JP4023659B2 - Game machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a gaming machine such as a pachinko machine or a slot machine in which a player can perform a predetermined game, and in particular, a main machine that mainly controls a gaming state.CPUAnd a sub that controls the production according to the gaming state controlled by the main control board.CPUAnd a gaming machine having:
[0002]
[Prior art]
Conventionally, in this type of gaming machine, the control of the gaming state and the control of the effect performed in relation to this gaming state have been performed on one control board. However, the storage capacity of the memory mounted on the control board has a certain limit, and it has been extremely difficult to diversify the game and diversify the effects.
[0003]
  For this reason, control the gaming stateEquipped with main CPUSeparate from main control boardEquipped with a sub CPUA sub-control board is provided, and the main control board outputs a control signal such as an effect control command to the sub-control board, and the sub-control board inputs this control signal, so that the main control board controls the gaming state. A large number of gaming machines that can control the corresponding production have been put into practical use.
[0005]
[Problems to be solved by the invention]
  The present invention has been made paying attention to such problems,The backup of the sub CPU can be reliably performed, and the consistency between the main CPU and the sub CPU can be achieved when the backup data of the main CPU is initialized.An object is to provide a gaming machine.
[0006]
[Means for Solving the Problems]
  In order to solve the above problems, the gaming machine of the present invention is:
  A gaming machine capable of performing a predetermined game,
  Control the gaming stateMain CPUWhen,
  A main memory used as a work memory of the main CPU;
  Control the productionSub CPUWhen,
  A sub memory used as a work memory of the sub CPU;
  A power-off determining means for determining the occurrence of power-off when a predetermined power-off condition is satisfied;
  Initialization operation means operated when initializing data stored in the main memory;
  With
  The main memory has a main backup area for storing main backup data for returning the gaming state,
  The sub memory includes a work area used as a work memory of the sub CPU, a first sub backup area in which sub backup data for restoring the presentation state is stored, and data of the first sub backup area And a second sub-backup area in which the data for correctness / incorrectness determination is stored separately.
  The main CPU is
  Control information transmission processing for transmitting to the sub CPU control information capable of specifying the control state of the main CPU at that time according to the gaming state controlled by the main CPU;
  A main backup process for storing the main backup data in the main backup area when the power-off determining unit determines the occurrence of a power-off,
  An initialization operation determination process for determining whether or not the initialization operation means is operated when power is turned on;
  When the initialization operation determining process determines that the initialization operation means has not been operated, the gaming state return is made to return to the gaming state before the power is turned off based on the main backup data stored in the main backup area. Processing,
  A main backup data initialization process for initializing main backup data stored in the main backup area when it is determined that the initialization operation means is operated by the initialization operation determination process;
  Specific control information transmission processing for transmitting specific control information to the sub CPU when initializing main backup data stored in the main backup area by the main backup data initialization processing;
  And
  The sub CPU is
  When the control information transmitted from the main CPU is received, an effect execution process for executing an effect according to the control state of the main CPU specified by the received control information;
  Only when the control information transmitted from the main CPU is received, the previous sub-backup data stored in the first sub-backup area is restored to the effect state when the control information is received. Sub-backup data update processing to update to the latest sub-backup data,
  Each time the control information transmitted from the main CPU is received and the sub-backup process is performed, correctness determination data is calculated using the data of the first sub-backup area, and the second sub-backup area Correct / wrong judgment data update processing for updating the previous true / wrong judgment data stored in the latest correct / wrong judgment data,
  An effect state return availability determination process for determining whether or not the data in the first sub-backup area is normal based on the correctness / incorrectness determination data stored in the second sub-backup area when the power is turned on;
  On the condition that it is determined to be normal by the performance state return availability determination process, the first support is performed. Production state return processing for returning to the production state before power-off based on the sub-backup data stored in the backup area,
  Specific control information reception determination processing for determining whether or not the specific control information is received from the main CPU at power-up;
  And
  If the sub CPU determines that the specific control information has been received from the main CPU in the specific control information reception determination process, is it possible to return to the effect state before the power is turned off based on the sub backup data? Regardless of whether or not, the effect state return process does not return to the effect state before power-off based on the sub-backup data stored in the first sub-backup area.
