it is assumed that the front door portion 11 is open (door open) here, the timing of opening the door may be before, at the same time, or after the start of pressing the third stop. Then, it can be considered that the third stop is released after the front door portion 11 is closed and the door opening is released (after the door is closed) in the situation where the third stop is pressed. ..

In this case, the setting key remains ON, but it is possible not to shift to the setting value confirmation state as described above. Further, it is conceivable to enable the progress of the game so that the next game and the subsequent games (games after the next game) can be performed. Then, when a symbol combination other than the replay is displayed in the game, the set value can be confirmed by opening the door. That is, the transition to the set value confirmable state is performed when all three conditions of ON of the setting key, opening of the door, and no betting setting are satisfied, and one of these is missing. For example, it is possible not to shift to the state where the set value can be confirmed.

When the state shifts to the set value confirmable state, it is possible to notify that the set value can be confirmed. As the notification that the set value can be confirmed, the display of the set value on the setting display LED 66 (FIG. 4) as described above, the display of characters and images on the effect unit 18 (FIG. 1), and the like are exemplified. be able to. Further, when the door is opened during the game (for example, during the period from the betting setting to the winning determination), it is possible not to shift to the set value confirmation state.

By doing so, the relationship between the third stop, the opening of the door, and the confirmation of the set value can be appropriately determined in advance, and it is possible to prevent an unexpected operation from being performed. Then, it becomes possible to confirm the set value when it is appropriate.

Here, when shifting to the setting confirmation mode (setting value confirmation state), it was necessary for multiple switches to be in the ON state, but when exiting the setting confirmation mode, only the setting key switch is confirmed. It has become so. That is, it can be said that the condition for ending the setting confirmation mode is relaxed as compared with the condition for starting.

It is also possible to establish the following relationships with respect to this countermeasure pattern 4-2-1. For example, in the countermeasure pattern 4-2-1, as described above, when the front door portion 11 is closed and the door opening is released (after the door is closed), there is a third stop pressing release. Was assumed. However, unlike this, it is possible to assume a case where the third stop is released in a state where the set value can be confirmed without releasing the door opening. In this case, it is conceivable to make a payout and shift to a state where the set value can be confirmed after the payout is completed.

Further, after the payout is completed, it is conceivable that the effect unit 18 or the like does not display the setting value confirmation, but displays a mode different from the setting value confirmation status (normal display). Then, the game after the next game is impossible. As a mode in which the game after the next game is impossible, it is conceivable that the betting operation (betting setting operation) and / or the game medal insertion are both impossible. In this case, it is conceivable that the main CPU 81 is in a state where the set value can be confirmed. Then, when the door is opened, it is possible for the effect unit 18 or the like to display that the set value can be confirmed.

Further, regarding the case where the third stop pressing release is made in the state where the set value can be confirmed, it is conceivable to start the payout when the release is made. In this case, after the payout is completed, it is conceivable that the game can be played with the setting key ON without shifting to the set value confirmation state. Then, it is possible to play the game after that, but when the door is opened, it is possible to shift to the state where the set value can be confirmed.

Here, for example, when the bell is hit as a small medal, it is assumed that the power is not turned off and the setting key is turned on in the situation where the third stop is pressed. However, when the power is turned off, the power is turned on. Since the setting key is ON at the time of return, the information indicating that the setting change device has been activated and the small winning combination has been won is cleared, and it is possible that the game medal is not paid out after the power is restored.
<< Pressing the 3rd stop and responding to the status notification that the set value can be confirmed (countermeasure pattern 4-2-2) >>

Subsequently, as the second countermeasure (countermeasure pattern 4-2-2) in this countermeasure pattern 4-2, the front door portion 11 is closed and the door is opened as in the above-mentioned countermeasure pattern 4-2-1. Consider the case where there is a release of the third stop after it is released. After that, unlike the above-mentioned countermeasure pattern 4-2-1, the state shifts to the set value confirmable state, but it is possible not to notify that the set value can be confirmed. Other points can be processed in the same manner as the above-mentioned countermeasure pattern 4-2-1.

By doing so, it is possible to obtain the same effects of the invention as the above-mentioned countermeasure pattern 4-2-1. In addition, after the release of the third stop, by not notifying that the set value can be confirmed, the set value can be confirmed for those who illegally try to confirm the set value after the winning judgment. It is possible to keep something secret.

In the various countermeasure patterns in the countermeasure pattern 4-1 and the various countermeasure patterns in the countermeasure pattern 4-2 described so far, processing is performed for matters such as whether or not to pay out when a small winning combination is established, whether or not to confirm the set value, and the like. I am targeting. However, not limited to this, it is also possible to consider measures for matters such as the operation of the stop button, the possibility of replay, and the possibility of confirming the set value in the case of hitting the replay.

