JP2013165869A - Game machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a false recognition of illegal alternation on a control board.SOLUTION: In a game machine 10 including a performance control board 310 having a wiring pattern formed on both sides, the performance control board 310 includes a mount area A where an inspection device connection circuit configuration device (debug device connection circuit 315) can be mounted for transmitting and receiving information on a performance control command transmitted between a first control means (1st CPU 311) and a second control means (2nd CPU 312) disposed on the performance control board 310, to and from a performance display inspection device (debug device 350) to be used for inspecting the first control means and the second control means outside the game machine 10. The mount area A is provided on an invisible surface on the performance control board 310, while the performance control board 310 has been mounted on the game machine 10.

Description

  The present invention provides a display device capable of executing a display game in which a plurality of symbols are variably displayed, a game control device including a game control board for overall control of games, and the display game executed in the display device The present invention relates to a game machine including an effect control device including an effect control board that controls an effect related to the above.

Conventionally, there is a pachinko machine as a representative example of a gaming machine. This pachinko machine includes a game control device that includes a game control board that controls the game in an integrated manner, and an effect control device that includes an effect control board that controls the effects of the display game. is there.
Although the same control boards (game control boards, production control boards, etc.) mounted on the pachinko machine are used at the time of development and mass production sales, the parts mounted on the board itself are at the time of development. It is known that there are parts that are only mounted and not mounted at the time of mass production and sales (see Patent Document 1).

JP 2011-183102 A

  However, as described in Patent Document 1, when there is a component mounted on the control board only at the time of development but not at the time of mass production and sales, a hole (perforation) in the board pattern at the mounting position of the component mounted only at the time of development. ) Etc. will be lined up in the amusement hall in a state of being crushed with solder at the time of mass production and sales. For this reason, when a hall staff who does not know that the number of components mounted on the control board differs between development and mass production sales, when the board pattern collapsed with the solder is seen, the components originally mounted are I often misunderstood that illegal tampering was done.

  An object of the present invention is to provide a gaming machine that can prevent a misunderstanding that an unauthorized modification to a control board has been performed.

In order to solve the above problems, the invention described in claim 1
A display device capable of executing a display game in which a plurality of symbols are variably displayed;
A game control device having a game control board for overall control of the game;
In a gaming machine including an effect control device including an effect control board that controls an effect on the display game executed in the display device,
The production control board is:
A double-sided board having wiring patterns on both front and back sides,
A first control means equipped with a first arithmetic processing unit for effect control based on a control command from the game control device;
Second control means equipped with a second arithmetic processing unit that performs display control in the display device based on an effect control command from the first control means;
An effect display inspection apparatus that uses information related to the effect control command transmitted between the first control means and the second control means for the inspection of the first control means and the second control means outside the gaming machine. An attachment area to which the inspection device connection circuit configuration means for transmitting and receiving can be attached; and
With
The attachment area is provided on an invisible surface of the effect control board in a state where the effect control board is attached to the gaming machine.

  According to the first aspect of the present invention, in the state where the effect control board is attached to the gaming machine, the attachment region to which the inspection device connection circuit constituting means can be attached is provided on the invisible surface of the effect control board. Therefore, even if the inspection device connection circuit configuration means is removed at the time of mass production and sales, the removed part is in a position where it is difficult to see, so an unauthorized modification was made to remove the originally mounted parts. This can make it difficult to make a mistake.

The invention according to claim 2 is the gaming machine according to claim 1,
The production control board includes an inspection connection unit that can be attached to and detached from an end of a cable that is communicably connected to the production display inspection device.
The inspection connecting portion is
The production control board is mounted on an invisible surface of the production control board in a state where the production control board is attached to the gaming machine.

According to the invention described in claim 2, by providing the connecting portion for inspection that can be attached to and detached from the end of the cable that is communicably connected to the effect display inspection device, for example, the effect display inspection device can be facilitated when developing a gaming machine. Will be able to connect to.
In addition, in the state where the production control board is attached to the gaming machine, the inspection connection part is mounted on the invisible surface of the production control board, so even if the inspection connection part is removed at the time of mass production sales, Since the removed part is in a position where it is difficult to see, it is possible to prevent a misunderstanding that an unauthorized modification that removes the originally mounted component has been performed.

A third aspect of the present invention is the gaming machine according to the second aspect,
The inspection connecting portion is arranged so that a coupling direction with an end portion of a cable that is communicably connected to the effect display inspection device is parallel to the effect control board.

  According to the third aspect of the present invention, the inspection connecting portion is disposed so that the coupling direction with the end portion of the cable that is communicably connected to the effect display inspection device is parallel to the effect control board. Even if the inspection connecting portion is mounted on the invisible surface of the production control board, the production display inspection apparatus can be easily connected from the side of the production control board.

The invention according to claim 4 is the gaming machine according to claim 1,
The production control board includes an inspection connection unit that can be attached to and detached from an end of a cable that is communicably connected to the production display inspection device.
The inspection connecting portion is mounted on a visually recognizable surface of the effect control board in a state where the effect control board is attached to the gaming machine.

  According to the invention described in claim 4, it is needless to say that the same effect as that of the invention described in claim 1 can be obtained, and in the state where the effect control board is attached to the gaming machine, the inspection connecting portion is Since it is mounted on the visually recognizable surface of the production control board, it is possible to easily connect the production display inspection device, for example, when developing a gaming machine.

The invention according to claim 5 is the gaming machine according to any one of claims 1 to 4,
The production control board is:
A notch for separating the attachment region is formed.

  According to the invention described in claim 5, since the mounting area to which the inspection device connecting circuit constituting means can be attached can be separated at the time of mass production and sales, the illegal modification that removes the originally mounted parts has been performed. It can make it difficult to make a mistake.

The invention according to claim 6 is the gaming machine according to any one of claims 2 to 5,
The production control command is configured to include inspection data used for the inspection by the production display inspection device,
The first control means includes
A connection determination means for determining whether or not the effect display inspection device is connected to the inspection connection unit;
When the connection determination means determines that the effect display inspection device is not connected to the inspection connection unit, the effect control command transmitted between the first control means and the second control means Does not include the inspection data.

According to the sixth aspect of the present invention, when the connection determining means determines that the effect display inspection device is not connected to the inspection connection unit, the effect control command does not include the inspection command. can do.
Therefore, when the production display inspection device is not connected, it is possible to prevent the processing using the inspection data which is not required from being performed between the arithmetic processing devices. The processing load can be reduced.

The invention according to claim 7 is the gaming machine according to claim 6,
The connection determination means includes
When a connection signal output when the production display inspection device is connected to the inspection connection portion is input to the first control means via the inspection connection portion, the inspection connection portion It is determined that an effect display inspection device is connected.

  According to the seventh aspect of the present invention, when the production display inspection device is connected to the inspection connection portion, the connection signal indicating that the connection is indicated via the inspection connection portion is the first control means. Therefore, it is possible to appropriately determine whether or not the effect display inspection apparatus is connected.

  According to the present invention, in the state where the production control board is attached to the gaming machine, the attachment area to which the inspection device connection circuit configuration means can be attached is provided on the invisible surface of the production control board. Even if the connection circuit configuration means is removed at the time of mass production and sales, the removed part is in a position where it is difficult to see, so it is said that an unauthorized modification that removes the parts originally mounted was done. Can make mistakes difficult.

It is a perspective view which shows one Embodiment of the game machine which concerns on this invention. It is a perspective view which shows the state which open | released the glass frame of the game machine of embodiment. It is a front view which shows the structural example of the game board in the game machine of embodiment. It is a back view of a gaming machine. It is a back view of a game board, and is a figure which shows the state which removed the cover of the back side of an effect control apparatus. It is a block diagram which shows the structural example of the control system and game control apparatus which are provided in the back surface of the game machine of embodiment. It is a block diagram which shows the structural example of the presentation control apparatus in the control system of FIG. (A) is a front view of an effect control apparatus, (b) is a back view of an effect control apparatus. (A) is an exploded perspective view of the production control device when the production control device is viewed from the front side, and (b) is an exploded perspective view of the production control device when the production control device is viewed from the back side. is there. (A) is a front view of an effect control board, (b) is a back view of the effect control board. (A) is a front view of the effect control board of the modification 1, (b) is a back view of the effect control board. (A) is a perspective view which shows the front side of the production control board of the modification 2, (b) is a perspective view which shows the back surface side of the said production control board, (c) is a back view of the said production control board. (D) is a side view of the effect control board. (A) is a front view of the effect control board of the modification 3, (b) is a back view of the effect control board. It is a flowchart which shows the first half part of the main process. It is a flowchart which shows the second half part of the main process. It is a flowchart which shows a timer interruption process. It is a flowchart which shows special figure game processing. It is a flowchart which shows 1st main processing. It is a flowchart which shows 1st scene control processing. It is a flowchart which shows 2nd main processing. It is a flowchart which shows a normal game process. It is a flowchart which shows V blank interruption processing. It is a flowchart which shows a communication permission process. It is a figure explaining an example of the determination method of whether the debugging apparatus is being mounted. It is a figure explaining the command transmitted between 1stCPU and 2ndCPU at the time of a debugging apparatus connection, between 1stCPU and a debugging apparatus, and between 2ndCPU and a debugging apparatus. It is a figure explaining the command transmitted between 1stCPU and 2ndCPU when a debugging apparatus is not connected. It is a figure explaining the communication protocol between 1stCPU and 2ndCPU. It is a figure explaining a power-on packet. It is a figure explaining a customer waiting packet. It is a figure explaining a customer waiting demo packet. It is a figure explaining a change packet (continuation 0th time). It is a figure explaining a change packet (continuation 1st time). It is a figure explaining a change packet (continuation 2nd time). It is a figure explaining a decoration design stop packet. It is a figure explaining a fanfare packet. It is a figure explaining a round number packet. It is a figure explaining an interval packet. It is a figure explaining an ending packet. It is a figure explaining an event type packet. It is a figure explaining the transmission diagram of each packet. It is a figure explaining an example of the presentation control command in which random value information was stored in the empty area of fixed length data. It is a figure explaining the transmission timing of a fluctuation packet. It is a figure explaining the transmission timing of a fluctuation packet. It is a timing chart at the time of transmitting a production control command and a debug request command. It is a flowchart which shows a communication permission process. It is a figure explaining the reach production which can occur in the special figure change display game in the gaming machine of an embodiment. It is a figure explaining an example of the table which shows the actual appearance frequency etc. of each reach production totaled by the debugging apparatus. It is a figure explaining the display mode of the debug information regarding each reach production displayed on a display.

DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described with reference to the drawings.
FIG. 1 is an explanatory diagram of a gaming machine according to an embodiment of the present invention.

  The gaming machine 10 of the present embodiment includes a front frame 12, and the front frame 12 is assembled to a main body frame (outer frame) 11 via a hinge 13 so as to be openable and closable. The game board 30 (see FIG. 3) is stored in a storage portion (not shown) formed on the front side of the front frame 12. Further, a glass frame 15 having a cover glass (transparent member) 14 covering the front surface of the game board 30 is attached to the front frame (inner frame) 12.

  Further, an illuminating device (moving light) 16 incorporating a lamp and a motor and a lamp (LED) 17 for notifying a dispensing abnormality are provided on the upper part of the glass frame 15. On the left and right sides of the glass frame 15, there are provided a frame decoration device 18 that incorporates a lamp or the like and emits light for decoration or production, and a speaker (upper speaker) 19a that emits sound (for example, sound effects). Further, a speaker (lower speaker) 19 b is also provided below the front frame 12.

  In addition, the game balls paid out from the upper plate 21 for supplying game balls to a hitting ball launching device, which will be described later, and the ball payout device 46 provided on the back side of the gaming machine 10 flow out to the lower part of the front frame 12. There are provided an upper plate ball outlet 22, a lower plate 23 for storing game balls paid out in a state in which the upper plate 21 is full, and an operation unit 24 of a ball hitting device. Further, an effect button 25 having a built-in operation switch for receiving an operation input from the player is provided on the upper edge of the upper plate 21. Further, a key 26 for opening and locking the front frame 12 is provided on the lower right side of the front frame 12.

  In the gaming machine 10 of this embodiment, when the player rotates the operation unit 24, the hitting ball launching device directs the game ball supplied from the upper plate 21 toward the game area 32 on the front surface of the game board 30. And fire. In addition, when the player operates the effect button 25, an effect or the like in which the player's operation is intervened is performed in the variable display game (decoration special map variable display game) on the display device 41 (see FIG. 3). Can do. Further, on the front surface of the glass frame 15 above the upper plate 21, a ball lending button 27 that is operated when a player receives a ball lending from an adjacent ball lending machine, and a prepaid card to be discharged from the card unit of the ball lending machine. A discharge button 28 for operating the balance, a balance display section (not shown) for displaying the balance of the prepaid card, and the like are provided.

  FIG. 2 is a perspective view showing a state in which the glass frame 15 of the gaming machine 10 of the present embodiment is opened. As shown in FIG. 2, a ball payout outlet 47 for paying out the game balls paid out from the ball paying device 46 to the upper plate 21 at a position corresponding to the front of the front frame 12 and behind the glass frame 15. And an upper plate communication path 48 for guiding the game balls paid out from the ball payout outlet 47 to the upper plate 21 is provided on the back surface of the glass frame 15.

  A launch unit 72 is disposed below the front handle 12 and above the operation handle 24. To the left of the launch unit 72 is a launch rail 73 inclined to the lower right and a foul ball flow lower entrance. 74 is provided, and the front of the foul ball flow lowering port 74 is covered with a falling ball flow lowering member 75. On the left side of the front surface of the falling ball flow-down member 75, a ball tray 75a that prevents the game balls remaining in the ball payout flow path when the glass frame 15 is opened is provided. The firing unit 72 and the firing rail 73 constitute a hitting ball launching device.

  Further, on the back surface of the glass frame 15, a launch ball supply path 76 that supplies the game ball on the upper plate 21 to the unit corresponding to the launch unit 72 is provided, and corresponds to the exit of the launch ball supply path 76. A launch ball supply port 72 a is provided on the front surface of the launch unit 72. Further, a lower tray ball outlet 77 is provided at the back of the lower plate 23 from which game balls discharged from the ball dispensing device 46 and overflowing from the upper plate 21 flow out.

  Next, an example of the game board 30 will be described with reference to FIG. FIG. 3 is a front view of the game board 30 of the present embodiment.

  On the surface of the game board 30, a substantially circular game area 32 surrounded by the guide rail 31 is formed. The game area 32 is surrounded by resin side cases 33 and guide rails 31 provided at the four corners of the game board 30. In the game area 32, a center case 40 provided with a display device 41 is disposed substantially at the center. The display device 41 is attached to a recessed portion provided in the center case 40 at a position deeper than the front surface of the center case 40. That is, the center case 40 surrounds the display area of the display device 41 and is formed to protrude forward from the display surface of the display device 41.

  The display device 41 is configured by a device having a display screen such as an LCD (Liquid Crystal Display) or a CRT (CRT). A plurality of pieces of identification information (special symbols), a character that produces a special figure variation display game, a background image that enhances the effect, and the like are displayed in an area (display area) in which an image of the display screen can be displayed. On the display screen of the display device 41, a plurality of special symbols assigned as identification information are variably displayed (variably displayed), and a decorative special figure variation display game corresponding to the special diagram variation display game is played. In addition, an image for an effect based on the progress of the game (for example, a jackpot display image, a fanfare display image, an ending display image, etc.) is displayed on the display screen.

On the right side of the center case 40 in the game area 32, a normal symbol start gate (ordinary start gate) 34 is provided. Three general winning openings 35 are arranged on the lower left side of the center case 40, and one general winning opening 35 is arranged on the lower right side of the center case 40.
In each of the general winning ports 35,..., Winning port switches 35a to 35n (see FIG. 6) for detecting a game ball that has entered each of the general winning ports 35 are arranged.

  A start winning opening 36 is provided below the center case 40 as a start winning area for giving a start condition for the special figure variation display game. In addition, a flat plate member (not shown) is provided in the vicinity of the lower right portion of the center case 40 so that a flat plate member (belt-shaped member) moves forward of the game board and changes into a state in which a game ball can easily flow in, and the first inside. An ordinary variable winning device (general power) 37 having two starting winning openings (starting winning areas) is provided.

  The flat plate member of the normal variation winning device 37 always maintains a closed state (a disadvantageous state for the player) behind the game board. Then, when the result of the general fluctuation display game becomes a predetermined stop display mode, the flat plate member is moved forward by the general electric solenoid 37c (see FIG. 6) as a driving device and is normally changed. The game device can be changed to an open state (a state advantageous to the player) in which a game ball easily flows into the winning device 37.