  It is characterized by that.
  According to this feature,Since the sub CPU is backed up every time control information transmitted from the main CPU is received, the sub CPU can be backed up reliably. Further, when the initialization operation means is operated when the power is turned on to initialize the backup data of the main CPU, specific control information is transmitted to the sub CPU so that the sub CPU also initializes the backup data. Therefore, consistency between the two can be achieved.
[0007]
  The gaming machine of the present invention is
  A drive voltage generating means mounted on the main control board and generating a drive voltage for driving the IC lower than the supply voltage from the supply voltage supplied to the main control board;
  The drive voltage generated by the drive voltage generation means is used as a voltage for driving the main CPU, and the drive voltage is also supplied to the sub-control board, and the drive voltage supplied from the main control board is , Used as a voltage for driving the sub CPU,
  The supply voltage isMain CPUUsed as a voltage to drive gaming peripherals controlled by
  It is preferable.
  This way,The drive voltage generated by the drive voltage generation means is used as a voltage for driving the main CPU, and the same drive voltage is also used as a voltage for driving the sub CPU. The voltage for driving the sub CPU does not become higher, and it is possible to prevent malfunction and breakage of the CPU mounted on each board. Also,Since it is not necessary to separately introduce a voltage for driving the peripheral device for gaming, the configuration of the gaming machine can be simplified.
[0008]
  The gaming machine of the present invention is
  A drive voltage generating means mounted on the main control board and generating a drive voltage for driving the IC lower than the supply voltage from the supply voltage supplied to the main control board;
  The drive voltage generated by the drive voltage generation means includes a voltage for driving the main CPU andSaidMain CPUUsed as a voltage to drive gaming peripherals controlled byThe drive voltage is also supplied to the sub control board, and the drive voltage supplied from the main control board is used as a voltage for driving the sub CPU.
  It is preferable.
  This way,The drive voltage generated by the drive voltage generation means is used as a voltage for driving the main CPU, and the same drive voltage is also used as a voltage for driving the sub CPU. The voltage for driving the sub CPU does not become higher, and it is possible to prevent malfunction and breakage of the CPU mounted on each board. Also,It is not necessary to separately introduce a voltage for driving a gaming peripheral device, and it is not necessary to separately provide a generating means for generating a voltage for driving a gaming peripheral device, thereby simplifying the configuration of the gaming machine can do.
[0009]
  The gaming machine of the present invention is
  A drive voltage generating means mounted on the main control board and generating a drive voltage for driving the IC lower than the supply voltage from the supply voltage supplied to the main control board;
  The drive voltage generated by the drive voltage generation means is used as a voltage for driving the main CPU, and the drive voltage is also supplied to the sub-control board, and the drive voltage supplied from the main control board is , Used as a voltage for driving the sub CPU,
  The drive voltage supplied from the main control board to the sub control board is:Sub CPUUsed as a voltage to drive the production peripherals controlled by
  It is preferable.
  This way,The drive voltage generated by the drive voltage generation means is used as a voltage for driving the main CPU, and the same drive voltage is also used as a voltage for driving the sub CPU. The voltage for driving the sub CPU does not become higher, and it is possible to prevent malfunction and breakage of the CPU mounted on each board. Also,Since it is not necessary to separately introduce a voltage for driving the performance peripheral device, the configuration of the gaming machine can be simplified.
[0015]
  The gaming machine of the present inventionMain CPUIn the main backup process performed byMain backup dataTheIn the main backup areaIt is preferable to perform a process of storing a plurality.
  In this way, it is saved in the main backup processMain backup dataCan be stored more accurately.
  In the gaming machine of the present invention, the first sub-backup area stores a plurality of the same sub-backup data, and in the sub-backup data update process performed by the sub CPU, a plurality of the same sub-backup data are stored in the first sub-backup area. It is preferable to update all stored previous sub-backup data to the latest sub-backup data.