For example, when the power is cut off during the pressing of the third stop in the situation where the replay is hit and the power is restored, it is possible to restore the information indicating the right to play the replay game. Also, when the power is restored, if there is a third stop press release with the setting key ON, when the replay information is restored, it will be in the betting state, so even if other conditions are met, it will be set. It is possible to perform processing such as preventing the value from being confirmed.

In addition, regarding the handling of such replays, regarding the various countermeasure patterns (countermeasure patterns 4-3 to 4-9) described below, unless there is a particular contradiction or duplication, the establishment of a small winning combination is regarded as the establishment of a replay. It is possible to assume a countermeasure pattern by replacing the payout with a replay and assuming that the situation is betting after the power is restored.
<< Opening the door and responding to payout (Countermeasure pattern 4-3) >>

Next, as a countermeasure pattern 4-3, a countermeasure for a situation related to payout while the front door portion 11 (front door) is open can be considered. For example, when the small winning combination is established, if the third stop is released while the front door is open, it is possible to pay out. The timing of opening the door may be before, at the same time, or after pressing the third stop. In this case as well, it is possible to define processes such as displaying the winning combination and outputting the winning sound. By doing so, the relationship between the third stop, the door opening, and the payout can be appropriately determined in advance, and it is possible to prevent unexpected operations from being performed.
<< Support for opening doors and inserting game medals (countermeasure pattern 4-4) >>

As a situation related to the above-mentioned countermeasure pattern 4-3, a situation related to the insertion of a game medal while the front door portion 11 (front door) is open can be considered. For example, if a game medal is inserted while the front door is open, the inserted game medal can be detected as usual, the game medal can be counted, and the insertion indicator LED can be turned on. .. Further, in this case, it is possible to output sound (output of input sound) in association with the detection of the game medal. Further, not limited to this, it is possible not to output the input sound when the game medal is detected. By doing so, the relationship between opening the door and inserting the game medal can be appropriately determined in advance, and it is possible to prevent unexpected operations from being performed.
<Other measures related to measure pattern 4>
<< Correspondence to payout before the release of pressing the 3rd stop (countermeasure pattern 4-5) >>

In relation to the above-mentioned countermeasure pattern 4, for example, the following countermeasures can be taken. First, in the main flow at the time of power recovery (game progress main process (see FIG. 14)), it is possible to execute the payout process before confirming the presence or absence of the release of the third stop press.

As shown in FIG. 14, in the game progress main process, a process of checking the stop of all rounds (S64) and a process of paying out the game medal by winning a prize (S67) are executed. Then, as described above, in the all-round body stop check process (S64), it is not in a state where any of the stop buttons 24L to 24R is continuously operated, and it is checked whether or not these operations are properly completed. Will be Therefore, for example, the execution order of the all-round body stop check process (S64) and the game medal payout process (S67) by winning is changed, and the game medal payout process (S67) by winning is stopped all times. By performing this before the check process (S64), it is possible to execute the payout process before confirming the presence or absence of the release of the third stop press.

By doing so, when the power is restored, the payout process is prioritized over the check of the stop button, and the payout can be reliably executed regardless of the situation where the third stop is pressed. Then, it is possible to prevent an unexpected operation from being performed with respect to the operation accompanying the third stop pressing release.

In this case, in the case of normal payout without any trouble, the winning combination display and the payout sound output are both executed, and the third stop button is pressed from the power off (or before the power off). When the third stop button is released after the power is restored by pressing the button, it is possible not to execute both the winning combination display and the payout sound output.
<< Correspondence to door opening after the release of pressing the 3rd stop (countermeasure pattern 4-6) >>

Subsequently, in relation to the above-mentioned countermeasure pattern 4-2-1, after the release of the third stop button, even if the above-mentioned setting key is ON, the subsequent game can be continuously performed. It is possible. Then, in this case, even if the game start condition including the insertion of the game medal is satisfied, the main CPU 81 can be prevented from shifting to the setting checkable state.

More specifically, for example, after inserting a specified number of game medals (three in this case), the reels (rotating cylinders 51L to 51R) start rotating by operating the start lever 25, and the stop buttons 24L to 24R are operated. The corresponding reel stops. Furthermore, in games other than the establishment of replay, if the door is unlocked and the door is opened after the release of the third stop button, the setting value can be confirmed by turning on the setting key. To. On the other hand, in the game in which the replay is established, the lock is unlocked and the door is opened after the release of the third stop button, and even if the setting key is turned on, it is not possible to shift to the state where the set value can be confirmed. Can be considered.