  Further, to the right of the start winning opening 36, a special variable winning apparatus (large winning opening) 38 that can be converted into a state in which a game ball is not accepted and a state in which it is easy to accept depending on the result of the special figure variation display game is disposed. Yes.

The special variation winning device 38 has an attacker-type open / close door 38c that can be opened by rotating in a direction in which the upper end side is tilted toward the near side, depending on the result of the special figure variation display game as an auxiliary game. The state is converted from a closed state (closed state unfavorable for the player) to an open state (a state advantageous to the player).
In other words, the special variable winning device 38 includes, for example, a large winning opening that is opened and closed by an open / close door 38c that is driven by a large winning opening solenoid 38b (see FIG. 6) as a driving device. By converting the closed state from the closed state to the open state, the inflow of game balls into the special winning opening is facilitated, and a predetermined game value (prize ball) is given to the player.
In addition, a count switch 38a (see FIG. 6) as a detecting means for detecting a game ball that has entered the special winning opening is disposed inside the special winning opening (winning area).
Further, below the start winning opening 36, an out opening 39 for collecting game balls that have not won the winning opening or the like is provided.

  In addition, on the outside of the game area 32 (for example, in the lower right part of the game board 30), the first special figure fluctuation display game, the second special figure fluctuation display game, and the general figure start gate 34 that form the special figure fluctuation display game are displayed. A collective display device 50 (see FIG. 6) is provided that executes a common-variation display game triggered by winning a prize in one place.

  The collective display device 50 includes a first special figure fluctuation display unit (first special figure display) and a second special figure for a first special figure fluctuation display game configured by a 7-segment display (LED lamp) or the like. A second special figure fluctuation display unit (second special figure display) for the fluctuation display game. Although not shown in the collective display device 50, the starting memory number of the special figure 1 variable display game composed of a variable display section (common figure display) for the normal figure variable display game and four LED lamps. Special figure 1 hold indicator for notification and special figure 2 hold indicator for special figure 2 variable display game notification, for start memory number notification of general figure variable display game composed of two LED lamps The first game status indicator that lights up when a big hit occurs and notifies the occurrence of a big hit, the second gaming state indicator that lights up when a short time state occurs and notifies the occurrence of a short time state, and the gaming machine 10 A high-probability alarm that displays that the probability status of the jackpot is a high-probability state when the power is turned on, and a number-of-rounds indicator that displays the number of rounds when the jackpot is hit (the number of times the special variable winning device 38 is opened and closed) are provided. Yes.

  The special figure fluctuation display game on the first special figure display and the second special figure display is, for example, during the execution of the fluctuation display game, that is, while the decoration special figure fluctuation display game is being performed on the display device 41, The segment is blinked to indicate that it is changing. When the result of the game is “out of”, for example, the central segment is turned on as a result mode of out of game. When the result of the game is “big hit”, the result of out of game (special result mode) is not. A game result is displayed with a result mode other than the result mode (for example, a number such as “3” or “7”) in a lit state.

  In the gaming machine 10 of the present embodiment, a game is played by launching a game ball (pachinko ball) from the hitting ball launcher toward the game area 32. The launched game balls flow down the game area 32 while changing the rolling direction by means of direction change members such as obstacle nails and windmills arranged at various locations in the game area 32, and the normal start gate 34 and the general winning opening 35 The winning prize opening 36, the normal variable prize winning device 37, or the special variable prize winning device 38 is won, or it flows into the out port 39 provided at the bottom of the game area 32 and is discharged from the game area 32. When a game ball wins the general winning opening 35, the start winning opening 36, the normal variation winning apparatus 37, or the special variable winning apparatus 38, the number of winning balls corresponding to the type of the winning opening is awarded by the payout control apparatus 200. It is discharged from the controlled dispensing unit to the upper plate 21 or the lower plate 23 of the front frame 12.

On the other hand, a gate switch 34a (see FIG. 6) including a non-contact type switch for detecting a game ball that has passed through the general diagram start gate 34 is provided in the general diagram start gate 34. When a game ball that has been driven into the area 32 passes through the usual figure start gate 34, it is detected by the gate switch 34a and a usual figure change display game is played.
In addition, the normal variation display game cannot be started, for example, the normal variation display game has already been played and the normal variation display game has not been completed, When 37 is converted to the open state and the game ball passes through the general figure start gate 34, if it is less than the upper limit of the normal figure start memory number, the general figure start memory number is added (+1) and the general figure start memory number is increased. One figure start memory is stored. The memorized number of the normal start prize is displayed on a general figure hold display (not shown) for notifying the start prize number of the collective display device 50.
In addition, in the normal chart start memory, a random number value for hit determination for determining a hit error of the normal figure fluctuation display game is stored, and when the random number value for hit determination coincides with the determination value In addition, a specific result mode (specific result) is derived by hitting the common map fluctuation display game.

The usual map change display game is executed by a change display unit (usual display device) (not shown) provided in the collective display device 50. The general-purpose indicator is composed of LEDs indicating normal identification information (general and normal symbols) in the lit state and indicating a shift in the unlit state, and the normal identification information is displayed by blinking this LED. The fluctuation display is performed, and after a predetermined fluctuation display time has elapsed, the LED is turned on or off to display the result.
Note that, for example, numbers, symbols, character designs, and the like may be used as the normal identification information, which is displayed by variably displaying for a predetermined time and then stopped. If the stop display of the normal figure change display game is a specific result, the open state in which the flat plate member of the normal change winning device 37 is opened for a predetermined time (for example, 0.3 seconds) becomes a hit of the normal figure. Become. This makes it easier for the game ball to win the second start winning opening inside the normal fluctuation winning device 37, and the number of times the second special figure changing display game is executed increases.

  When the random number value extracted at the time of detection of the passage to the universal figure start gate 34 is a winning value, the normal symbol displayed on the universal figure indicator stops in the hit state and enters the hit state. At this time, the normal variation winning device 37 is in a state in which the flat plate member is opened for a predetermined time (for example, 0.3 seconds) by driving the built-in general-purpose solenoid 37c (see FIG. 6). It is converted and the winning of the game ball is allowed.

The winning ball to the starting winning port 36 and the winning ball to the normal variation winning device 37 are detected by the starting port 1 switch 36a and the starting port 2 switch 37a provided inside, respectively. The game ball that has won the start winning opening 36 is detected as the start winning ball of the first special figure variable display game, is stored up to a predetermined upper limit number (for example, 4), and is awarded to the normal variable winning device 37. The played game balls are detected as start winning balls for the second special figure variation display game, and stored with a predetermined upper limit number (for example, four) as a limit.
In addition, when the starting winning ball is detected, a big hit random number value, a big hit symbol random number value, and each variation pattern random number value are extracted, and the extracted random number value is stored in a special figure in the game control device 100 (see FIG. 6). Each area (a part of the RAM) is stored as a special figure start memory for a predetermined number of times (for example, a maximum of four times). The number stored in the special figure start memory is displayed on the special figure 1 and special figure 2 on-hold display (not shown) for notifying the start winning number of the collective display device 50 and the display device 41 of the center case 40. Is also displayed.

The game control device 100 displays the first or second special figure variation display on the special figure 1 display or the special figure 2 display on the basis of the winning at the start winning opening 36 or the normal variable prize winning device 37 or the start memory thereof. Play the game.
The first special figure fluctuation display game and the second special figure fluctuation display game are performed by variably displaying a plurality of special symbols (special figures, identification information) and then stopping and displaying a predetermined result form. In addition, a decorative special figure fluctuation display game for displaying a plurality of types of identification information (for example, numbers, symbols, character designs, etc.) corresponding to each special figure fluctuation display game on the display device 41 is executed. ing.
As a result of the special figure variation display game, when the display form of the special figure 1 display or the special figure 2 display becomes a special result form, it becomes a big hit and a special game state (so-called big hit state). Become. Correspondingly, the display mode of the display device 41 is also a special result mode.

  In the decorative special symbol variation display game on the display device 41, for example, the decorative special symbol (identification information) composed of the above-described numbers is left (first special symbol), right (second special symbol), middle (third special symbol). The variation display is started in the order of symbols), the symbols that have been varied after a predetermined time are sequentially stopped, and the result of the special symbol variation display game is displayed. In addition, the display device 41 performs a variable display game with a decorative special symbol corresponding to the number of special figure starting memories, and various effect displays such as the appearance of a character are performed to improve interest.

  Note that the special figure 1 display and the special figure 2 display may be separate displays or the same display. Is displayed. In addition, the display device 41 may use different display devices and different display areas in the first special map variable display game and the second special map variable display game, or use the same display device and display area. However, the decoration special figure variation display game is displayed so as not to be executed independently or simultaneously. Further, the special game variable display game may be executed only by the display device 41 without providing the game machine 10 with the special map 1 display and the special map 2 display.

In addition, in the state where the first special figure fluctuation display game (second special figure fluctuation display game) can be started and the number of start memories is zero, the start winning opening 36 (or the normal fluctuation prize winning device 37) is entered. When the game ball wins, the start memory is stored as the start right is generated, the start memory number is incremented by 1, and the first special figure variation display game (second special figure) is immediately added based on the start memory. (Variable display game) is started, and at this time, the start memory number is decremented by one.
On the other hand, a state in which the first special figure fluctuation display game (second special figure fluctuation display game) cannot be started immediately, for example, the first or second special figure fluctuation display game has already been performed, and the special figure fluctuation display game has ended. If the game ball is won in the start winning opening 36 (or the normal variable prize winning device 37) in a state that is not in the special game state or in the special game state, the start memory number is 1 if the start memory number is less than the upper limit number. By adding, one start memory is stored. Then, in a state where the starting memory number becomes 1 or more, a state in which the first special figure fluctuation display game (second special figure fluctuation display game) can be started (the end of the previous special figure fluctuation display game or the special game state) (End), the start memory number is decremented by 1, and the first special figure fluctuation display game (second special figure fluctuation display game) is started based on the stored start memory.
In the following description, when the first special figure fluctuation display game and the second special figure fluctuation display game are not distinguished, they are simply referred to as a special figure fluctuation display game.

  Although not particularly limited, the starting port 1 switch 36a in the starting winning port 36, the starting port 2 switch 37a in the normal variable winning device 37, the gate switch 34a, the general winning port switches 35a to 35n, the count The switch 38a is a non-contact type magnetic proximity sensor (hereinafter referred to as a proximity switch) that includes a magnetic detection coil and detects a game ball using a phenomenon in which a magnetic field changes when a metal approaches the coil. Has been. A micro switch having a mechanical contact is used for the front frame opening detection switch 63 provided on the glass frame 15 or the like of the gaming machine 10 or the game frame opening detection switch 64 provided on the front frame (game frame) 12 or the like. be able to.

Next, the back surface structure of the gaming machine 10 will be described with reference to FIGS.
4 is a rear view of the gaming machine 10, and FIG. 5 is a rear view of the gaming board 30 constituting the gaming machine 10, showing a state where the cover on the rear side of the effect control device 300 is removed.

  As shown in FIG. 4, a storage tank 81 for storing game balls before paying out and information to the outside (for example, a symbol determination signal, a jackpot signal, a probability variation signal, a prize ball signal, An external information terminal board 71 for outputting a ball rental signal or the like) is provided. In addition, a chute 82 having a gentle inclination and guiding the game ball toward one side of the gaming machine 10 is connected to the bottom of the storage tank 81, and the flow direction of the game ball is horizontal at the end of the chute 82. A bent channel device 83 for converting the direction to the vertical direction is connected. A ball payout device 46 having a drive source is disposed at the lower end of the bent flow passage device 83, and a predetermined number of game balls can be paid out by the ball payout device 46.

As shown in FIGS. 4 and 5, a payout control device 200 that controls the ball payout device 46 and an effect control device that controls the effect of the variable display game on the display device 41 are provided at the lower back of the front frame 12. 300, a game control device 100 that performs overall control of the payout control device 200, the effect control device 300, etc., a power supply device 400 that has a power supply circuit and supplies power to the game control device 100, the payout control device 200, the effect control device 300, etc. Is arranged.
Further, a card unit relay board 210 and the like for relaying signals exchanged between the gaming machine side and the card unit side are provided at the bottom of the back surface of the front frame 12.

FIG. 6 is a block diagram of the control system of the gaming machine 10 of this embodiment.
The gaming machine 10 includes a game control device 100. The game control device 100 is a main control device (main board) for comprehensively controlling games, and a gaming microcomputer (hereinafter referred to as a gaming microcomputer) 111 is provided. The CPU unit 110 includes an input unit 120 having an input port, an output unit 130 having an output port, a driver, and the like, and a data bus 140 connecting the CPU unit 110, the input unit 120, and the output unit 130.

  The CPU section 110 receives signals (starting winning detection signals) from a gaming microcomputer (CPU) 111 called an amusement chip (IC) and a proximity switch interface chip (proximity I / F) 121 in the input section 120. An inversion circuit 112 composed of an inverter or the like that is logically inverted and input to the gaming microcomputer 111 and an oscillator such as a crystal oscillator are provided to generate a clock for a CPU operation clock, a timer interrupt, and a random number generation circuit. An oscillation circuit (crystal oscillator) 113 is included. The game control device 100 and electronic components such as a solenoid and a motor driven by the game control device 100 are supplied with a predetermined level of DC voltage such as DC32V, DC12V, and DC5V generated by the power supply device 400 so as to be operable. Is done.

  The power supply apparatus 400 includes a normal power supply including an AC-DC converter that generates the DC 32V DC voltage from a 24V AC power source, a DC-DC converter that generates a lower level DC voltage such as DC 12V and DC 5V from the DC 32V voltage, and the like. Unit 410, backup power supply unit 420 for supplying power supply voltage to the internal RAM of gaming microcomputer 111 in the event of a power failure, and a power failure monitoring circuit and an initialization switch to inform gaming control device 100 of the occurrence and recovery of power failure A control signal generation unit 430 that generates and outputs control signals such as a power failure monitoring signal, an initialization switch signal, and a reset signal is provided.

  In this embodiment, the power supply device 400 is configured separately from the game control device 100, but the backup power supply unit 420 and the control signal generation unit 430 are integrated on a separate board or the game control device 100, that is, the main control device 100. You may comprise so that it may provide on a board | substrate. Since the game board 30 and the game control device 100 are to be replaced when the model is changed, the backup power supply unit 420 and the control signal generation unit 430 are provided on a board different from the power supply apparatus 400 or the main board as in the embodiment. By providing, it can remove from the object of replacement | exchange and can aim at cost reduction.

  The backup power supply unit 420 can be composed of one large-capacity capacitor such as an electrolytic capacitor. The backup power is supplied to the game microcomputer 111 (particularly, the built-in RAM) of the game control device 100, and the data stored in the RAM is held even during a power failure or after the power is shut off. The control signal generation unit 430 monitors the voltage of 32V generated by the normal power supply unit 410, for example, detects the occurrence of a power failure when the voltage drops below 17V, for example, changes the power failure monitoring signal, and resets the signal after a predetermined time. Is output. In addition, a reset signal is output after a predetermined time has elapsed from the time when the power is turned on or the power is restored.

  The initialization switch signal is a signal generated when the initialization switch is turned on, and forcibly initializes information stored in the RAM 111C in the gaming microcomputer 111 and the RAM in the payout control device 200. . Although not particularly limited, the initialization switch signal is read when the power is turned on, and the power failure monitoring signal is repeatedly read in the main loop of the main program executed by the gaming microcomputer 111. The reset signal is a kind of forced interrupt signal and resets the entire control system.

  The gaming microcomputer 111 constitutes a control means for comprehensively controlling the game. Specifically, the gaming microcomputer 111 includes a CPU (central processing unit: microprocessor) 111A, a read-only ROM (read-only memory) 111B, and a RAM (random access memory) 111C that can be read and written as needed.

  The ROM 111B stores invariant information (programs, fixed data, various random number judgment values, etc.) for game control in a nonvolatile manner, and the RAM 111C stores a work area for the CPU 111A and various signals and random number values during game control. Used as As the ROM 111B or the RAM 111C, an electrically rewritable nonvolatile memory such as an EEPROM may be used.

In addition, the ROM 111B stores a variation pattern table for determining a variation pattern that defines, for example, the execution time of the special figure variation display game, the production contents, and the presence or absence of the reach state.
The variation pattern table is a table for the CPU 111A to determine the variation pattern by referring to the variation pattern random numbers 1 to 3 stored as the start memory. The variation pattern table includes a loss variation pattern table selected when the result is out of order, a big hit variation pattern table selected when the result is per 15R probability variation or 2R probability variation, and the like.