  In this way, the sub-backup data updated by the sub-backup data update process can be stored more accurately.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0017]
Example 1
Embodiment 1 of the present invention will be described with reference to the drawings. FIG. 1 is an overall front view of a slot machine as an example of a gaming machine to which the present invention is applied, and FIGS. Each structural drawing is shown. The slot machine 1 includes a housing 2a having an open front surface and a front door 2b pivotally supported on a side end of the housing 2a, and a locking device provided on the back surface of the front door 2b. By rotating a predetermined key inserted in the key hole 3a of No. 3 (see FIG. 3) in the clockwise direction, the lock is released and the front door 2b can be opened.
[0018]
An upper decorative frame 4 is provided at the upper front part of the front door 2b, and a game effect lamp part 41, a winning symbol explanation panel 5, and a liquid crystal display part 15 are provided on the substantially inverted trapezoidal upper part. A game panel 6 and various display units are provided at the center of the elliptical shape. The lower part of the upper decorative frame 4 is formed so as to protrude forward from the game panel 6, and a medal insertion part 34 capable of inserting a medal as a game medium and various operation buttons 35, 36 a, 36 b, 37, 40L, 40C, 40R, a start lever 38, and the like are provided. In addition, game effect lamp portions 42 to 45 are respectively provided around the center portion of the upper decorative frame 4 and on the left and right sides of the lower portion.
[0019]
A lower decorative frame 7 is provided below the upper decorative frame 4, and a title panel 8 on which the model name of the slot machine 1 is drawn is provided in this frame. Further, below the lower decorative frame 7, a medal payout hole 9 for paying out a medal as an example of a game medium is provided, and a medal tray 11 having an ashtray 10 provided at an end thereof is provided.
[0020]
On the upper left and right sides of the upper decorative frame 4, sound emitting units 12 a and 12 b that emit sounds output from high-frequency speakers 136 a and 136 b (see FIGS. 3 and 4) provided therein are provided. At the side of the medal payout hole 9, there is provided a sound emitting portion 13 for emitting a sound output from a low-frequency speaker 137 (see FIGS. 3 and 4) provided inside. The sound emitting units 12a, 12b, and 13 emit sound effects such as voice and melody for enhancing the production effect output from the speakers 136a, 136b, and 137.
[0021]
The gaming panel 6 includes a see-through window 14 through which the reels 51L, 51C, 51R provided in the housing 2a of the slot machine 1 can be seen through, and small role notification display portions 20a, 20b located above the see-through window 14. 20c, a one-bet display unit 21, a two-bet display unit 22, 23, a three-bet display unit 24, 25 located on the left side of the fluoroscopic window 14, and a game over display unit 26 positioned on the right side of the fluoroscopic window 14. A replay display unit 27, a weight display unit 28, a start display unit 29, an insertion instruction display unit 30, a credit display unit 31, a game number display unit 32, and a payout display unit 33 located below the fluoroscopic window 14. Each is provided.
[0022]
The one-bet display unit 21, the two-bet display units 22, 23, and the three-bet display units 24 and 25 display the number of bets that the player has bet on the game. The two-bet lamps 113 and 114 are incorporated in the two-bet display units 22 and 23, and the three-bet lamps 115 and 116 are incorporated in the three-bet display units 24 and 25, respectively. (See FIG. 4). Each of the betting display sections 21 to 25 corresponds to one of five pay lines L1, L2, L2 ′, L3, and L3 ′ drawn on the transparent window 14 as shown in FIG. The pay line L1, L2, L2 ′, L3, and L3 ′ that are validated in this way are also used as an effective line display unit that informs in a distinguishable manner.
[0023]
One small winning symbol is drawn on each of the small role notification display portions 20a to 20c provided in the upper portion of the see-through window 14 in the game panel 6. Specifically, a “white 7” symbol is drawn on the small role notification display portion 20a, a “black 7” symbol is drawn on the small role notification display portion 20b, and a “BAR” symbol is drawn on the small role notification display portion 20c. ing. These small role notification display units 20a to 20c are allowed to generate a predetermined small role winning by the control unit of the slot machine 1, that is, that the predetermined small role winning is internally won. Display unit for notifying by turning on the small role notification lamps 140a to 140c (see FIG. 4) built in the small role notification display units 20a to 20c on which the winning symbol corresponding to the small role winning is drawn. And functions only when a predetermined condition is satisfied.