By doing so, it is possible to prevent an unexpected operation from being performed with respect to the operation accompanied by the third stop pressing release and the door opening.
<< Door opening and response to payout noise (countermeasure pattern 4-7) >>

Next, the relationship between the door opening and the payout sound will be described. Regarding the relationship between the door opening and the payout sound, it is possible to pay out the game medal and output the payout sound even while the door is open. However, when the notification sound when the door opening is detected (door opening notification sound) is output, if the door opening notification sound and the payout sound conflict (polymerize), the payout sound should not be output. It is possible. It is also possible to output the payout sound, but make the volume of the payout sound inaudible. By doing so, it is possible to prevent an unexpected operation from being performed with respect to the operation involving the opening of the door and the payout sound.
<< Pattern 1 related to door opening notification sound and payout sound (countermeasure pattern 4-7-1) >>

FIG. 63A illustrates a countermeasure pattern 1 (countermeasure pattern 4-7-1) relating to the combination of the door opening and the payout sound as described above. The upper part of FIG. 63A shows a normal operation (basic operation). Further, the middle part of FIG. 63A shows the mutual relationship when the payout occurs before the door is opened, and the lower part shows the mutual relationship when the payout occurs after the door is opened.

In the basic operation shown in the upper part of FIG. 63 (a), the front door portion 11 (front door) is in the closed state (not opened), and the output of the door opening notification sound indicated by "sound 1" is Not done. Then, in such a situation, when there is a third stop pressing release, the payout sound indicated by "sound 2" is output.

On the other hand, in the case where the payout occurs before the door is opened, which is shown in the middle of FIG. 63 (a), there is a third stop pressing release in the state where the front door portion 11 (front door) is closed. As shown in "Sound 2", the payout sound is output. Then, for example, if the door is opened during the output of the payout sound, the door opening notification sound is output accordingly as shown in "Sound 1".

Further, in the case where the payout occurs after the door is opened, which is shown in the lower part of FIG. 63 (a), there is no output of the payout sound as shown in "Sound 2" at the stage of opening the door, and it is shown in "Sound 1". The door opening notification sound is output. Here, in the figure, the illustration is made so that the door opening notification sound is output at a predetermined timing after the door is opened. Then, when there is a third stop pressing release in the situation where the door is open, the payout sound is output as shown in "Sound 2". Here, there is a third stop pressing release during the output of the door opening notification sound, and the payout sound is also output during the output of the door opening notification sound. Then, the output of the payout sound ends after the output of the door opening notification sound ends.
<< Pattern 2 related to door opening notification sound and payout sound (countermeasure pattern 4-7-2) >>

Subsequently, FIG. 63 (b) shows another example (countermeasure pattern 4-7-2) of the relationship between the door opening and the payout sound. FIG. 63 (b) shows an example of a countermeasure pattern in which the door opening notification sound and the payout sound do not compete (polymerize) as described above. The upper part of FIG. 63A shows a normal operation (basic operation). This basic operation is the same as that shown in FIG. 63 (a). Further, as in FIG. 63 (a), the middle row in FIG. 63 (b) shows the mutual relationship when the payout occurs before the door is opened, and the lower row shows the payout after the door is opened. It is a mutual relationship when doing.

When payout occurs before the door is opened, which is shown in the middle of FIG. 63 (b), the "front door", "sound 1", and "third stop pressing release" are shown in FIG. 63 (a) above. Similar to the one shown. However, the payout sound of "sound 2" accompanying the release of the third stop pressing is terminated when the output of the door opening notification sound accompanying the subsequent door opening is started.

Further, in the case where the payout occurs after the door is opened, which is shown in the lower part of FIG. 63 (b), the "front door", "sound 1", and "third stop pressing release" are described in FIG. 63 (a) described above. It is the same as the one shown in. However, the payout sound of "sound 2" accompanying the release of the third stop pressing is started when the output of the door opening notification sound accompanying the subsequent door opening ends.