  Reach (reach state) has a display device whose display state can change, and the display device derives and displays a plurality of display results at different times, and the plurality of display results are predetermined. In the gaming machine 10 in which the gaming state becomes a gaming state advantageous to the player (special gaming state) when the special result mode is entered, the game is already derived at the stage where some of the plurality of display results are not yet derived and displayed. This means a display state in which the displayed display result satisfies the condition for the special result mode. In other words, the reach state is deviated from the display condition that is the special result mode even when the display device's variable display control progresses and reaches the stage before the display result is derived and displayed. There is no display mode. For example, a state where so-called full-rotation reach is performed in a variable display region while maintaining a state in which special result modes are aligned (so-called full rotation reach) is also included in the reach state. The reach state is a display state at the time when the display control of the display device has progressed to reach a stage before the display result is derived and displayed, and is determined before the display result is derived and displayed. The display state in the case where at least a part of the display results of the plurality of variable display areas satisfies the condition for the special result mode.

  Thus, for example, a decorative special figure fluctuation display game displayed on a display device corresponding to a special figure fluctuation display game fluctuates a plurality of identification information for a predetermined time in each of the left, middle, and right fluctuation display areas on the display device. After displaying, when the display of the result mode is stopped in the order of left, right, and middle, the condition that becomes the special result mode is satisfied in the left and right variable display areas (for example, The state in which the variable display is stopped with the same identification information) is the reach state. In addition to this, when the variable display of all the variable display areas is temporarily stopped, the condition that the special result mode is satisfied in any two of the left, middle, and right variable display areas (for example, the same The state in which the identification information is obtained (except for the special result mode) may be set as the reach state, and the remaining one variable display area may be variably displayed from the reach state. This reach state includes a plurality of reach effects, and the possibility of deriving a special result mode is different (having different reliability), such as normal reach, special 1 reach, special 2 reach, special 3 reach, etc. Is set.

  The reliability increases in the order of no reach <normal reach <special 1 reach <special 2 reach <special 3 reach. In addition, this reach state is included in a variable display mode at least in a case where a special result mode is derived in a special figure variable display game (when a big hit is achieved). That is, when it is determined that the special result mode is not derived in the special figure variable display game (when it is out of date), it may be included in the variable display mode. Therefore, the state in which the reach state has occurred is a state that is more likely to be a big hit than the case in which the reach state does not occur.

The CPU 111A executes a game control program in the ROM 111B, generates control signals (commands) for the payout control device 200 and the effect control device 300, and generates and outputs drive signals for the solenoid and the display device, thereby playing the gaming machine. 10 overall control is performed.
Further, although not shown, the gaming microcomputer 111 is a jackpot determination random number for the special figure variation display game (random number for jackpot determination), a big hit symbol random number for determining the big hit symbol, a fluctuation in the special figure variation display game. Generates variation pattern random numbers (variation mode determination random numbers) for determining patterns (including the execution time of variation display games in various reach and non-reach variation display), random numbers for determining hits of ordinary variable display games, etc. And a clock that gives a timer interrupt signal of a predetermined period (for example, 4 milliseconds) to the CPU 111A and the update timing of the random number generation circuit based on the oscillation signal (original clock signal) from the oscillation circuit 113 It has a clock generator.

  In addition, the CPU 111A selects one of a plurality of variation pattern tables stored in the ROM 111B in a start port switch monitoring process (step A1) or a special figure routine process (step A9) in a special figure game process to be described later. One fluctuation pattern table is acquired. Specifically, the CPU 111A determines the game result (big hit or miss) of the special figure fluctuation display game, the probability state (normal probability state or high probability state) of the special figure fluctuation display game as the current game state, and the current game. Any one of a plurality of variation pattern tables is selected based on the operation state (normal operation state or short-time operation state) of the normal variation winning device 37 as a state, the number of start memories, a predetermined timing immediately after recovery from a power failure, etc. The fluctuation pattern table is selected and acquired.

  Although not shown, the payout control device 200 includes a CPU, a ROM, a RAM, an input interface, an output interface, and the like, and drives a payout motor of the payout unit in accordance with a prize ball payout command (command or data) from the game control device 100. , Control for paying out a prize ball. In addition, the payout control device 200 drives the payout motor of the payout unit based on the ball rental request signal from the card unit, and performs control for paying out the ball.

  The input unit 120 of the gaming microcomputer 111 includes a start port 1 switch 36a in the start winning port 36, a start port 2 switch 37a in the normal variation winning device 37, a gate switch 34a in the usual start gate 34, and a general winning port. An interface which is connected to the switches 35a to 35n and the count switch 38a and receives a negative logic signal such as a high level of 11V and a low level of 7V supplied from these switches, and converts it into a positive logic signal of 0V-5V. A chip (proximity I / F) 121 is provided. Proximity I / F 121 seems to be floating because the input range is 7V-11V, the lead wire of the proximity switch is improperly shorted, the switch is disconnected from the connector, or the lead wire is disconnected. An abnormal state can be detected, and an abnormality detection signal is output.

  All the outputs of the proximity I / F 121 are supplied to the second input port 122 and read into the gaming microcomputer 111 via the data bus 140, and also supplied from the main board 100 to the test firing test apparatus (not shown) via the relay board 70. It is like that. In addition, the detection signals of the start port 1 switch 36a and the start port 2 switch 37a among the outputs of the proximity I / F 121 are input to the gaming microcomputer 111 via the inverting circuit 112 in addition to the second input port 122. It is configured. The inversion circuit 112 is provided because the signal input terminal of the gaming microcomputer 111 detects that a signal from a micro switch or the like is input, and detects negative logic, that is, low level (0 V) as an effective level. Because it is designed to do.

  Therefore, when a micro switch is used as the start port 1 switch 36a and the start port 2 switch 37a, the detection signal can be directly input to the gaming microcomputer 111 without providing the inverting circuit 112. That is, when it is desired to directly input negative logic signals from the start port 1 switch 36a and the start port 2 switch 37a to the gaming microcomputer 111, the proximity switch cannot be used. As described above, the proximity I / F 121 has a signal level conversion function. In order to enable such a level conversion function, the proximity I / F 121 is supplied with a voltage of 12 V from the power supply device 400 in addition to a voltage such as 5 V required for normal IC operation. It has become.

  Further, the input unit 120 includes a start winning opening 36 converted by signals from the fraud detection magnetic sensor switch 61 and the vibration sensor switch 62 provided on the front frame 12 of the gaming machine 10 and the proximity I / F 121. The start port 1 switch 36a in the inside, the start port 2 switch 37a in the normal variation winning device 37, the gate switch 34a, the general winning port switches 35a to 35n, and the signals from the count switch 38a are taken in via the data bus 140. A second input port 122 for supplying to the microcomputer 111 is provided. The data held by the second input port 122 is read by asserting the enable signal CE1 (changing to an effective level) by the gaming microcomputer 111 decoding the address assigned to the second input port 122. be able to. The same applies to other ports described later.

  Further, the input unit 120 receives signals and payouts from the front frame opening detection switch 63 provided on the glass frame 15 and the like of the gaming machine 10 and the game frame opening detection switch 64 provided on the front frame (game frame) 12 and the like. A status signal indicating a payout abnormality from the control device 200, a shot ball break switch signal indicating a shortage of game balls before payout, and an overflow switch signal indicating overflow are fetched and supplied to the game microcomputer 111 via the data bus 140. One input port 123 is provided. The overflow switch signal is a signal that is output when it is detected that a predetermined amount or more of game balls are stored in the lower plate 23 (full).

  Further, the input unit 120 is provided with a Schmitt trigger circuit 124 for inputting signals such as a power failure monitoring signal, an initialization switch signal, and a reset signal from the power supply device 400 to the gaming microcomputer 111 and the like. The circuit 124 has a function of removing noise from these input signals. Of the signals from the power supply device 400, the power failure monitoring signal and the initialization switch signal are once inputted to the first input port 123 and taken into the gaming microcomputer 111 via the data bus 140. That is, it is treated as a signal equivalent to the signal from the various switches described above. This is because the number of terminals receiving external signals provided in the gaming microcomputer 111 is limited.

  On the other hand, the reset signal RST from which noise has been removed by the Schmitt trigger circuit 124 is directly input to a reset terminal provided in the gaming microcomputer 111 and is supplied to each port of the output unit 130. Further, the reset signal RST is directly output to the relay board 70 without going through the output unit 130, thereby turning off the test test signal held in the port (not shown) of the relay board 70 for output to the test board. It is configured as follows. Further, the reset signal RST may be configured to be output to the test firing test apparatus via the relay board 70. The reset signal RST is not supplied to the ports 122 and 123 of the input unit 120. Data set in each port of the output unit 130 by the gaming microcomputer 111 immediately before the reset signal RST is input needs to be reset to prevent malfunction of the system. This is because the data read by the gaming microcomputer 111 from the port is discarded when the gaming microcomputer 111 is reset.

  The output unit 130 is connected to the data bus 140 and outputs a 4-bit data signal output to the payout control device 200, a control signal (data strobe signal) indicating validity / invalidity of the data, and a data strobe signal SSTB output to the effect control device 300. 1 and a second output port 132 for generating an 8-bit data signal to be output to the effect control device 300. Data is transmitted from the game control device 100 to the payout control device 200 and the effect control device 300 by parallel communication. In addition, the data strobe signal from the first output port 131 is input to the output unit 130 in order to prevent a signal from being input to the game control device 100 from the side of the effect control device 300, that is, to ensure one-way communication. A unidirectional buffer 133 that outputs an 8-bit data signal from the SSTB and the second output port 132 is provided. A buffer may be provided for a signal output from the first output port 131 to the payout control device 200.

  In addition, the output unit 130 is connected to the data bus 140 via a relay board 70 for data indicating special symbol information of the variable display game to a test firing test apparatus of an accredited organization (not shown) and a signal indicating the probability status of jackpot. The output buffer 134 is configured to be mountable. This buffer 134 is a component that is not mounted on a game control device (main board) of a pachinko gaming machine as an actual machine (mass production product) installed in the game store. A detection signal output from the proximity I / F 121, such as a start port switch, that is not required to be processed is supplied to the test firing test apparatus via the relay board 70 without passing through the buffer 134.

  On the other hand, detection signals such as the magnetic sensor switch 61 and the vibration sensor switch 62 that cannot be supplied to the test fire testing device as they are are once taken into the gaming microcomputer 111 and processed into other signals or information. An error signal indicating that the control is not possible is supplied from the data bus 140 to the trial test apparatus via the buffer 134 and the relay board 70. The relay board 70 is provided with a port that takes in the signal output from the buffer 134 and supplies it to the test test apparatus, a connector that relays and transmits a signal line of a switch detection signal that does not pass through the buffer, and the like. ing. A chip enable signal CE output from the gaming microcomputer 111 is also supplied to the port on the relay board 70, and the signal of the port selected and controlled by the signal CE is supplied to the test firing test apparatus.

  In addition, the output unit 130 is connected to the data bus 140 to open a special variable prize winning device 38 (a large prize opening solenoid) 38b and a solenoid for driving a flat member (not shown) of the normal variable prize winning device 37 (general power). Solenoid) a third output port 135 for outputting open / close data of 37c and digit line ON / OFF data to which the cathode terminal of the LED of the collective display device 50 is connected, depending on the contents displayed on the collective display device 50 A fourth output port 136 for outputting on / off data of the segment line to which the anode terminal of the LED is connected, and a fifth output port for outputting information related to the gaming machine 10 such as jackpot information to the external information terminal 71 137 is provided. Information relating to the gaming machine 10 output from the external information terminal 71 is supplied to, for example, an information collection terminal installed in a game store or a game hall internal management device (not shown).

  Further, the output unit 130 receives the opening / closing data signal of the big prize opening solenoid 38b output from the third output port 135, and receives the solenoid driving signal and the opening / closing data signal of the power solenoid 37c to generate the solenoid driving signal. A first driver (drive circuit) 138a for outputting, a second driver 138b for outputting an on / off drive signal for a digit line on the current drawing side of the collective display device 50 outputted from the third output port 135, and a fourth output port 136 The external information signal supplied to the external device such as the management device from the third driver 138c and the fifth output port 137 for outputting the ON / OFF drive signal of the segment line on the current supply side of the collective display device 50 output from the external information A fourth driver 138d for outputting to the terminal 71 is provided.

  The first driver 138a is supplied with DC32V from the power supply device 400 as a power supply voltage so that a solenoid operating at 32V can be driven. Also, DC12V is supplied to the third driver 138c that drives the segment lines of the collective display device 50. Since the second driver 138b for driving the digit line is for extracting the digit line corresponding to the display data with a current, the power supply voltage may be either 12V or 5V. The third driver 138c that outputs 12V causes a current to flow to the anode terminal of the LED via the segment line, and the second driver 138b that outputs the ground potential extracts the current via the segment line from the cathode terminal. The power supply voltage flows through the LEDs sequentially selected in step 1 so as to be lit. The fourth driver 138d that outputs the external information signal to the external information terminal 71 is supplied with DC12V in order to give the external information signal a level of 12V. The buffer 134, the third output port 135, the first driver 138a, and the like may be provided on the output board 130 of the game control apparatus 100, that is, on the relay board 70 side instead of the main board.

  Further, the output unit 130 is provided with a photocoupler 139 for transmitting information such as an identification code and a program of each gaming machine to the external inspection device 500. The photocoupler 139 is configured to be capable of bi-directional communication so that the gaming microcomputer 111 can transmit and receive data to and from the inspection device 500 through serial communication. Note that such data transmission / reception is performed using a serial communication terminal of the gaming microcomputer 111 as in the case of a general general-purpose microprocessor, and therefore, ports such as the input ports 122 and 123 are not provided.

Next, the configuration of the effect control device 300 will be described with reference to FIG.
The effect control device 300 includes a main control microcomputer (1st CPU) 311 formed of an amusement chip (IC), as with the game microcomputer 111, and a video control microcomputer (2nd CPU) 312 that performs video control exclusively under the control of the 1st CPU 311 , VDP (Video Display Processor) 313 as a graphic processor that performs image processing for video display on the display device 41 in accordance with commands and data from the 2nd CPU 312 and various melody and sound effects are reproduced from the speakers 19a and 19b. The sound source LSI 314 for controlling the sound output is provided.

  The main control microcomputer (1st CPU) 311 and the video control microcomputer (2nd CPU) 312 are connected to program ROMs 321 and 322 each composed of a PROM (programmable read only memory) storing a program executed by each CPU. Is connected to an image ROM 323 storing character images and video data, and an audio ROM 324 storing audio data is connected to the tone generator LSI 314. The main control microcomputer (1st CPU) 311 analyzes the command from the game microcomputer 111, decides the contents of the presentation, instructs the video control microcomputer 312 about the contents of the output video, and instructs the sound source LSI 314 about the reproduced sound. Then, processing such as lighting of the decoration lamp, motor drive control, and production time management is executed. RAMs that provide work areas for the main control microcomputer (1st CPU) 311 and the video control microcomputer (2nd CPU) 312 are provided in the respective chips. Note that the RAM that provides the work area may be provided outside the chip.

  In addition, the effect control device 300 receives information related to the effect control command transmitted from the main control microcomputer (1stCPU) 311 to the video control microcomputer (2ndCPU) 312 and the main control microcomputer (1stCPU) 311 outside the gaming machine 10 and A debug device connection circuit 315 for transmitting / receiving to / from the debug device 350 used for the inspection (production control inspection) of the video control microcomputer (2ndCPU) 312 can be mounted. This debug device connection circuit 315 is a component that is not mounted on the production control device 300 of a pachinko gaming machine as a real machine (mass production product) installed in the amusement store. Further, the debug device connection circuit 315 is configured to be connectable to the debug device 350 via an inspection connection unit (inspection connector) 317 mounted on the effect control device 300.

  Although not particularly limited, the main control microcomputer (1stCPU) 311 and the video control microcomputer (2ndCPU) 312 and the main control microcomputer (1stCPU) 311 and the sound source LSI 314 are serially connected. Data transmission / reception is performed, and data transmission / reception is performed in parallel with the video control microcomputer (2ndCPU) 312 and between the main control microcomputer (1stCPU) 311 and the VDP 313. By transmitting and receiving data in parallel, commands and data can be transmitted in a shorter time than in the case of serial. The VDP 313 includes an ultra-high speed VRAM (video RAM) 313a used for developing and processing image data such as characters read from the image ROM 323, and a scaler for enlarging and reducing images. 313b, a signal conversion circuit 313c that generates a video signal to be transmitted to the display device 41 by an LVDS (small amplitude signal transmission) method, and the like are provided.

  A vertical synchronization signal VSYNC is input from the VDP 313 to the main control microcomputer 311 in order to synchronize the image of the display device 41 and the lighting of the decorative lamps provided on the front frame 12 and the game board 30. In addition, the VDP 313 notifies the video control microcomputer 312 that it is waiting to receive an interrupt signal INT0-n and a command or data from the video control microcomputer 312 in order to notify the processing status such as the end of drawing in the VRAM. A wait signal WAIT is input. Further, the video control microcomputer 312 receives from the main control microcomputer 311 a synchronization signal SYNC that informs that the video control microcomputer 312 is operating normally and gives command transmission timing. A call signal CTS and a response signal RTS are exchanged between the main control microcomputer 311 and the tone generator LSI 314 in order to transmit and receive commands and data in the handshake method.