[0024]
The game over display unit 26 is incorporated in the game when the big bonus, which will be described later, is stopped, or when an error occurs and the game cannot be advanced. The game overlamp 117 (see FIG. 4) lights up. In the replay display unit 27, when a replay winning occurs, a replay lamp 119 (see FIG. 4) incorporated therein is turned on. In the start display unit 29, when it becomes possible to perform a start operation by setting the number of bets, a start lamp 118 (see FIG. 4) incorporated therein is turned on, and an effective start operation is performed. Turns off when detected. When the insertion instruction display unit 30 is in a state where a medal can be received, the insertion instruction lamp 111 (see FIG. 4) incorporated therein blinks, the maximum bet number is set, and the credit number is set. When a predetermined upper limit is reached, the game is turned off when the game is started.
[0025]
When a start operation is detected during the wait time, the weight display unit 28 turns on a wait lamp 139 (see FIG. 4) built therein, and turns off after the wait time has elapsed. The wait time is a game progress restriction period set to restrict the game from progressing too quickly.If a start operation is detected during this wait time, the reel is moved after the wait time has elapsed. It is set to start. Therefore, when the game is progressed with a sufficient time interval, the progress of the game is not restricted when the start lever 38 is operated. Is temporarily restricted, and the reels are in a waiting state until the wait time elapses.
[0026]
In this slot machine 1, a game progress regulation period of, for example, 4.1 seconds is set on the basis of the time when reel rotation starts in the previous game, and the reel rotation starts in the previous game. If the current start operation is detected before 4.1 seconds have elapsed from the time point, the reel starts to rotate after the game progress regulation period has elapsed.
[0027]
The credit display unit 31 displays the number of credits. The credit is the number of medals stored in the storage unit inside the slot machine 1 as a valuable value owned by the player, and is added and updated when a medal is inserted into the medal slot and a payout with a payout occurs, Subtraction is updated by setting a bet number or paying out medals based on a settlement operation. In this slot machine 1, the upper limit of the value that can be stored as credit is set to 50 medals at the maximum, and when the upper limit (50 medals) is reached, the insertion instruction display unit 30 is turned off. When a credit addition / renewal request exceeding the upper limit is generated, medals exceeding the upper limit are paid out from the medal payout hole 9.
[0028]
The number-of-games display section 32 displays the regular bonus (RB) winning status during the big bonus (BB), the number of winnings during the regular bonus, and the like. The word “END” is displayed to notify the player that the player is in a stopped state. Furthermore, the game number display unit 32 also functions as an error indicator that is a notification means for displaying various abnormalities occurring in the slot machine 1. For example, the abnormality type detected by the control unit is derived from a combination of winning symbols despite the fact that “medal shortage to be paid out”, “medal clogged”, and “payout conditions are not satisfied” And “the game state cannot be restored to the state before the power failure”. When these abnormalities are detected by the control unit, an error code that can specify the abnormality type is displayed in the form of “E-1”, “E-2”, “E-3”, or the like.
[0029]
The payout display unit 33 displays the number of medals awarded to the player based on the winnings generated during one game every time there is a winning.
[0030]
On the right side of the lower upper surface of the upper decorative frame 4 formed so as to protrude from the game panel 6 to the front side, a medal insertion portion 34 having a medal insertion slot is provided, and on the left side is a checkout button 37, A single BET button 36a and a MAXBET button 36b are provided.
[0031]
The one-BET button 36a is a button that is pressed when betting one credit, and the MAXBET button 36b stores the maximum number of bets allowed in one game (three medals in this embodiment) as credits. This button is pressed when betting on a game within a certain range. A BET button lamp 121a is built in the single BET button 36a, and a BET button lamp 121b is built in the MAX BET button 36b (see FIG. 4). These BET button lamps 121a and 121b are Lights when the corresponding BET button is pressed and the bet number can be set, and turns off when the bet number cannot be set.
[0032]
The settlement button 37 is a button that is pressed when the settlement operation of the credit stored in the storage unit is performed, and the credit number displayed on the credit display unit 31 is reduced to 0 in accordance with the pressing operation of the settlement button 37. The medals corresponding to the credits are paid out from the medal payout hole 9 while being subtracted and updated.