As for measures to prevent the door opening notification sound and the payout sound from competing with each other, for example, during a quiet period between intermittent messages such as "the door is open" in the door opening notification sound. It is also possible to output the payout sound. Further, in order to prevent the door opening notification sound and the payout sound from competing with each other, it is conceivable to measure the output period of the door opening notification sound and output the payout sound based on the measurement result.
<< Support for opening doors and clearing game medals (countermeasure pattern 4-8) >>

Subsequently, in the case of clearing the game medal while the door is open, it is possible to pay out when the clearing button is pressed in the main input section 26 (FIG. 1), and after the clearing is completed, a demo display can be performed in the production section 18 or the like. Is. It is also possible that even if the clearing button is pressed, the payment will not be made while the door is open. By doing so, it is possible to properly determine the relationship between opening the door and clearing the game medal in advance, and it is possible to prevent unexpected operations from being performed.
<< Support for combined door opening and input / release / clearing (countermeasure pattern 4-9) >>

Next, various possible modes of the combination of opening the door and charging / releasing / clearing will be described. Since the purpose of this section is to provide a comprehensive explanation of various composite modes, the ones described so far are included in some of them. In addition, here, the processing in each case is the case where the game medal is inserted while the door is open, the game medal is paid out while the door is open, and the game medal is settled while the door is open. Aspects will be described.

First, when a game medal is inserted while the door is open, it is conceivable to output the input sound and detect the inserted game medal (recognize the game medal). Further, if the game medal is paid out while the door is open, it is conceivable that the payout sound is output and the payout is started with the release of pressing the third stop. Further, if the game medal is cleared while the door is open, it is conceivable that the sound is not output and the payout is started when the clear button is pressed. Then, it is conceivable to configure a slot machine in which these processing modes are combined.

It is also possible that if a game medal is inserted while the door is open, the inserted coin is not recognized. Further, if the game medal is paid out while the door is open, it is possible not to pay out. Furthermore, if the game medal is settled while the door is open, it is possible not to pay out.

In addition, it is possible to take measures even when the settlement of the game medal and the confirmation of the set value are combined. For example, while the setting value is being confirmed (when the setting key is ON), the payout is not performed even if the clearing button is pressed, but when the small winning combination is won, the 3rd stop is being pressed and the setting key is ON. In such a situation, when the third stop button is released, the payout can be performed, and then the set value confirmation mode (set value confirmation state) can be entered. In other words, normally, while the set value can be confirmed, the payout is not performed even if the clearing button is pressed, but if the third stop is pressed, it is possible to pay out because it is before the transition to the set value confirmable state. It is conceivable to do. In this case, even if the setting key is ON, there are cases where the payout is performed and cases where the payout is not performed. As a result, even if the setting key switch is turned on while the third stop button is being pressed, the setting key switch will be turned on due to a failure or the like because there will be a payout when the third stop button is released. However, the payout can be given so that the player is not disadvantaged.

Although the present invention has been described above by taking the slot machine 10 as an example, the present invention is not limited to this, and the present invention can be applied to, for example, various other slot machines. Further, the present invention is not limited to slot machines, and can be applied to other types of gaming machines such as pachinko gaming machines. Further, the present invention can be applied to, for example, a casino machine installed in a casino facility.

10 slot machine, 11 front door part, 12 housing part, 15 times body display part,
16 game medal payout exit, 17 saucer, 18 production department, 21 game medal slot,
24L-24R 1st stop button-3rd stop button, 25 start lever,
31 Sub-control board, 51L-51R 1st to 3rd cylinder, 61 Main control board,
62 setting unit, 68 setting key switch, 81 main CPU.

Claims (1)

With reel
With the start switch
With a stop switch
Equipped with internal lottery means
When the start switch is operated, the acceleration process for rotating the reel can be executed for a predetermined period of time .
If an event occurs in which the power supply to the game machine is cut off and then a power outage is detected, the power outage processing can be executed.
If the acceleration process for rotating the specific reel is started, the power supply cutoff process is executed by the elapse of the predetermined period, and then the power is restored after the specific reel is stopped, the rest of the predetermined period. It is configured so that the acceleration process for rotating the specific reel can be continuously executed during the period of.
A predetermined result is determined as a determination result of the internal drawing means, and an operation of a predetermined stop switch for first stopping the predetermined reel in a situation where all the reels are rotating is detected at a predetermined timing. When the predetermined symbol corresponding to the predetermined result is stopped at the predetermined position and then all the reels are stopped and the predetermined symbol combination corresponding to the predetermined result is stopped in the predetermined situation, the predetermined symbol combination is used. It is configured to be able to grant the corresponding game medium,
The predetermined result is determined as the determination result of the internal lottery means, and the operation of the predetermined stop switch for first stopping the predetermined reel in a situation where all the reels are rotating is performed at the predetermined timing. The predetermined symbol corresponding to the predetermined result in a predetermined situation in which the predetermined symbol corresponding to the predetermined result is not stopped at the predetermined position and all the reels are subsequently stopped despite being detected. A gaming machine characterized in that a gaming medium corresponding to the predetermined symbol combination can be applied even when the combination is not stopped.

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