  Note that the video control microcomputer (2ndCPU) 312 uses a CPU that is faster or more expensive than the main control microcomputer (1stCPU) 311. By providing a video control microcomputer (2ndCPU) 312 separately from the main control microcomputer (1stCPU) 311 and sharing the processing, it is possible to display a fast moving image on a large screen that is difficult to achieve with the main control microcomputer (1stCPU) 311 alone. It is possible to display on the display device 41, and it is possible to suppress an increase in cost compared to the case where two CPUs having processing capabilities equivalent to the video control microcomputer (2nd CPU) 312 are used. Also, by providing two CPUs, it becomes possible to separately develop the control programs for the two CPUs in parallel, thereby shortening the development period of the new model.

  In addition, the effect control device 300 is provided with an interface chip (command I / F) 331 that receives a command transmitted from the game control device 100. Fluctuation start command, start opening winning effect command, starting opening winning effect design command, customer waiting demonstration command, fanfare command, probability information command transmitted from the game control device 100 to the effect control device 300 via the command I / F 331 A change stop command, a big hit end command, etc. are received as an effect control command signal. Since the game microcomputer 111 of the game control device 100 operates at DC 5V and the main control microcomputer (1st CPU) 311 of the effect control device 300 operates at DC 3.3V, the command I / F 331 has a signal level conversion function. Is provided.

  The effect control device 300 includes a panel decoration LED control circuit 332 for driving and controlling a panel decoration device 42 having LEDs (light emitting diodes) provided on the game board 30 (including the center case 40), and the front frame 12. Frame decoration LED control circuit 333 for driving and controlling a frame decoration device (for example, the frame decoration device 18 and the like) having LEDs (light emitting diodes) and board effects provided on the game board 30 (including the center case 40). A board effect motor / SOL control circuit 334 for driving and controlling a device (for example, an electric accessory that enhances effect effects in cooperation with effect display on the display device 41), and a motor (for example, the moving device) provided on the front frame 12 A frame effect motor control circuit 335 for driving and controlling the light 45 is provided. These control circuits 332 to 335 for driving and controlling lamps, motors and solenoids are connected to a main control microcomputer (1st CPU) 311 via an address / data bus 340.

  Furthermore, in the effect control device 300, an effect button switch 25a built in the effect button 25 provided on the front frame 12 and an effect motor switch for detecting the initial position of the motor in the panel effect device 44 are turned on / off. A switch input circuit 336 that detects a state and inputs a detection signal to a main control microcomputer (1st CPU) 311; an amplifier circuit 337a that includes an audio power amplifier that drives an upper speaker 19a provided on the front frame 12; Is provided with an amplifier circuit 337b for driving the lower speaker 19b.

  The normal power supply unit 410 of the power supply apparatus 400 drives a motor or a solenoid to supply a desired level of DC voltage to the effect control apparatus 300 having the above-described configuration and electronic components controlled thereby. DC32V for driving the display device 41 composed of a liquid crystal panel, DC5V serving as the power supply voltage for the command I / F 331, DC18V for driving the LED and speaker, and a reference for these DC voltages It is configured to generate a voltage of NDC 24V used to turn on the monitor lamp. Further, when an LSI that operates at a low voltage such as 3.3 V or 1.2 V is used as the main control microcomputer (1st CPU) 311 or the video control microcomputer (2nd CPU) 312, DC 3. The effect control device 300 is provided with a DC-DC converter for generating 3V or DC 1.2V. The DC-DC converter may be provided in the normal power supply unit 410.

  The reset signal RST generated by the control signal generation unit 430 of the power supply apparatus 400 includes a main control microcomputer 311, a video control microcomputer 312, a VDP 313, a sound source LSI 314, control circuits 332 to 335 for driving and controlling lamps and motors, speakers, and the like. Are supplied to the amplifier circuits 337a and 337b, which are in a reset state. In this embodiment, a general-purpose port of the video control microcomputer 312 is used to generate and supply a reset signal to the VDP 313. Thereby, the cooperation of the operations of the video control microcomputer 312 and the VDP 313 can be improved.

Next, game control performed in these control circuits will be described.
The CPU 111A of the game microcomputer 111 of the game control device 100 extracts a random number value for hit determination of the normal figure based on the input of the detection signal of the game ball from the gate switch 34a provided to the normal figure start gate 34, and the ROM 111B. Is compared with the determination value stored in the table, and a process of determining whether or not the normal variation display game is missed is performed. Then, after the identification symbol is variably displayed for a predetermined time on a general-purpose display (not shown), a process for displaying a general-variation display game to be stopped is performed. If the result of this general-purpose fluctuation display game is a win, a special result mode is displayed on the general-purpose display, and the general-purpose solenoid 37c is operated so that the flat member of the normal fluctuation winning device 37 is kept for a predetermined time (for example, , 0.3 seconds) Control to open as described above.
In addition, when the result of the normal map change display game is out of control, control is performed to display the result form of the shift on the general map display.

Further, a start winning (starting memory) is stored based on an input of a detection signal of a game ball from a starting port 1 switch 36a provided in the starting winning port 36, and based on this start memory, the first special figure variation display game is stored. The big hit determination random number value is extracted and compared with the determination value stored in the ROM 111B, and a process of determining whether or not the first special figure variation display game is missed is performed.
In addition, the start memory is stored based on the input of the detection signal of the game ball from the start port 2 switch 37a provided in the normal variation winning device 37. A random number value is extracted and compared with the determination value stored in the ROM 111B, and a process of determining whether or not the second special figure variation display game is missed is performed.

Then, the CPU 111 </ b> A of the game control device 100 outputs a control signal (effect control command) including the determination results of the first special figure variation display game and the second special figure variation display game to the effect control device 300. Then, after the identification symbol is variably displayed for a predetermined time on the special figure 1 display or the special figure 2 display, processing for displaying a special figure variation display game to be stopped is performed.
In addition, in the production control device 300, based on the control signal from the game control device 100, the display device 41 performs a process of displaying a decoration special figure fluctuation display game corresponding to the special figure fluctuation display game.
Furthermore, in the production control device 300, based on the control signal from the game control device 100, the sound output from the speakers 19a and 19b, the process of controlling the light emission of various LEDs, and the like are performed.

Then, when the result of the special figure variation display game is a big hit, the CPU 111A of the game control device 100 displays a special result mode on the special figure 1 display or the special figure 2 display and generates a special game state. I do.
For example, if the display form of the special figure 1 display or the special figure 2 display becomes a special result form (for example, “7”) as a result of the special figure change display game, a special game state is given. (So-called big hit state).

In the process of generating the special game state, the CPU 111A performs control for allowing the game ball to flow into the special winning opening by, for example, opening the open / close door 38c of the special variable winning apparatus 38 by the special winning opening solenoid 38b. .
Then, when the result of the special figure variation display game is a big hit, a predetermined number (for example, 10) of game balls wins the big winning opening, or a predetermined time (for example, 25 seconds or 0) from the opening of the big winning opening. .5 seconds) until one of the conditions is achieved is defined as one round, which is a predetermined number of rounds (for example, 15 times (first special gaming state) or 2 times) (Second special game state)) Control (cycle game) to be continued (repeated) is performed.
When the result of the special figure variation display game is out of control, control is performed to display the result form of the deviation on the special figure 1 display or the special figure 2 display.

In addition, the game control device 100 can generate a probability change state as a game state after the special game state ends based on the result mode of the special figure variation display game.
This probability variation state is a state (high probability state) in which the probability of a hit result in the special figure variation display game is higher than the normal probability state. In addition, the first special figure variation display game and the second special figure variation display game, regardless of which one of the first special figure variation display game and the second special figure variation display game results in a certain variation state. Both display games are in a probable state.

In addition, the game control device 100 can generate a short time state as a game state after the special game state is ended based on the result mode of the special figure variation display game.
In this time-short state, control is performed so that the normal-variation display game and the normal variation winning device 37 are in the time-short operation state. Specifically, in the short-time state, the execution time of the above-described usual-variable display game is controlled to be a second variable display time shorter than the first variable display time (for example, 10 seconds is 1 second). Thus, the number of times of opening of the normal variation winning device 37 per unit time is controlled to be substantially increased. Further, in the short time state, when the normal variation winning device 37 is released as a result of the normal variation display game being won, the release time becomes a second release time longer than the first release time in the normal state. (For example, 0.3 seconds is 1.7 seconds). In the short-time state, the number of times of opening of the normal variation winning device 37 is not the first opening number of one time but a plurality of times of two or more times (for example, (3 times) the second number of times of opening.
It should be noted that the execution time of the normal variation display game is set to the second variation display time (for example, 1 second), and the release mode of the normal variation winning device 37 is the second release time (for example, 1.7). Second), and the number of times of opening with respect to one hit result of the normal variation display game is the second number of times of opening (for example, 3 times), either one or both may be performed. May be. In the short-time operation state, control may be performed so that the probability of a hit result of the normal-variable display game is higher than that in the normal operation state.
As a result, the game ball can easily win the normal variation winning device 37, and the second special figure variation display game can be easily started.

  In addition, the time variation operation state of the probability variation state, the normal variation display game, and the normal variation prize winning device 37 can be generated independently, and both can be generated at the same time, or only one can be generated. Is possible.

Next, the detailed structure of the effect control device 300 will be described with reference to FIGS.
FIG. 8A is a front view of the effect control device 300, and FIG. 8B is a rear view of the effect control device 300. In the following description, the surface that can be seen from the back side of the gaming machine 10 is based on the state in which the effect control device 300 disposed on the back side of the gaming machine 10 is viewed from the back side of the gaming machine 10. The front and the side attached to the game board 30 are the rear surface, and the upper, lower, left, and right are also the upper, lower, left, and right as viewed from the back side of the gaming machine 10.

As shown in FIGS. 8A and 8B, the effect control device 300 includes an effect control board 310 that controls an effect in the gaming machine 10 in a board box 360, and the rear surface of the game board 30. Is attached to the side.
In the effect control board 310, for example, processing related to display control of the display device 41 and operation control of the electric accessory, decorative light emitting member, and the like is performed, and the effect control board 310 that performs such control. The production control board 310 is housed in the board box 360 in order to prevent fraudulent acts.

9A is an exploded perspective view of the effect control device 300 when the effect control device 300 is viewed from the front side, and FIG. 9B is the effect when the effect control device 300 is viewed from the back side. 2 is an exploded perspective view of a control device 300. FIG. FIG. 10A is a front view of the effect control board 310, and FIG. 10B is a rear view of the effect control board 310.
As shown in FIGS. 9 and 10, the effect control board 310 is a rectangular plate-like board having a plurality of connectors 13, 13,... It is comprised with the double-sided board | substrate (2 layer board | substrate) which can mount.
In addition, the effect control board 310 is used to develop information regarding the effect control command transmitted between the 1st CPU 311 and the 2nd CPU 312 at the time of development of the gaming machine 10 and the debugging device 350 used for the inspection of the 1st CPU 311 and the 2nd CPU 312 outside the gaming machine 10. It is possible to mount a debug device connection circuit 315 for transmitting and receiving data and a test connection unit (test connector) 317 for connecting the debug device 350.
More specifically, as shown in FIG. 9A and FIG. 10A, when the gaming machine 10 is developed, the inspection connection portion (inspection connector) 317 is mounted on the left side of the front of the effect control board 310. It has come to be.
Further, as shown in FIGS. 9B and 10B, the debug device connection circuit 315 is mounted on the right attachment region A on the rear surface of the effect control board 310.

The debug device connection circuit 315 is a component that is not mounted on the effect control board 310 of the pachinko gaming machine as an actual machine (mass production product) installed in the game shop.
For parts that are not mounted on the production control board 310 at the time of mass production sales (for example, the debug device connection circuit 315), information on the parts (for example, attributes, names, etc.) at the position on the production control board 310 where the parts are mounted. It is desirable not to apply silk printing.

  The board box 360 that houses the effect control board 310 includes a first box forming member 361 that constitutes the front side of the effect control device 300 and a second box forming member 362 that constitutes the rear side, and the first box forming member. The effect control board 310 is housed in a housing portion formed by combining the 361 and the second box forming member 362. In addition, the first box forming member 361 and the second box forming member 362 can be fixed by the fixing means 60, whereby the effect control board 310 is completely contained in the board box 360, and the effect control board Injustice to 310 is prevented. Further, the first box forming member 361 and the second box forming member 362 constituting the substrate box 360 are formed of a light-transmitting synthetic resin, so that the effect control substrate 310 accommodated therein can be visually recognized. Yes.

<Modification 1>
Next, a modified example of the above-described effect control board 310 will be described with reference to FIG.
FIG. 11A is a front view of the effect control board 310 of Modification 1, and FIG. 11B is a back view of the effect control board 310.
As shown in FIGS. 11A and 11B, the production control board 310 of the first modification is not limited to the debugging device connection circuit 315 during the development of the gaming machine 10, but the inspection connection portion (inspection connector) 317. Is also mounted in the attachment area A on the right side of the rear surface of the effect control board 310.

<Modification 2>
Next, a modified example of the effect control board 310 of the above-described modified example 1 will be described with reference to FIG.
FIG. 12A is a perspective view showing the front side of the effect control board 310 of the second modification, and FIG. 12B is a perspective view showing the back side of the effect control board 310. FIG. 10C is a rear view of the effect control board 310 of the second modification, and FIG. 10D is a side view of the effect control board 310.

As shown in FIGS. 12A and 12B, similar to the production control board 310 of the first modification, the production control board 310 of the second modification is not limited to the debugging device connection circuit 315 when the gaming machine 10 is developed. The inspection connecting portion (inspection connector) 317 is also mounted in the attachment region A on the right side of the rear surface of the effect control board 310.
As shown in FIGS. 12B to 12D, a connector (external connector) of a cable that is communicably connected to the debugging device 350 is connected to the inspection connection portion (inspection connector) 317 of the production control board 310 of the second modification. A right angle type connector is used so that the coupling direction when coupled (fitted) to the connector) is parallel to the effect control board 310, and the coupling portion (connector for inspection) 317 The fitting portion 317a is arranged so as to face the outside of the effect control board 310. Thereby, even when the inspection connecting portion 317 is mounted on the invisible surface of the production control board 310, the production display inspection apparatus (debug device 350) can be easily operated from the side of the production control board 310. You will be able to connect.

<Modification 3>
Next, a modified example of the above-described effect control board 310 will be described with reference to FIG.
FIG. 13A is a front view of the effect control board 310 of Modification 3, and FIG. 13B is a rear view of the effect control board 310.
As shown in FIGS. 13A and 13B, the production control board 310 of Modification 3 has a debugging device connection circuit 315 and a test connection part (test connector) 317 on the front side of the production control board 310. It is to be implemented. Further, on the plane (both sides) of the production control board 310, a notch 310a is formed in the periphery (attachment area A) where the debugging device connection circuit 315 and the inspection connection portion (inspection connector) 317 are mounted. When the game machine 10 is mass-produced, the debugging control circuit 310 is cut along the notch 310a to remove the debug device connection circuit 315 and the test connection unit (test connector) 317. Can be shipped.

Next, control executed by the game microcomputer (game microcomputer) 111 of the game control apparatus 100 will be described.
The control process by the gaming microcomputer 111 includes a main process (mainly see FIGS. 14 and 15) that is a main routine that is repeated as a loop process, and a timer that is performed at a predetermined time period (for example, 4 ms) as an interrupt routine for the main process. Interrupt processing (see FIG. 16).

[Main processing]
First, the main process will be described.
The main process is started when the power is turned on. In this main process, as shown in FIG. 14, an interrupt vector setting process (step S1) is first performed to set a jump destination vector address to be executed when an interrupt occurs. Step S2), a stack pointer setting process for setting a stack pointer that is the start address of an area for saving a value of a register or the like when an interrupt occurs (Step S3), an interrupt mode setting process for setting an interrupt processing mode (Step S3) S4) is performed.

  Next, in order to wait for the program of the payout control apparatus (payout board) 200 to start up normally, for example, a time of 4 ms is waited (step S5). As a result, when the power is turned on, the game control device 100 first rises and the command is sent to the payout control device 200 before the payout control device 200 starts up, so that the payout control device 200 avoids losing the command. be able to. After that, access to a readable / writable RWM (read / write memory) such as a RAM or EEPROM is permitted, and off data is set so that there is no output in all output ports (steps S6 and S7). Also, the serial port ((port previously installed in the gaming microcomputer 111) is not used in this embodiment because it is in parallel communication with the payout control device 200 and the effect control device 300). Is performed (step S8).