[0033]
A start lever 38, stop buttons 40L, 40C, 40R, and a medal clogging release button 35 are provided on the front side surface of the lower part of the upper decorative frame 4, respectively. The start lever 38 is a lever that is operated when starting the game, and the rotation of each of the reels 51L, 51C, 51R is started by operating the start lever 38 after the setting of the betting amount is completed.
[0034]
The stop buttons 40L, 40C, and 40R are buttons that are operated when the rotation of the reels 51L, 51C, and 51R is stopped after the game is started, and an operation valid lamp 122L is provided inside the stop button 40L, and the stop button 40C. The operation effective lamp 122C is built in the interior of the, and the operation effective lamp 122R is built in the stop button 40R (see FIG. 4). These operation valid lamps 122L, 122C, 122R are turned on when the operation of the corresponding stop buttons 40L, 40C, 40R is valid, and are turned off when the operation is invalid. Further, the stop button unit 39 in which the stop buttons 40L, 40C, 40R are arranged has a bonus notification lamp 120 (see FIG. 5) incorporated therein when a big bonus winning or a regular bonus winning internal winning flag is set. 4) lights up.
[0035]
The medal clogging release button 35 is a button that is operated when a medal inserted into the medal insertion unit 34 is clogged inside to cancel the clogging.
[0036]
As shown in FIG. 2, a plurality of types of symbols (in this embodiment, “black 7”, “white 7”, “BAR”, “watermelon”, “bell”, It has reels 51L, 51C, and 51R (game reels used for executing a game) in which a translucent belt-shaped reel sheet printed with “cherry” and “plum” is wound around the outer periphery. A variable display device 50 including a reel unit 52 is provided. Each of the reels 51L, 51C, 51R is configured to be rotated (driven) and stopped independently in the vertical direction by reel motors 54L, 54C, 54R comprising stepping motors provided corresponding to each of the reels 51L, 51C, 51R. As the reels 51L, 51C, 51R rotate, the various symbols are displayed on the display window 14 while being continuously changed.
[0037]
Between the reels 51L and 51C arranged side by side in the horizontal direction, and between the reels 51C and 51R, arc-shaped inter-reel concealing members 53 are provided to block the reels. The inside is hidden from view. In the see-through window 14, three regions divided by the field of view being divided by the inter-reel concealing member 53, that is, three region parts that can be visually recognized by each reel, correspond to the respective reels. It is called a variable display section and a right variable display section (region).
[0038]
From each variable display section of the fluoroscopic window 14, three consecutive symbols out of a plurality of symbols drawn on each reel are displayed at the upper, middle, and lower positions, and the upper portion of the upper stage is soon in the upper stage. A part of the symbol appearing at the position is displayed in the lower part of the lower stage, and a part of the symbol that will soon be hidden under the variable display portion is displayed.
[0039]
Each reel 51L, 51C, 51R is provided with a reel sensor 56 for detecting a reference position of each reel. The reel sensor 56 can derive a stop position of a predetermined symbol, and each reel A plurality of reel lamps 55 capable of individually irradiating specific display areas (upper, middle, and lower display areas) in 51L, 51C, and 51R from the back surface are provided in the upper, middle, and lower stages, respectively. 55 is configured to function as a backlight that is lit from the rear so that each symbol displayed on the fluoroscopic window 14 is conspicuous in a normal state.
[0040]
On the upper front surface of the back plate 85 of the housing 2a, as will be described later, a storage case 500 containing a control unit 210 for mainly controlling the progress of the game and a game control board 200 provided with various circuits is not removable. It is fixed to. In addition, a reel relay board 203 to be described later is attached to the upper part of the inner surface of the right side plate as viewed from the front in the reel unit 52 constituting the variable display device 50, and a reel lamp relay board 204 to be described later is attached to the lower part thereof. Yes.
[0041]
An external output board 205 (to be described later) is attached to a side position of the reel unit 52 on the inner surface of the right side plate 87 when the housing 2a is viewed from the front side.
[0042]
Below the reel unit 52, a hopper tank 57 for storing medals inserted from the medal insertion section 34 can be pulled forward through a guide rail 58 fixed on the upper surface of the lower plate constituting the housing 2a. It is arranged. An overflow tank 59 for storing medals overflowing from the hopper tank 57 is provided on the right side of the hopper tank 57. A full tank sensor 60 capable of detecting medals is provided in the overflow tank 59 so that it can be notified that the amount of stored medals has exceeded a predetermined amount.
[0043]
A hopper motor 62 is provided at a lower portion of the hopper tank 57, and medals in the hopper tank 57 are discharged from the medal discharge port 63 by rotating the hopper motor 62. The discharged medals are detected by a payout medal sensor 61 provided in the vicinity of the medal discharge port 63 and then paid out to the medal tray 11 from the medal payout hole 9 through a return medal flow path 73 described later. The hopper motor 62 is controlled to stop when a predetermined number of payout medals are detected by the payout medal sensor 61.
[0044]
On the side of the hopper tank 57, there is a main switch unit 65 for turning on / off the main power source, and a reset to a state where the game can be continued again when the big bonus ends or an error occurs during the game. A second reset button 66, a setting button 67 for changing the winning probability, an automatic settlement selection switch section 68 for turning on / off the automatic settlement function, and a stop selection switch section 69 for turning on / off the automatic stop function. And a power key unit 64 provided with a setting key insertion portion 70 into which a specific key possessed by a manager of the game hall or the like can be inserted.
[0045]
In the present embodiment, the setting key switch 82 described later is detected to be turned on by an operation of turning on the power in a state where a specific key is inserted into the setting key insertion unit 70 and rotated 90 degrees clockwise, that is, in the on state. The game state is initialized, that is, the contents stored in the RAM 212 are initialized, and the operation of the setting button 67 is enabled, and the winning probability, that is, the payout rate can be changed by operating the setting button 67. It becomes. In other words, the operation of turning on the power while the setting key is on functions as the operation of clearing the main memory and the operation of setting the payout rate in the present invention.
[0046]
As shown in FIG. 3, an insertion medal selector 71 that guides medals inserted from the medal insertion portion 34 to the hopper tank 57 is fixedly provided at a substantially central portion on the rear surface of the front door 2 b. An illegal medal discharge unit 72 is provided on the upstream side of the inserted medal selector 71. An illegal medal having a size or thickness different from that of the appropriate medal is inserted into the upper portion of the return medal channel 73 provided below the inserted medal selector 71. It is discharged to the mouth and returned to the medal tray 11 through the medal payout hole 9.
[0047]
A flow path switching solenoid 107 is provided on the downstream side of the illegal medal discharge unit 72 to selectively switch the flowing medal flow path. Normally, the flow path switching solenoid 107 is excited, and the flowing medal flows down without switching the flow path, and is detected by the insertion medal sensor 106 provided on the downstream side, and then stored in the hopper tank 57. It has come to be. For example, when the number of credits reaches 50, when a medal is inserted from the medal insertion unit 34 or a medal is paid out to the player, the excitation of the flow path switching solenoid 107 is released and the flow path is switched. The medal is guided to the return medal channel 73 through the return channel.
[0048]
A storage case 550 in which an effect control board 201 provided with a control unit 230 for controlling a predetermined effect state related to a game and various circuits is provided at the upper rear surface of the front door 2b is not removable. It is fixed to.
[0049]
On the left and right sides of the storage case 550, high-frequency speakers 136a and 136b are fixed so as to face the sound emitting portions 12a and 12b, respectively. The speaker 137 is fixed so as to face the sound emitting unit 13. For example, when a medal is inserted into the medal insertion unit 34, the start lever 38 is operated, the stop buttons 40L, 40C, 40R are operated, etc. When various actions are performed, when a specific symbol combination is displayed on an activated active line and a predetermined winning condition is met, or when a big bonus or regular bonus is executed, etc. In various game states, a predetermined game sound effect or the like corresponding to the game state is output from each speaker 136a, 136b, 137. It has become way.
[0050]
Next, an operation for a player to play a game (game) and operating states of various devices accompanying the operation will be described.