  Subsequently, it is determined whether or not the initialization switch in the power supply apparatus 400 is ON (step S9). Here, when it is determined that the initialization switch is OFF (step S9; No), in step S10, the value of the data in the power failure inspection region 1 is checked among a plurality of power failure inspection regions provided in the RWM. (Step S10), it is determined whether or not the value of the power failure inspection area 1 is normal power failure inspection area check data 1 (Step S11). If it is determined in step S11 that the value of the power outage inspection area 1 is normal power outage inspection area check data 1 (step S11; Yes), the value of the data in the power outage inspection area 2 is checked (step S12), It is determined whether or not the value of the power failure inspection area 2 is normal power failure inspection area check data 2 (step S13). If it is determined in step S13 that the value of the power failure inspection area 2 is normal power interruption inspection area check data 2 (step S13; Yes), a process of calculating data called a checksum (step S14) is performed. The calculated checksum is compared with the checksum when the power is turned off (step S15), and it is determined whether or not the values match (step S16).

  Moreover, when it determines with the initialization switch being ON by step S9 (step S9; Yes), when it determines with the value of the power failure test | inspection area | region 1 not normal at step S11 (step S11; No), it is a power failure at step S13. If it is determined that the value of the inspection area 2 is not normal (step S13; No), or if it is determined in step S16 that the checksums do not match (step S16; No), the process jumps to step S24 in FIG. .

  If it is determined in step S16 that the checksums match (step S16; Yes), the process proceeds to step S17 in FIG. 15 to clear all power failure inspection areas (step S17). After performing the clearing process (step S18), the area related to the error or fraud monitoring is reset (step S19). Next, an area for storing the gaming state in the RWM is examined to determine whether or not the gaming state is a high probability state (step S20). If it is determined that the probability is not high (step S20; No), steps S21 and S22 are skipped and the process proceeds to step S23.

  If it is determined in step S20 that there is a high probability (step S20; Yes), the ON information is saved in the high-probability notification flag area (step S21), and then, for example, the high provided in the batch display device 50 The ON data for turning on (lighting) the probability notification LED (error indicator) is saved in the area (port 136) corresponding to the segment (step S22), and the process proceeds to step S23. In step S23, a power failure recovery command corresponding to the special figure game process number is transmitted, and the process proceeds to step S29.

  On the other hand, when jumping from step S9, S11, S13, S16 to step S24, first, the process of clearing all work areas before the access prohibited area in the RAM used by the CPU 111A (step S24), the access prohibited area After the process of clearing all subsequent stack areas (step S25), the initial value at power-on is saved in the area to be initialized (step S26). Then, an output timer initial value of external information (security signal) relating to clearing of the RWM is saved in the security signal control timer area (step S27), and a command at power-on is transmitted to the effect control device 300 (step S28). ) And the process proceeds to step S29.

In step S29, a process of starting a CTC (Counter / Timer Circuit) circuit that generates a timer interrupt signal and a random number update trigger signal (CTC) in the gaming microcomputer 111 (clock generator) is performed.
The CTC circuit is provided in a clock generator in the gaming microcomputer 111. The clock generator divides the oscillation signal (original clock signal) from the crystal oscillator 113, a timer interrupt signal and a random number having a predetermined period (for example, 4 ms) to the CPU 111A based on the divided signal. And a CTC circuit that generates a signal CTC that gives a trigger for updating a random number to be supplied to the generation circuit.

  After the CTC activation process in step S29, a process for activating and setting the random number generation circuit is performed (step S30). Specifically, the CPU 111A performs setting of a code (specified value) for starting the random number generation circuit in a predetermined register (CTC update permission register) in the random number generation circuit. Then, the values of the predetermined registers (soft random number registers 1 to n) in the random number generation circuit at the time of power-on are changed to various initial value random numbers (random numbers for determining the big hit symbol (big hit symbol random number 1, big hit symbol random number 2) After saving the initial value (start value) of a random number for determining the hit of the usual figure (start value) in a predetermined area of the RWM (step S31), the interruption is permitted (step S32). In the random number generation circuit in the CPU 111A used in the present embodiment, since the initial value of the soft random number register is changed every time the power is turned on, this value is the initial value of various initial value random numbers generated on the CPU side. By setting (start value), it is possible to break the regularity of random numbers generated by software, making it difficult for a player to obtain illegal random numbers.

  Subsequently, an initial value random number update process (step S33) is performed to update the values of various initial value random numbers to break the regularity of the random numbers. In the present embodiment, although not particularly limited, the big hit random number is configured to be generated using a random number (big hit random number) generated in a random number generation circuit. That is, the big hit random number is a hard random number generated by hardware, and the big hit symbol random number is a soft random number generated by software.

  After the initial value random number update process in step S33, the number of times that the power failure monitoring signal is checked is set (step S34). Then, the power failure monitoring signal input from the power supply device 400 is read and checked via the port and the data bus, and it is determined whether or not the power failure monitoring signal is ON (step S35). If it is determined in step S35 that the power failure monitoring signal is not ON (step S35; No), the process returns to step S33, and the initial value random number update processing and the power failure monitoring signal check (loop processing) are repeated. By permitting an interrupt before the initial value random number update process (step S33) (step S32), if a timer interrupt occurs during the initial value random number update process, the interrupt process is executed with priority, and the timer interrupt Can be prevented from being interrupted by waiting for the initial value random number update process.

  Note that the initial value random number update process in step S33 includes a method of performing an initial value random number update process in the timer interrupt process in addition to the main process. In order to avoid execution of value random number update processing, when performing initial value random number update processing in the main processing, it is necessary to disable interrupt and then update to cancel the interrupt. If the initial value random number update process in the timer interrupt process is not performed in the main process and only the main process is performed, there is no problem even if the interrupt is canceled before the initial value random number update process. There is an advantage that it is simplified.

  If it is determined in step S35 that the power failure monitoring signal is ON (step S35; Yes), it is determined whether or not ON is continued for the set number of checks (step S36). And when it determines with not having been continued (step S36; No), it returns to step S35 and repeats determination (loop process) of whether the power failure generate | occur | produced. If it is determined in step S36 that the operation has been continued (step S36; Yes), that is, if it is determined that a power failure has occurred, processing for temporarily prohibiting interruption (step S37), all output ports are turned OFF. A process of outputting data (step S38) is performed. Thereafter, a process for saving the power failure recovery inspection area check data 1 in the power failure recovery inspection area 1 (step S39), a process for saving the power failure recovery inspection area check data 2 in the power failure recovery inspection area 2 (step S40), and the power supply of the RWM After the process of calculating the checksum at the time of blocking (step S41), the calculated checksum is saved in the checksum area (step S42), and the process of prohibiting access to the RWM (step S43) is performed. And wait for the power to the gaming machine to be cut off. Thus, by saving the check data in the power failure recovery inspection area and calculating the checksum at the time of power interruption, the information stored in the RWM before the power interruption of the gaming machine 10 due to the power failure or the like is correct. Whether or not the game machine 10 is backed up can be determined when the gaming machine 10 is turned on again.

[Timer interrupt processing]
Next, timer interrupt processing will be described.
As shown in FIG. 16, the timer interrupt process is started when a periodic timer interrupt signal generated by the CTC circuit in the clock generator is input to the CPU 111A. When a timer interrupt occurs in the gaming microcomputer 111, the timer interrupt process of FIG. 16 is started.

  When the timer interrupt process is started, the game microcomputer 111 of the game control device 100 first performs a register save process (step S51) for transferring a value held in a predetermined register to the RWM. In the Z80 microcomputer used as the gaming microcomputer in this embodiment, the processing can be replaced by saving the value held in the front register to the back register. Next, an input process (step S52) for taking in inputs from various sensors (start port 1 switch 36a, start port 2 switch 37a, usual gate switch 34a, count switch 38a, etc.), that is, reading the state of each input port. )I do. Then, based on the output data set in various processes, an output process (step S53) for performing drive control of an actuator such as a solenoid (large winning opening SOL38b, general electric power SOL37c) and the like is performed.

Next, a command transmission process (step S54), a random number update process 1 (step S55), and a random number update process 2 (steps) for outputting commands set in the transmission buffer in various processes to the effect control device 300, the payout control device 200, and the like. S56) is performed.
Thereafter, it is monitored whether a normal signal is input from the start port 1 switch 36a, the start port 2 switch 37a, the usual gate switch 34a, the winning port switch 35a... 35n, and the count switch 38a. A prize opening switch / error monitoring process (step S57) is performed to determine whether the front frame or the glass frame is open. Also, a special figure game process (step S58) for performing a process related to the special figure variable display game and a general figure game process (step S59) for performing a process related to the general map variable display game are performed.

  Next, a segment LED editing process (step S60) that is provided in the gaming machine 10 and that drives a segment LED that displays special information variation display game and various information related to the game to display desired contents, magnetic sensor switch A magnetic error monitoring process (step S61) is performed in which detection signals from 61 and the vibration sensor switch 62 are checked to determine whether there is any abnormality. Then, external information editing processing (step S62) is performed in which signals to be output to various external devices are set in the output buffer. Subsequently, a process of clearing the interrupt request and declaring the end of the interrupt (step S63), a process of restoring the register data saved in step S51 (step S64), and a process of permitting the interrupt (step S64) Step S65) is performed, and the timer interrupt process is terminated.

[Special Figure Game Processing]
Next, details of the special game process (step S58) in the timer interrupt process described above will be described.
In the special figure game process, the input of the start port 1 switch 36a and the start port 2 switch 37a is monitored, the entire process related to the special figure variation display game is controlled, and the special figure display is set.

  As shown in FIG. 17, in the special figure game process, first, a start port switch monitoring process (step A1) for monitoring a winning of the start port 1 switch 36a and the start port 2 switch 37a is performed. In the start port switch monitoring process, when a game ball is won in the normal variable winning device 37 that forms the start winning port 36 and the second starting winning port, various random numbers (such as big hit random numbers) are extracted, and a special feature based on the winning is obtained. Prior to the start of the figure variation display game, a game result preliminary determination is performed in which a game result based on a prize is determined in advance.

  Next, a count switch monitoring process (step A2) is performed. In this count switch monitoring process, a process of monitoring the count number of the count switch 38a provided in the special variation winning device 38 is performed.

Next, it is checked whether the special figure game processing timer has already timed up, or the special figure game processing timer has been updated (-1) and then timed up (step A3). It is determined whether the time is up (step A4).
If it is determined in step A4 that the special figure game process timer has expired (step A4; Yes), a special figure game sequence branch table to be referred to branch to the process corresponding to the special figure game process number is registered. (Step A5) is performed, and a process (step A6) of acquiring a branch destination address of the process corresponding to the special figure game process number is performed using the table.
Then, after performing the process of saving the return address after the branch process to the stack area (step A7), the game branch process (step A8) is performed according to the special figure game process number.

  If the special figure game process number is “0” in step A8, the fluctuation start of the special figure fluctuation display game is monitored, the fluctuation start setting of the special figure fluctuation display game, the setting of the production, A special figure routine process (step A9) for setting information necessary for the process is performed.

  In step A8, when the special figure game process number is “1”, the special figure change for setting the special figure stop display time, setting the information necessary for performing the special figure display process, etc. Medium processing (step A10) is performed.

  In step A8, when the special figure game process number is “2”, if the game result of the special figure fluctuation display game is a big hit, the fanfare command is set according to the big hit type (2R big hit or 15R big hit). In addition, special chart display processing (step A11) for setting fanfare time according to the big winning opening opening pattern of each big hit (2R big hit or 15R big hit), setting information necessary for performing fanfare / interval processing, etc. )I do.

  If the special figure game process number is “3” in step A8, setting of the opening time of the big prize opening, updating of the number of times of opening, setting of information necessary for performing the processing during opening of the big prize opening, etc. The fanfare / interval processing (step A12) is performed.

  In step A8, when the special figure game process number is “4”, if the big hit round is not the final round, an interval command is set, whereas if it is the final round, a process for setting a big hit end screen command is set. Then, a special winning opening opening process (step A13) for setting information necessary for the special winning opening remaining ball processing is performed.

  In step A8, if the special figure game process number is “5”, if the big hit round is the final round, a process for setting the time for discharging the remaining balls in the big prize opening, The big winning opening remaining ball processing (step A14) for setting information necessary for processing is performed.

  If the special figure game process number is “6” in step A8, a big hit end process (step A15) for setting information necessary for performing the special figure normal process (step A9) is performed.

  Then, after preparing the table for controlling the fluctuation | variation of a special figure 1 display or a special figure 2 display (step A16), the symbol fluctuation control process (step A17) which concerns on a special figure 1 display or a special figure 2 display ) To complete the special figure game process.

  On the other hand, when it is determined in step A4 that the special figure game process timer has not expired (step A4; No), the process proceeds to step A16, and the subsequent processes are performed.

[1st main processing]
The main control microcomputer (1st CPU) 311 of the effect control device 300 performs the 1st main process shown in FIG. In this 1st main process, the process at the start of the program is first performed. As processing at the time of starting the program, first, interrupts are prohibited (step B11), the RAM is cleared to 0 (step B12), and a CPU initialization process (step B13) for initializing the CPU is performed. Next, an initial value of the RAM is set (step B14), random number initialization processing (step B15) for initializing random numbers is performed, timers for various interrupts are started (step B16), and interrupts are permitted (step B16). B17).

  Next, loop processing is performed as main loop processing. In this loop process, first, WDT (watchdog timer) is cleared (step B18), and an effect button input process (step B19) for creating input information from an input signal (rising edge) based on the operation of the effect button 25 is performed. . Thereafter, a game control command analysis process (step B20) is performed. In this game control command analysis process (step B20), it is determined whether or not a command related to a game transmitted from the game control apparatus 100 has been correctly received. Processing to classify commands for processing.

  Next, a test mode process (step B21), which is a process related to a test mode for testing the display device 41, the decoration device, the rendering device, and the like, is performed. When the test mode is set by the test mode process (step B21), the subsequent game-related processes are not performed. However, in the test mode, when performing display on the display device 41, output of sound from the speaker, light emission of the LED of the decoration device, operation of the effect device, etc., control is performed in a process for controlling these. Note that the test mode ends when the gaming machine is powered off.

  Next, between the main control microcomputer (1stCPU) 311 and the video control microcomputer (2ndCPU) 312, between the main control microcomputer (1stCPU) 311 and the debug device 350, and the video control microcomputer (2ndCPU) 312. And a communication permission process (step B22) for determining whether or not to permit command communication between the debugging device 350 and the debugging device 350. Details of the communication permission process will be described later.

  And the 1st scene control process (step B23) regarding control of the effect of a game is performed. Details of the first scene control process (step B23) will be described later. Next, based on an error notification command transmitted from the game control device 100 when an error occurs in the gaming machine, a gaming machine error monitoring process (step B24) for performing a corresponding notification is performed. In addition, the display on the display device 41 for performing the corresponding notification, the sound output from the speaker, the light emission of the LED of the decoration device, the operation of the effect device, and the like are controlled in a process for controlling these.

  Thereafter, an effect command editing process (step B25) for editing a command to be output to the video control microcomputer (2ndCPU) 312 is performed, and a sound control process for controlling the sound output from the speakers (upper speaker 19a and lower speaker 19b). (Step B26) is performed. Next, a decoration control process for controlling the LEDs of the panel decoration device 42 and the frame decoration device 18 (step B27), and a motor / SOL control process for controlling the motors and solenoids of the board effect device 44 and the frame effect device 45 (step) B28) is performed. And the random number update process (step B29) which updates the random number which determines the detail of the fluctuation | variation aspect of a decoration special figure change display game is performed, and it returns to the process (step B18) which clears WDT.

[1st scene control processing]
Next, details of the 1st scene control process (step B23) in the 1st main process described above will be described. As shown in FIG. 19, in the 1st scene control process, first, it is determined whether or not the test mode is in effect (step B31). If the test mode is in effect (step B31; Yes), the 1st scene control process is terminated. . When the test mode is not being executed (step B31; No), it is determined whether a scene change command has been received (step B32).

  The scene change commands are various commands relating to games transmitted from the game control device 100 to the effect control device 300. When this scene change command is received (step B32; Yes), the game state to be updated (current game state) is acquired (step B33), and it is determined whether the command is a valid command (step B34). In determining whether the command is valid (step B34), it is determined whether the received scene change command is valid for the acquired current gaming state. If the command is valid (step B34; Yes), the received command is saved (step B35), an effect request flag is set (step B36), and a branch process based on the command identifier of the received command (step B37). )I do.

  On the other hand, when the scene change command has not been received (step B32; No) or when it is not a valid command (step B34; No), branch processing (step B37) based on the command identifier of the received command is performed. In this case, a branch is performed based on the identifier of the command that was most recently valid.

  In the branch process based on the command identifier (step B37), a process to be executed is selected based on the received command. When a power-on command is received, a power-on process (step B38) for performing a process necessary when the power is turned on is performed. When a power failure recovery command is received, a power failure recovery (other than waiting for a customer) process (step B39) is performed for performing processing necessary at the time of power failure recovery. When a customer waiting demo command is received, a customer waiting process (step B40) for performing processing related to the display of the customer waiting demo is performed.

  When a variation pattern command is received, a variation processing (step B41) for performing processing relating to the execution of the decoration special diagram variation display game is performed. In the changing process (step B41), information necessary for playing the decorative special figure changing display game is set. In the setting of information necessary for playing this decoration special figure variation display game, for example, information included in the variation pattern command transmitted from the game control device 100 (whether it is a big hit, mode information, variation pattern information, etc.) Based on this, the production (variation pattern, variation time, etc.) is set. Further, when the variation time of the special figure variation display game is ended, the variation display of the identification information in the decoration special figure variation display game is stopped, the stop display time is set, and the like.

Further, when a symbol stop command is received, a symbol stop process (step B42), which is a process of stopping the variation display of the identification symbol in the decorative special symbol variation display game and displaying the result mode, is performed. In the symbol stop process, the stop display time of the result in the decorative special symbol variation display game is set.
When a fanfare command is received, a fanfare process (step B43), which is a process related to the start of the special game state or the specific game state, is performed. In addition, when the large entry / release n-th command is received, an in-round process (step B44) which is a process related to the round game is performed. When an interval command is received, an interval process (step B45) that is a process related to an interval between rounds is performed. When an ending command is received, an ending process (step B46), which is a process related to the end of the special game state or the specific game state, is performed.

  After performing each of the above-described processes selected by the branch process based on the command identifier (step B37), a process based on a command that is not immediately reflected in the video is performed. As this process, first, a symbol command reception process (step B47) for performing processing based on a decoration special symbol command including information related to a stop symbol of the special symbol variation display game is performed, and a hold number command (including information related to increase / decrease of the start memory) ( A hold number command reception process (step B48) is performed for performing processing based on the special figure 1 hold number command and the special figure 2 hold number command.

  Further, a prefetch command (start opening prize effect command, winning effect symbol command) including a result of a prefetching process for determining the result of the special figure variation display game based on the start memory in advance before the execution of the special figure variation display game is used. A prefetch command reception process (step B49) for performing the process based on this is performed. Thereafter, a probability information command receiving process (step B50) is performed for performing a process based on a probability information command including information on the probability state.

[2nd main processing]
The video control microcomputer (2ndCPU) 312 performs a 2nd main process shown in FIG. In the 2nd main process, the process at the start of the program is first performed. As processing at the start of the program, first, CPU initialization processing (step B51) for initializing the CPU is performed, the RAM is cleared to 0 (step B52), and the initial value of the RAM is set (step B53). Next, VDP initialization processing (step B54) for initializing VDP is performed, and various interrupts are permitted (step B55). Furthermore, initialization processing (step B56) of various control devices is performed, and screen drawing is permitted (step B57).

  Next, loop processing is performed as main loop processing. In this loop processing, first, the system cycle wait flag is cleared (step B58), and it is determined whether or not the system cycle wait flag is 1 (step B59). The system cycle is a cycle for switching between two buffers for temporarily storing image data. When the switching is enabled, the system cycle flag is “1”. Until the system cycle wait flag becomes 1, the determination whether the system cycle wait flag is 1 is repeated (step B59). When the system cycle wait flag becomes 1 (step B59; Yes), WDT (watchdog timer) is cleared (step B60), the normal game process (step B61) is performed, and the process returns to the process of clearing the system cycle waiting flag (step B58).

[Normal game processing]
Next, details of the normal game process (step B61) in the above-described 2nd main process will be described. As shown in FIG. 21, in the normal game process, first, a received command check process (step B71) is performed. In this received command check process (step B71), it is determined whether or not the command transmitted from the 1st CPU 311 has been correctly received. If the command has been correctly received, the command is determined and the command for the next 2nd scene control process is determined. Process to classify.

  Next, a background process (step B72) for setting a background is performed, and a reel control / display process (step B73), which is a display control process related to the variation of the identification information in the decoration special figure variation display game, is performed. Furthermore, the display of the special figure 1 hold indicator and the special figure 2 hold indicator, that is, a setting for changing the display of the special figure hold number displayed on the display device 41 in accordance with the increase / decrease of the hold number, the game state, etc. The hold display process (step B74) to be performed is performed, and the customer waiting demonstration process (step B75) relating to the display of the customer waiting demonstration is performed. Then, a scene control / display process (step B76) is performed, a ROM system data is transferred to a buffer set in the RAM, and a display system process (step B77) is performed for actual display. Exit.

[V blank interrupt processing]
Next, the V blank interrupt process will be described with reference to the flowchart shown in FIG.
The V blank interrupt process shown in FIG. 22 is started when a periodic V blank interrupt signal is input to the 2nd CPU 312 every 16.6 ms (1/2 of the frame period 33 ms), for example.

  When the V blank interrupt process is started, first, a process of updating the value of the frame counter by +1 is performed (step B81), and it is determined whether or not the value of the frame counter is equal to or greater than a specified value (step B82).

  Here, when the value of the frame counter is less than the specified value (step B82; No), the V blank interrupt process is terminated, and when the value of the frame counter is equal to or greater than the specified value (step B82; Yes), the process goes to step B83. Then, it is determined whether or not the system cycle wait flag is “0” (step B83).

  If it is determined in step B83 that the system cycle wait flag is not "0" (step B83; No), the V blank interrupt process is terminated, and the system cycle wait flag is determined to be "0" ( Step B83; Yes) proceeds to Step B84, and determines whether or not the VDP 313 has completed the drawing displayed on the display device 41 (Step B84).

  If it is determined in step B84 that the VDP 313 has not completed drawing (step B84; No), the V blank interrupt process is terminated, and if it is determined that the VDP 313 has completed drawing (step B84; Yes). The process proceeds to step B85, performs the process of switching the display frame buffer, and then instructs to start drawing in the display frame buffer switched by the VDP 313 (step B86). By setting the specified value to “2”, for example, it is possible to basically switch frames once every two V blank interrupts.

  Next, after performing processing (step B87) for setting a VDP drawing flag indicating that VDP 313 has started drawing, processing for clearing the frame counter to 0 (step B88), and setting the system cycle wait flag to “1” The processing (step B89) is sequentially performed, and the V blank interrupt processing is terminated.

[Communication permission processing]
Next, details of the communication permission process (step B22) in the above-described normal game process will be described. As shown in FIG. 23, in the communication permission process, first, it is determined whether or not the debug device 350 is being mounted (connected) (step B91).

  Here, when it is determined that the debug device 350 is being mounted (step B91; Yes), processing for permitting communication between the first CPU 311 and the second CPU 312 (step B92) is performed. Next, processing for permitting communication between the 1st CPU 311 and the debugging device 350 (step B93) is performed. Then, processing for permitting communication between the 2nd CPU 312 and the debugging device 350 (step B94) is performed, and the communication permission processing is terminated.

  On the other hand, if it is determined that the debug device 350 is not being installed (step B91; No), a process for permitting communication between the first CPU 311 and the second CPU 312 (step B95) is performed, but between the first CPU 311 and the debug device 350 is performed. Processing for disabling communication (step B96) is performed, processing for disabling communication between the 2nd CPU 312 and the debug device 350 (step B97) is performed, and the communication permission processing is terminated.

Next, an example of a method for determining whether or not the debugging device 350 is being mounted will be described with reference to FIG.
FIG. 24A shows that when the gaming machine 10 is developed, that is, when the debugging device connection circuit 315 and the inspection connection unit 317 are mounted on the gaming machine 10, the debugging device 350 is mounted on the effect control device 300 ( (B) is a diagram showing a state where the debugging device 350 is not mounted (connected) to the effect control device 300 when the gaming machine 10 is developed.

As shown in FIGS. 24A and 24B, the debug device connection circuit 315 for connecting the 1st CPU 311 and the debug device 350 has a circuit configuration of an open collector output format.
As shown in FIG. 24A, when the debug device 350 is connected to the debug device connection circuit 315 via the test connection portion (test connector) 317, the transistor T is turned on, and the ground is grounded. As a result, a low voltage (connection signal (connection command)) is output.
Also, as shown in FIG. 24B, when the debug device 350 is not connected to the debug device connection circuit 315 via the test connection portion (test connector) 317, the transistor T is turned off, A high voltage (connection signal (connection command)) is output by the pull-up resistor R.
Accordingly, the 1st CPU 311 can determine whether or not the debug device 350 is connected to the debug device connection circuit 315 via the test connection unit (test connector) 317 according to the output voltage. It has become.

  Next, commands transmitted between the 1st CPU 311 and the 2nd CPU 312, between the 1st CPU 311 and the debug device 350, and between the 2nd CPU 312 and the debug device 350 will be described with reference to FIGS. 25 and 26.

  As shown in FIG. 25, when the debugging device 350 is connected to the debugging device connection circuit 315 via the inspection connection unit (inspection connector) 317 during the development of the gaming machine 10, as described above, the debugging device When a low voltage (connection signal (connection command)) is output from 350 to the first CPU 311, it is determined that the debug device 350 is connected to the debug device connection circuit 315 via the test connection unit (test connector) 317. (Step B91; see FIG. 23) Communication between the 1st CPU 311 and the 2nd CPU 312 is possible between the 1st CPU 311 and the debug device 350, and between the 2nd CPU 312 and the debug device 350 (Steps B92 to B94; FIG. 23). reference).

Then, an effect control command for performing video control can be transmitted from the 1st CPU 311 to the 2nd CPU 312. Further, when the effect control command transmitted from the 1st CPU 311 to the 2nd CPU 312 is a command selected based on the lottery result of the random value extracted by the 1st CPU 311, the random value is output from the 1st CPU 311 to the debugging device 350. A random value information command including is sent.
Further, the 2nd CPU 312 can transmit the effect control command received from the 1st CPU 311 to the debugging device 350.

In addition, when the debug device 350 is connected to the debug device connection circuit 315 via the test connection unit (test connector) 317, the debug device 350 allows the developer to verify the contents of the effect display. A debug request signal (debug request command) can be transmitted to the 1st CPU 311. At this time, an effect control command based on the debug request signal received from the debug device 350 is transmitted from the first CPU 311 to the 2nd CPU 312, and the effect control command includes a debug display command.
Here, the debug display command is a command for causing the display device 41 to display information or the like (see FIG. 48) relating to the production content corresponding to the debug request signal.

  The debug device 350 is connected to a development verification jig (not shown). The debugging device 350 includes a RAM (not shown) as a storage unit that temporarily stores information. Thereby, the debugging device 350 can store the effect control command received from the 2nd CPU 312 in the RAM, convert the effect control command into a verification command, and transmit the command to the development verification jig.

FIG. 26 is a diagram illustrating a state in which the debug device 350 is not connected to the debug device connection circuit 315 via the test connection unit (test connector) 317 during the development of the gaming machine 10.
As shown in FIG. 26, when the debug device 350 is not connected to the debug device connection circuit 315 via the test connection unit (test connector) 317, the high voltage (from the debug device 350 to the 1st CPU 311 as described above. When the connection signal (connection command) is output, it is determined that the debugging device 350 is not connected to the inspection connection unit (inspection connector) 317 (step B91; see FIG. 23), the 1st CPU 311 and the debugging device 350. And communication between the 2nd CPU 312 and the debug device 350 are disabled (steps B96 and B97; see FIG. 23).
As a result, when the debug device 350 is not connected to the debug device connection circuit 315 via the test connection unit (test connector) 317, the random value information command is not transmitted from the 1st CPU 311 to the debug device 350. It becomes. Further, the production control command is not transmitted from the 2nd CPU 312 to the debugging device 350.

Next, a communication protocol between the 1st CPU 311 and the 2nd CPU 312 will be described with reference to FIG.
FIG. 27A schematically shows a communication packet format, FIG. 27B schematically shows a communication character format, and FIG. 27C shows a data range of each character. (D) is a figure for demonstrating the transmission interval of a communication packet.

The communication packet format is a packet telegram method in which a plurality of characters are combined into one. Specifically, each packet is defined by a 16-character fixed length packet. Note that “NULL” is defined for unused or spare characters.
As shown in FIG. 27 (a), the top of each packet is a “PT (Packet Top)” character, and after the “PT” character, the order of “PD (Packet Data)” characters is defined. Yes. The end of each packet does not have an END character because the packet length for each PT is determined.

As shown in FIG. 27B, each of the 16 characters constituting each packet includes a 1-bit (fixed to 0) start bit (“Start”), an 8-bit data bit, and a 1-bit (EVEN parity) parity. It consists of a bit (“Parity”) and a 1-bit (1 fixed) stop bit (“Stop”).
In addition, as shown in FIG. 27C, the data range of each character is “F0H” to “FFH” for the “PT” character, “01H” to “EFH” for the “PD” character, and “NULL”. The character is “00H”.
In the following description, 8-bit data is divided into 4 bits, and each of the upper 4 bits and the lower 4 bits is represented by a hexadecimal number corresponding to 16 characters “0” to “F”.

  Further, as shown in FIG. 27D, the transmission interval from the start of each packet transmission to the start of the next packet transmission is one frame or more for drawing.

Hereinafter, a packet (effect control command) communicated between the first CPU 311 and the second CPU 312 will be described with reference to FIGS.
Communication packets transmitted from the 1st CPU 311 to the 2nd CPU 312 include, for example, a power-on packet (see FIG. 28), a customer waiting packet (see FIG. 29), a customer waiting demo packet (see FIG. 30), and a variable packet (continuous 0 to 2). Round) (see FIGS. 31 to 33), decorative symbol stop packet (see FIG. 34), fanfare packet (see FIG. 35), round number packet (see FIG. 36), interval packet (see FIG. 37), ending packet (see FIG. 38) and event type packets (see FIG. 39).
The data structure of each of these communication packets will be described individually for each packet below.

Hereinafter, the power-on packet will be described with reference to FIG.
FIG. 28A is a diagram schematically showing the data structure of the power-on packet, and FIG. 28B is a diagram showing an example of the data structure of the power-on packet.

As shown in FIG. 28A, the power-on packet includes a first character that is a “PT” character, and second to sixteenth characters (“PD1” to “PD1” to “PD1”) that relate to various commands related to power-on of the gaming machine 10. "PD15" character).
Specifically, for example, as shown in FIG. 28B, the first character is data for identifying a power-on packet and is represented by “F0H”.
The second character is data for turning on the power, the data represented by “01H” is for designating RAM initialization, and the data represented by “02H” is designated for power failure recovery. The data represented by “03H” is for performing a power failure recovery (waiting for customer) designation.
The third character is data for specifying the game mode, and is represented by “01H” to “EFH”.
The fourth character is data for designating the effect background, and is represented by “01H” to “EFH”.
The fifth character is data for making a hold designation (special 1 hold number / special 2 hold number designation), and is represented by “00H” to “44H”.
The sixth character is data for specifying the left symbol and right symbol (symbol 1) of the display device 41 (when the power is turned on), and is represented by “01H” to “EFH”.
The seventh character is data for specifying the middle symbol of the display device 41 and special figure 1 or special figure 2 (when the power is turned on), and is represented by “01H” to “EFH”. .
The eighth to fifteenth characters are unused and are represented by “00H”.
The sixteenth character is data for specifying the model, and is represented by “01H” to “EFH”.

Hereinafter, the customer waiting packet will be described with reference to FIG.
FIG. 29A is a diagram schematically illustrating a data structure of a customer waiting packet, and FIG. 29B is a diagram illustrating an example of a data structure of a customer waiting packet.

As shown in FIG. 29A, the customer waiting packet includes a first character that is a “PT” character and second to second commands related to designation of a customer waiting screen displayed on the display device 41. It consists of 16th characters (“PD1” to “PD15” characters).
Specifically, for example, as shown in FIG. 29B, the first character is data for identifying a customer waiting packet and is represented by “F1H”.
The second character is data for specifying the customer waiting screen, and the data represented by “01H” is for designating the A state during customer waiting and is represented by “02H”. The data designates the waiting B state.
The third character is data for specifying the game mode, and is represented by “01H” to “EFH”.
The fourth character is data for designating the effect background, and is represented by “01H” to “EFH”.
The fifth to fifteenth characters are unused and are represented by “00H”.
The sixteenth character is data for specifying the model, and is represented by “01H” to “EFH”.

The customer waiting demo packet will be described below with reference to FIG.
FIG. 30A is a diagram schematically illustrating a data structure of a customer waiting demo packet, and FIG. 30B is a diagram illustrating an example of a data structure of a customer waiting demo packet.

As shown in FIG. 30 (a), the customer waiting demo packet includes a first character that is a “PT” character and second commands related to various commands related to designation of the customer waiting demo screen displayed on the display device 41. To 16th characters ("PD1" to "PD15" characters).
Specifically, for example, as shown in FIG. 30 (b), the first character is data for identifying the customer waiting demo packet and is represented by "F2H".
The second character is data for designating the customer waiting demonstration screen, and is represented by “01H” to “EFH”.
The third character is data for specifying the game mode, and is represented by “01H” to “EFH”.
The fourth character is data for specifying a demonstration for waiting for a customer, and is represented by “01H” to “EFH”.
The fifth character is data for designating the background character displayed on the display device 41 and is represented by “01H” to “EFH”.
The sixth character is data for designating the movement of the movable accessory arranged in the center case 40 or the like, and is represented by “01H” to “EFH”.
The seventh to fifteenth characters are unused and are represented by “00H”.
The sixteenth character is data for specifying the model, and is represented by “01H” to “EFH”.

Hereinafter, the variable packet (continuation 0th) will be described with reference to FIG.
FIG. 31A is a diagram schematically illustrating the data structure of the variable packet (continuation 0th), and FIG. 31B is a diagram illustrating an example of the data structure of the variable packet (continuation 0th). .

As shown in FIG. 31 (a), the change packet (continuation 0th) is related to the designation of the game contents of the first character that is the “PT” character and the special figure change display game displayed on the display device 41. It consists of second to sixteenth characters (“PD1” to “PD15” characters) related to various commands.
Specifically, for example, as shown in FIG. 31B, the first character is data for identifying a variable packet, and is represented by “F3H”.
The second character is data for displaying the change M (equivalent to the MODE of the main command) and designating the display time, and is represented by “01H” to “EFH”.
The third character is data for displaying the change A (equivalent to the main command ACTION) and designating the display time, and is represented by “01H” to “EFH”.
The fourth character is data for designating the symbol 1, that is, the first stop symbol (left symbol) that stops first, and the second stop symbol (right symbol) that stops next, “01H”. ~ "EFH".
The fifth character is data for designating the second stop symbol, that is, the third stop symbol (medium symbol) that stops next to the second stop symbol, and the special symbol 1 or special symbol 2, and is “01H”. ~ "EFH".
The sixth to fifteenth characters are data for specifying the distribution notice of change notice (use of the assignment table of notices 1 to 10), and are represented by “01H” to “EFH”.
The sixteenth character is data for continuing to the variable packet (the first continuation), and is represented by “81H”.

In the following, the variable packet (the first continuation) will be described with reference to FIG.
FIG. 32A is a diagram schematically illustrating the data structure of the variable packet (continuation first time), and FIG. 32B is a diagram illustrating an example of the data structure of the variable packet (continuation first time). .

As shown in FIG. 32 (a), the change packet (the first continuation) is related to the designation of the game contents of the first character that is the “PT” character and the special figure change display game displayed on the display device 41. It consists of second to sixteenth characters (“PD1” to “PD15” characters) related to various commands.
Specifically, for example, as shown in FIG. 32B, the first character is data for identifying a variable packet, and is represented by “F4H”.
The second to thirteenth characters are data for designating the change notice distribution (use of the notice table 11-22 notice table), and are represented by “01H” to “EFH”.
The 14th character is data for designating the number of jackpots displayed on the display device 41, and is represented by “01H” to “EFH”.
The fifteenth character is data for specifying the number of time reductions displayed on the display device 41, and is represented by “01H” to “EFH”.
The sixteenth character is data for continuing to the variable packet (continuation second time), and is represented by “82H”.

Hereinafter, the variable packet (second continuous) will be described with reference to FIG.
FIG. 33A is a diagram schematically illustrating the data structure of the variable packet (second continuous), and FIG. 33B is a diagram illustrating an example of the data structure of the variable packet (second continuous). .

As shown in FIG. 33 (a), the variation packet (continuation second time) is related to the designation of the game contents of the first character that is the “PT” character and the special-figure variation display game displayed on the display device 41. It consists of second to sixteenth characters (“PD1” to “PD15” characters) related to various commands.
Specifically, for example, as shown in FIG. 33B, the first character is data for identifying a variable packet and is represented by “F4H”.
The second to fourth characters are data for specifying the distribution notice of change notice (use of the assignment table of notice notices 23 to 25), and are represented by “01H” to “EFH”.
The fifth character is data for performing stop designation of the left symbol and the right symbol, and is represented by “01H” to “EFH”.
The sixth character is data for designating the stop of the middle symbol, and is represented by “01H” to “EFH”.
The seventh to fifteenth characters are preliminary data and are represented by “01H” to “EFH”.
The sixteenth character is data for determining whether or not to continue the special figure fluctuation display game, and data represented by other than “0DH” is continuously produced in the designated fluctuation packet (for example, reach production). The data represented by “0DH” is for ending the special figure variation display game.

Hereinafter, the decorative symbol stop packet will be described with reference to FIG.
FIG. 34A is a diagram schematically illustrating a data structure of a decorative symbol stop packet, and FIG. 34B is a diagram illustrating an example of a data structure of a decorative symbol stop packet.

As shown in FIG. 34A, the decorative symbol packet includes a first character that is a “PT” character and second to sixteenth characters related to various commands related to the designation of the decorative symbol displayed on the display device 41. ("PD1" to "PD15" characters).
Specifically, for example, as shown in FIG. 34B, the first character is data for identifying a decorative symbol stop packet, and is represented by “F5H”.
The second character is data for designating stoppage of decorative symbols, and is represented by “01H”.
The third to fifteenth characters are unused and are represented by “00H”.
The sixteenth character is data for specifying the model, and is represented by “01H” to “EFH”.

Hereinafter, the fanfare packet will be described with reference to FIG.
FIG. 35A is a diagram schematically illustrating the data structure of the fanfare packet, and FIG. 35B is a diagram illustrating an example of the data structure of the fanfare packet.

As shown in FIG. 35A, the fanfare packet includes a first character that is a “PT” character and second to sixteenth characters (“ PD1 "to" PD15 "characters).
Specifically, for example, as shown in FIG. 35B, the first character is data for identifying a fanfare packet and is represented by “F6H”.
The second character is data for specifying a fanfare according to the type of jackpot, and is represented by “01H” to “EFH”.
The third character is data for designating a jackpot symbol (determined symbol) and is represented by “01H” to “EFH”.
The fourth character is data for specifying the current effect mode, and is represented by “01H” to “EFH”.
The fifth character is data for designating the number of big hits, and is represented by “01H” to “EFH”.
The sixth character is data for specifying the movement of the movable accessory, and is represented by “01H” to “EFH”.
The seventh to fifteenth characters are unused and are represented by “00H”.
The sixteenth character is data for specifying the model, and is represented by “01H” to “EFH”.

Hereinafter, the round number packet will be described with reference to FIG.
FIG. 36A is a diagram schematically illustrating the data structure of the round number packet, and FIG. 36B is a diagram illustrating an example of the data structure of the round number packet.

The round number packet is transmitted from the 1st CPU 311 to the 2nd CPU 312 during the cycle game (during the big hit round). As shown in FIG. 36A, the first character that is a “PT” character and the cycle game are transmitted. Are composed of second to sixteenth characters ("PD1" to "PD15" characters) related to various commands related to designation of the number of rounds displayed on the display device 41.
Specifically, for example, as shown in FIG. 36B, the first character is data for identifying the round number packet, and is represented by “F7H”.
The second character is data for specifying the number of rounds, and is represented by “01H” to “EFH”.
The third character is data for designating the jackpot symbol (determined symbol) and is represented by “01H” to “EFH”.
The fourth character is data for specifying the current effect mode, and is represented by “01H” to “EFH”.
The fifth character is data for designating an effect during the big hit round, and is represented by “01H” to “EFH”.
The sixth character is data for introducing the contents of the gaming machine and is represented by “01H” to “EFH”.
The seventh to fifteenth characters are unused and are represented by “00H”.
The sixteenth character is data for specifying the model, and is represented by “01H” to “EFH”.

Hereinafter, the interval packet will be described with reference to FIG.
FIG. 37A is a diagram schematically illustrating the data structure of the interval packet, and FIG. 37B is a diagram illustrating an example of the data structure of the interval packet.

As shown in FIG. 37 (a), the interval packet is displayed on the display device 41 between the first character that is the “PT” character and the round of the cycle game (in a state where the big prize opening is closed). It consists of second to sixteenth characters (“PD1” to “PD15” characters) related to various commands related to the designation of the interval screen.
Specifically, for example, as shown in FIG. 37B, the first character is data for identifying an interval packet and is represented by “F8H”.
The second character is data for specifying a round promotion effect, and is represented by “01H” to “EFH”.
The third character is data for designating the jackpot symbol (determined symbol) and is represented by “01H” to “EFH”.
The fourth character is data for specifying the current effect mode, and is represented by “01H” to “EFH”.
The fifth character is data for specifying the interval effect, and is represented by “01H” to “EFH”.
The sixth to fifteenth characters are unused and are represented by “00H”.
The sixteenth character is data for specifying the model, and is represented by “01H” to “EFH”.

Hereinafter, the ending packet will be described with reference to FIG.
FIG. 38A is a diagram schematically illustrating the data structure of the ending packet, and FIG. 38B is a diagram illustrating an example of the data structure of the ending packet.

The ending packet relates to the display effect until the ending of the cycle game, that is, all the jackpot rounds are finished and the next change can be started, as shown in FIG. A first character that is a “PT” character and second to fifteenth characters (“PD1” to “PD15” characters) related to various commands related to designation of an ending screen displayed on the display device 41 at the end of the cycle game It is composed of
Specifically, for example, as shown in FIG. 38B, the first character is data for identifying the ending packet, and is represented by “F9H”.
The second character is data for designating the display of the ending, and is represented by “01H” to “EFH”.
The third character is data for designating the display of the jackpot symbol (determined symbol), and is represented by “01H” to “EFH”.
The fourth character is data for specifying the current effect mode, and is represented by “01H” to “EFH”.
The fifth character is data for specifying the next (after the big hit round) state (probability variation state or short time state) notice effect, and is represented by “01H” to “EFH”.
The sixth to fifteenth characters are unused and are represented by “00H”.
The sixteenth character is data for specifying the model, and is represented by “01H” to “EFH”.

The event type packet will be described below with reference to FIG.
FIG. 39A is a diagram schematically illustrating the data structure of an event packet, and FIG. 39B is a diagram illustrating an example of the data structure of an event packet.

As shown in FIG. 39 (a), the event-related packet includes a first character that is a “PT” character and second to sixteenth characters (“PD1”) related to various commands related to the designation of the effect of the event being played. To "PD15" character).
Specifically, for example, as shown in FIG. 39B, the first character is data for identifying an event packet and is represented by “FAH”.
The second character is data for designating the number of reservations that increases by winning and the number of reservations that decreases by fluctuation, and is represented by “01H” to “44H”.
The third to fourth characters are data for designating error display and are represented by “01H” to “EFH”.
The fifth character is data for specifying the number of times the effect button 25 has been pressed, and is represented by “01H” to “EFH”.
The sixth character is data for designating the number of winning game balls to be given to the start winning opening 36 or the normal variation winning device 37, and is represented by “01H” to “EFH”.
The seventh character is data for designating the number of reserves at the time of winning the game ball to the start winning opening 36 or the normal variable winning device 37, and is represented by “00H” to “04H”.
The eighth character is data for specifying a prefetch effect, and is represented by “01H” to “EFH”.
The ninth to sixteenth characters are unused and are represented by “00H”.

Next, a transmission diagram of each packet described above will be described with reference to FIG.
As shown in FIG. 40, in the power-on stage ST1 when the effect control device 300 is powered on, a power-on packet is transmitted from the 1st CPU 311 to the 2nd CPU 312.
When the power-on packet is transmitted, the machine type designation, the special figure 1 hold number and the special figure 2 hold number designation, and the probability information (game mode) are designated.
Here, if the power-on operation is for RAM initialization, the customer-waiting demo is displayed after the power-on operation based on the transmission of the customer-waiting packet and the customer-waiting demo packet in stage ST2. If the power-on operation is for a customer waiting demo, the customer waiting demonstration is displayed based on the transmission of the customer waiting packet and the customer waiting demo packet in stage ST2.

  Next, in the stage ST2 during the customer waiting demonstration, when a game ball win occurs in the start winning opening 36 or the normal variation winning device 37 and a hold information command and a decorative symbol command are transmitted, in the stage ST3, the 1st CPU 311 to the 2nd CPU 312 A variable packet (continuous 0 to 2 times) is transmitted.

  Next, when the decorative symbol stop timing is reached, a decorative symbol stop packet is transmitted from the 1st CPU 311 to the 2nd CPU 312 in stage ST4. If the stop symbol at this time is a symbol related to the jackpot, a decorative symbol command and a probability information command are transmitted, and a fanfare packet is transmitted from the 1st CPU 311 to the 2nd CPU 312 in stage ST5.

  Next, when the fanfare is finished and the big hit round game is started, the round number packet is transmitted from the first CPU 311 to the second CPU 312 in the round stage ST6 during the big hit round game. Then, when the big hit game round ends and the interval between the big hit game round and the next big hit game round is started, an interval packet is transmitted from the 1st CPU 311 to the 2nd CPU 312 in the interval stage ST7 in the interval. Until the final jackpot game round is completed, the round number packet and the interval packet are repeatedly transmitted in the round stage ST6 and the interval stage ST7.

Next, when the final jackpot game round is completed, an ending packet is transmitted from the 1st CPU 311 to the 2nd CPU 312 in the ending stage ST8 that displays the ending of the jackpot game round. Then, a probability information command is transmitted, and an operation suspension monitoring process is performed.
Here, if there is no information relating to the number of reserved special figure 1 or the number of special figure 2 held, the process proceeds to stage ST2. On the other hand, when there is information relating to the special figure 1 hold number or the special figure 2 hold number, the hold information command and the decorative symbol command are transmitted, and the process proceeds to the stage ST3.

Moreover, in stage ST4, when the stop symbol is a symbol related to a deviation, a probability information command is transmitted, and an operation suspension monitoring process is performed.
The probability information command is transmitted, for example, at the end of a specified number of times of fluctuation in a gaming machine having a variable time shortening function, or at the end of the specified number of times of change in a game machine having a so-called turn-off probability changing function or a falling lottery function Like that.

  In addition, when the power is turned on in stage ST1 is not during the customer waiting demonstration, a power failure recovery command is transmitted, and the process proceeds immediately after any of the stages ST2 to ST8 where the power failure occurs. For example, if a power failure occurs while the decorative symbol is changing (during symbol variation; ST3) in the special symbol variation display game, and the power is turned on to recover from the power failure, the game proceeds immediately after stage ST3.

  Further, when the power is turned on in stage ST1, the process proceeds to the start opening prize monitoring stage ST9, and each error state of the start opening (start winning opening 36, normal variation winning apparatus 37, etc.) is monitored and a game is sent to the start opening. When there is a winning of a ball, a holding information command and a start opening winning effect command are transmitted, and when the starting opening winning effect is finished, a process of monitoring each error state of the starting opening is repeated.

  When the power is turned on in stage ST1, the process proceeds to each error monitoring stage ST10 for monitoring each error state other than the start port, and each error state is monitored, and when an error occurs, an error notification command is transmitted. When the error is canceled, an error notification end command is transmitted.

  Next, an example of an effect control command in which random value information is stored in an empty area of fixed-length data will be described with reference to FIG. An example of the effect control command is a variable packet (continuous second time).

As shown in FIG. 41A, when storing random value information based on the determination of the effect control command, the seventh character, which is a spare area, is used as a debugging area, and the random value information is stored in the area (FIG. 41). (See (b)).
In addition, the eighth and ninth characters, which are spare areas, can also store other data for debugging in the area as a debugging area (see FIG. 41B).

Next, the transmission timing of the variable packet will be described with reference to FIGS.
FIG. 42A is a diagram showing the transmission timing of the variable packet in a state where the debug device 350 is not connected to the debug device connection circuit 315 via the test connection unit (test connector) 317. FIG. 9A is a diagram showing a state in which no event-related packet (see FIG. 39) is transmitted based on pressing of the effect button 25 or the like while the variable packet is being transmitted.

  As shown in FIG. 42A, in the state where the debug device 350 is not connected to the debug device connection circuit 315 via the test connection unit (test connector) 317, the variable packets 0 to 12 are each 33.333 ms apart. It is supposed to be sent by. In addition, the timing at which the variable packets 0 to 2 are transmitted is set in an event-related packet insertion-impossible section, and the event-related packet is not transmitted even if the presentation button 25 is pressed in the section. Yes.

  FIG. 42B shows the transmission timing of the variable packet in a state where the debug device 350 is not connected to the debug device connection circuit 315 via the test connection unit (test connector) 317 as in FIG. FIG. FIG. 6B is a diagram showing a state in which an event-related packet (see FIG. 39) is transmitted based on pressing of the effect button 25 or the like during the transmission of the variable packet.

  As shown in FIG. 42 (b), in the state where the debug device 350 is not connected to the debug device connection circuit 315 via the connection for inspection (connector for inspection) 317, as in FIG. 0 to 12 are transmitted at intervals of 33.333 ms. In addition, the timing at which the variable packets 0 to 2 are transmitted is set in an event-related packet insertion-impossible section, and the event-related packet is not transmitted even if the presentation button 25 is pressed in the section. Yes. When the presentation button 25 is pressed, the event packet is transmitted in the event packet insertable section (see the arrow in FIG. 42B) where the event packet can be inserted. .

  FIG. 43A is a diagram showing the transmission timing of the variable packet in a state where the debug device 350 is connected to the debug device connection circuit 315 via the test connection unit (test connector) 317. FIG. 9A is a diagram showing a state in which no event-related packet (see FIG. 39) is transmitted based on pressing of the effect button 25 or the like while the variable packet is being transmitted.

  As shown in FIG. 43A, in the state where the debug device 350 is connected to the debug device connection circuit 315 via the test connection portion (test connector) 317, the variable packets 0 to 12 are 66.666 (33.333), respectively. X2) It is transmitted at ms intervals. In addition, the timing at which the variable packets 0 to 2 are transmitted is set in an event-related packet insertion-impossible section, and the event-related packet is not transmitted even if the presentation button 25 is pressed in the section. Yes.

  43 (b), similarly to FIG. 43 (a), shows the transmission timing of the variable packet in the state where the debug device 350 is connected to the debug device connection circuit 315 via the test connection unit (test connector) 317. FIG. FIG. 6B is a diagram showing a state in which an event-related packet (see FIG. 39) is transmitted based on pressing of the effect button 25 or the like during the transmission of the variable packet.

  As shown in FIG. 43B, in the state where the debug device 350 is mounted on the debug device connection circuit 315 via the test connection unit (test connector) 317, the variable packet is similar to FIG. 0 to 12 are transmitted at intervals of 66.666 (33.333 × 2) ms. In addition, the timing at which the variable packets 0 to 2 are transmitted is set in an event-related packet insertion-impossible section, and the event-related packet is not transmitted even if the presentation button 25 is pressed in the section. Yes. When the presentation button 25 is pressed or the like, the event packet is transmitted in the event packet insertable section (see the arrow in FIG. 43B) where the event packet can be inserted. .

Next, a timing chart when transmitting the effect control command will be described with reference to FIG.
FIG. 44A is a timing chart of transmission of the effect control command in a state where the debug device 350 is not connected to the debug device connection circuit 315 via the test connection portion (test connector) 317 (normal time). .
As shown in FIG. 44A, in the state where the debug device 350 is not mounted on the debug device connection circuit 315 via the test connection portion (test connector) 317, the effect control command (for example, Fluctuating packets) are sent at 33.333ms intervals.

FIG. 44B is a timing chart of transmission of the effect control command in a state where the debug device 350 is connected to the debug device connection circuit 315 via the test connection unit (test connector) 317.
As shown in FIG. 44B, in the state where the debug device 350 is mounted on the debug device connection circuit 315 via the test connection portion (test connector) 317, the effect control command (for example, (Variable packet) is transmitted at intervals of 66.666 (33.333 × 2) ms.
As shown in FIG. 44C, when the debug device 350 is mounted on the debug device connection circuit 315 via the test connection unit (test connector) 317, the debug request command is sent from the 1st CPU 311 to the 2nd CPU 312. The effect control command is transmitted at a timing (t1 to t2, t3 to t4, t5 to t6, t7 to t8, etc.) not transmitted.

[Communication permission processing]
Next, a communication permission process in the case where the transmission time of the effect control command is changed according to whether or not the debug device 350 is connected will be described. As shown in FIG. 45, in the communication permission process, it is first determined whether or not the debug device 350 is being mounted (connected) (step B91).

  Here, when it is determined that the debug device 350 is being mounted (step B91; Yes), processing for permitting communication between the first CPU 311 and the second CPU 312 (step B92) is performed. Next, processing for permitting communication between the 1st CPU 311 and the debugging device 350 (step B93) is performed. Then, after performing processing for permitting communication between the 2nd CPU 312 and the debugging device 350 (step B94), the transfer time of the effect control command is changed to be used for mounting the debugging device 350 (slower than usual) (step) B98), the communication permission process is terminated.

  On the other hand, if it is determined that the debug device 350 is not being installed (step B91; No), a process for permitting communication between the first CPU 311 and the second CPU 312 (step B95) is performed, but between the first CPU 311 and the debug device 350 is performed. Processing for disabling communication (step B96) is performed, and processing for disabling communication between the 2nd CPU 312 and the debugging device 350 (step B97) is performed, and then the transfer time of the effect control command is set. It changes for normal time (step B99), and complete | finishes a communication permission process.

Next, the reach effect that can occur in the special figure variation display game in the gaming machine 10 of the present embodiment will be described with reference to FIG.
FIG. 46A is a diagram for explaining the types of reach effects that can occur in the gaming machine 10 of the present embodiment.
Here, the reach development target rate is a distribution rate when a reach effect occurs. For example, when the reach effect occurs, the normal reach is set to appear with a probability of 50/100.
The appearance reliability indicates the probability that a game result will be a big hit when each reach effect occurs. For example, when the character A reach occurs, the game result is set to be a big hit with a probability of 10%.
The upper reach promotion rate indicates the probability of promotion to another reach production after one reach production has occurred. For example, after the occurrence of the character B reach, the character B development reach or story reach is promoted with a probability of 20% during the production of the reach.

FIG. 46B is a diagram illustrating the upper reach promotion route.
As shown in FIG. 46B, for example, from normal reach, the character A reach, the character A development reach, the character B reach, the character B development reach, the character C reach, the character C development reach, or the story reach is selected. Promoted. In this case, the promotion rate from normal reach is set to 25% (see FIG. 46A).

Next, an example of a table indicating the actual number of appearances of each reach effect totalized by the debugging device 350 will be described with reference to FIG.
As shown in FIG. 47, the debug device 350 can count the number of appearances of each reach effect, the number of detachments after each reach effect, the number of jackpots, the reliability at the time of appearance, the upper reach promotion rate, and the like. It has become.
Thereby, it is possible to verify whether the appearance reliability and the upper reach promotion rate tabulated by the debugging device 350 are higher or lower than the preset appearance reliability and the upper reach promotion rate. It becomes like this.
Here, the upper reach promotion rate from the character C development reach of the aggregation results shown in FIG. 47 is the number of appearances of story reach (2 times), the number of appearances of character C development reach (6 times), and the number of appearances of story reach. It is derived by a value obtained by dividing (2 times) by a value obtained by adding (2 times) (8 times) (25%). It is assumed that the number of appearances of the story reach (2 times) is promoted from the character C development reach.

Next, a display mode of debug information related to each reach effect displayed on the display device 41 will be described with reference to FIG.
As shown in FIG. 48, when each reach effect is derived in a state where the debug device 350 is connected to the debug device connection circuit 315 via the test connection unit (test connector) 317, the upper right of the display device 41 is displayed. In the section, the type of reach effect derived, the reliability at the time of appearance after the start of counting by the debug device 350, and the upper reach promotion rate are displayed.

Specifically, as shown in FIG. 48 (a), when normal reach is derived, the type of reach effect (normal reach) derived in the upper right part of the display device 41 and counting by the debug device 350 are started. Appearance reliability (0.00%) and top reach promotion rate (43.0%) are displayed.
The circles shown in the lower part of FIG. 48 (a) indicate the number of special figure reservations. Specifically, the special figure 1 reservation number is 4 and the special figure 2 reservation number is 2. It is shown that. Further, among the circles indicating the special figure 1 suspension, the black circles indicate that the pre-reading effect is executed.

  According to the gaming machine 10 of the embodiment described above, a game including a display device 41 capable of executing a decorative special figure variable display game in which a plurality of symbols are variably displayed, and a game control board that controls the game in an integrated manner. In the gaming machine 10 including the control device 100 and the effect control device 300 including the effect control board 310 that controls the effect related to the decoration special figure variation display game executed on the display device 41. The control board 310 is a double-sided board having wiring patterns on both front and back sides, and a first control means (1st CPU 311) equipped with a first arithmetic processing unit that performs presentation control based on a control command from the game control device 100; , A second arithmetic processing unit that performs display control in the display device 41 based on an effect control command from the first control means (1stCPU 311). Information relating to the effect control command transmitted between the second control means (2ndCPU 312), the first control means (1stCPU311), and the second control means (2ndCPU312). Inspection device connection circuit configuration means (debug device connection circuit 315) for transmitting and receiving to and from the effect display inspection device (debug device 350) used for the inspection of the first control means (1stCPU 311) and the second control means (2ndCPU 312) An attachment area A that can be attached, and the attachment area A is configured to be provided on an invisible surface of the effect control board 310 when the effect control board 310 is attached to the gaming machine 10. Has been.

  Thereby, in the state where the production control board 310 is attached to the gaming machine 10, the attachment area A to which the inspection device connection circuit configuration means (debug device connection circuit 315) can be attached is an invisible surface of the production control board 310. Even if the inspection device connection circuit configuration means (debug device connection circuit 315) is removed at the time of mass production and sales, the removed portion is in a position where it is difficult to see, so it was originally installed. It is possible to make it difficult to cause a misunderstanding that an unauthorized modification that removes the component (debugging device connection circuit 315) has been performed.

  In addition, according to the gaming machine 10 of the above-described embodiment (Modification 1), the production control board 310 is capable of detaching an end portion of a cable that is communicably connected to the production display inspection device (debug device 350). Connection portion 317, and the inspection connection portion 317 is configured to be mounted on an invisible surface of the effect control board 310 when the effect control board 310 is attached to the gaming machine 10. ing.

  Thereby, by providing the connection part 317 for inspection that can attach and detach the end of the cable that is communicably connected to the effect display inspection device (debug device 350), for example, when the gaming machine 10 is developed, the effect display inspection device (debug device) 350) can be easily connected. In addition, in the state where the production control board 310 is attached to the gaming machine 10, the inspection connection unit 317 is mounted on an invisible surface of the production control board 310, so that the inspection connection unit 317 is removed at the time of mass production sales. Even in such a case, since the removed part is in a position where it is difficult to see, it is difficult to make a misunderstanding that an unauthorized modification that removes the originally mounted component (inspection connection portion 317) has been performed. be able to.

  In addition, according to the gaming machine 10 of the above-described embodiment (Modification 2), the connection portion for inspection 317 is coupled to the end portion of the cable that is communicably connected to the effect display inspection device (debug device 350). Are arranged so as to be parallel to the effect control board 310.

  As a result, the inspection connecting portion 317 is arranged so that the coupling direction with the end portion of the cable that is communicably connected to the effect display inspection device (debug device 350) is parallel to the effect control board 310. Even when the inspection connection unit 317 is mounted on an invisible surface of the production control board 310, the production display inspection device (debug device 350) can be easily connected from the side of the production control board 310. Will be able to.

  In addition, according to the gaming machine 10 of the above-described embodiment, the production control board 310 has the inspection connection portion 317 that can be attached to and detached from the end of the cable that is communicably connected to the production display inspection device (debug device 350). The inspection connection portion 317 is configured to be mounted on a visually recognizable surface of the presentation control board 310 in a state where the presentation control board 310 is attached to the gaming machine 10.

  Thereby, in the state where the production control board 310 is attached to the gaming machine 10, the inspection connection unit 317 is mounted on a visible surface of the production control board 310. A device (debugging device 350) can be easily connected.

  Moreover, according to the gaming machine 10 of the above-described embodiment (Modification 3), the effect control board 310 is configured such that a cut 310a for separating the attachment area A is formed.

  As a result, the mounting area A to which the inspection device connection circuit configuration means (debugging device connection circuit 315) can be attached at the time of mass production sales can be separated, so that unauthorized modification that removes the originally mounted components has been performed. It can make it difficult to make a mistake.

  Further, according to the gaming machine 10 of the above embodiment, the production control command is configured to include inspection data used for the inspection by the production display inspection device (debug device 350). The control means (1stCPU 311) includes connection determination means (1stCPU311) for determining whether or not the effect display inspection device (debug device 350) is connected to the inspection connection unit 317, and the connection determination means (1stCPU311). When it is determined that the effect display inspection device (debug device 350) is not connected to the inspection connection unit 317, between the first control unit (1stCPU 311) and the second control unit (2ndCPU 312). The production control command to be transmitted is configured not to include the inspection data.

  Thereby, when the production display inspection device (debug device 350) is not connected, it is possible to prevent the processing using the inspection data that is not required from being performed between the arithmetic processing devices. Thus, the processing load on each arithmetic processing unit can be reduced.

  Further, according to the gaming machine 10 of the above-described embodiment, the connection determination unit (1stCPU 311) outputs a connection signal that is output when the effect display inspection device (debug device 350) is connected to the inspection connection unit 317. Is input to the first control means (1stCPU 311) via the inspection connection unit 317, it is determined that the effect display inspection device (debug device 350) is connected to the inspection connection unit 317. It is configured as follows.

  Thereby, when the production display inspection device (debug device 350) is connected to the inspection connection unit 317, a connection signal indicating the connection is sent via the inspection connection unit 317 to the first control means ( 1st CPU 311), it is possible to appropriately determine whether or not the presentation display inspection device (debug device 350) is connected.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  In addition, the gaming machine of the present invention is not limited to the pachinko gaming machine as shown in the above embodiment, for example, other pachinko gaming machines, arrange ball gaming machines, sparrow ball gaming machines, etc. Applicable to all used gaming machines.

DESCRIPTION OF SYMBOLS 10 Game machine 41 Display apparatus 100 Game control apparatus 300 Effect control apparatus 310 Effect control board 311 1stCPU (1st control means)
312 2ndCPU (second control means)
315 Debug device connection circuit (inspection device connection circuit configuration means)
317 Connection unit for inspection 350 Debug device (production display inspection device)
A Mounting area

Claims (7)

A display device capable of executing a display game in which a plurality of symbols are variably displayed;
A game control device having a game control board for overall control of the game;
In a gaming machine including an effect control device including an effect control board that controls an effect on the display game executed in the display device,
The production control board is:
A double-sided board having wiring patterns on both front and back sides,
A first control means equipped with a first arithmetic processing unit for effect control based on a control command from the game control device;
Second control means equipped with a second arithmetic processing unit that performs display control in the display device based on an effect control command from the first control means;
An effect display inspection apparatus that uses information related to the effect control command transmitted between the first control means and the second control means for the inspection of the first control means and the second control means outside the gaming machine. An attachment area to which the inspection device connection circuit configuration means for transmitting and receiving can be attached; and
With
The gaming machine is characterized in that the attachment area is provided on a surface of the production control board that is not visible in a state where the production control board is attached to the gaming machine. The production control board includes an inspection connection unit that can be attached to and detached from an end of a cable that is communicably connected to the production display inspection device.
The inspection connecting portion is
The gaming machine according to claim 1, wherein the stage control board is mounted on an invisible surface of the stage control board in a state where the stage control board is attached to the gaming machine.   3. The inspection connecting portion is disposed so that a coupling direction with an end portion of a cable that is communicably connected to the effect display inspection device is parallel to the effect control board. Game machines. The production control board includes an inspection connection unit that can be attached to and detached from an end of a cable that is communicably connected to the production display inspection device.
The gaming machine according to claim 1, wherein the inspection connection unit is mounted on a visually recognizable surface of the presentation control board in a state where the presentation control board is attached to the gaming machine. The production control board is:
The gaming machine according to any one of claims 1 to 4, wherein a notch for separating the attachment region is formed. The production control command is configured to include inspection data used for the inspection by the production display inspection device,
The first control means includes
A connection determination means for determining whether or not the effect display inspection device is connected to the inspection connection unit;
When the connection determination means determines that the effect display inspection device is not connected to the inspection connection unit, the effect control command transmitted between the first control means and the second control means 6. The gaming machine according to claim 2, wherein the inspection data is not included.   When the connection signal output when the presentation display inspection device is connected to the inspection connection unit is input to the first control unit via the inspection connection unit, The gaming machine according to claim 6, wherein it is determined that the production display inspection device is connected to the inspection connection unit.