[0051]
When starting the game, the player first sets a desired number of bets by betting a desired value of value using medals and credits when the insertion instruction lamp 111 is lit or flashing. To do. The number of bets can be set by inserting medals from the medal insertion unit 34 or by using credits. In order to use the credit, the MAXBET button 36b or the single BET button 36a may be pressed. When the MAXBET button 36b is pressed, the number of credits displayed on the credit display unit 31 is allowed in one game in this embodiment. Credits displayed on the credit display unit 31 are displayed by subtracting and displaying “3” which is the maximum number of bets to be placed, setting the number of bets for three medals, and pressing one BET button 36a. The number is subtracted by “1” and the bet number for one medal is set. When the number of credits displayed on the credit display unit 31 is less than 3, the settable bet number range is limited to the credit number range.
[0052]
When a player inserts one medal from the medal insertion unit 34 or presses the one-BET button 36a, the bet number is set to “1” and the winning line L1 in the horizontal row in the middle row is set. Becomes valid, and the single bet lamp 112 (see FIG. 4) indicating that the winning line L1 has become valid lights. Subsequently, when the second medal is inserted from the medal insertion unit 34 or when the single BET button 36a is pressed twice, the bet number is set to “2”, and the upper, middle, and lower rows are arranged in three horizontal rows. The winning lines L1, L2, and L2 ′ are activated, and the one betting lamp 112 and the two betting lamps 113 and 114 are turned on to indicate that these winning lines L1, L2, and L2 ′ are activated. Subsequently, when the third medal is inserted from the medal insertion unit 34, the one-BET button 36a is pressed three times, or the MAXBET button 36b is pressed, the bet number is set to “3”. The upper, middle, and lower rows of three winning lines L1, L2, and L2 ′ and the diagonally diagonal upper two winning lines L3 and L3 ′ are valid, and these winning lines L1, L2, L2 ′, L3, and L3 are valid. The one-bet lamp 112, the two-bet lamps 113 and 114, and the three-bet lamps 115 and 116 indicating that 'is valid are turned on. When the maximum bet number is set to “3”, the BET button lamps 121a and 121b are turned off because the bet number exceeding the maximum bet cannot be set.
[0053]
When the minimum bet number “1” is set as described above, the operation of the start lever 38 is effectively accepted, that is, the game can be started. A start lamp 118 is turned on to indicate that is effectively received.
[0054]
Note that the number and shape of the activated lines activated according to the number of bets set such as medals and credits can be arbitrarily changed, and are not limited to the embodiment. . In addition, the number of active lines activated according to the number of bets can be arbitrarily set and changed. For example, when one medal is inserted, all the five winning lines L1, L2, L2 ′, L3, and L3 ′ are changed. It may be activated.
[0055]
If the start lever 38 is pressed while the start lamp 118 is lit, the variable display device 50 is actuated to rotate the reels 51L, 51C, 51R, and a plurality of types of symbols are continuously displayed in the see-through window 14. Is displayed to change. As described above, when a predetermined time elapses after the reels 51L, 51C, 51R start to rotate, the operation of each stop button 40L, 40C, 40R becomes effective, and the operation of these stop buttons 40L, 40C, 40R becomes effective. The operation effective lamps 122L, 122C, and 122R indicating that they are turned on are turned on. If the player presses one of the stop buttons 40L, 40C, 40R while the operation valid lamp is lit, the corresponding operation valid lamps 122L, 122C, 122R are turned off and the corresponding reels 51L, 51C are turned off. , 51R is stopped, and symbols are displayed on the upper, middle and lower stages of the corresponding variable display section from the fluoroscopic window 14.
[0056]
When the player does not press the stop buttons 40L, 40C, 40R, the reels 51L, 51C, 51R are automatically stopped in order of priority when a predetermined time (for example, 30 seconds) elapses.
[0057]
When any two of the three reels stop rotating, the same kind of symbols are arranged on any of the winning lines L1, L2, L2 ′, L3, and L3 ′ activated according to the number of bets. If the display is stopped, reach is established.
[0058]
Furthermore, when all the reels 51L, 51C, 51R are stopped, a predetermined symbol combination on any of the pay lines L1, L2, L2 ′, L3, L3 ′ activated according to the number of bets Is displayed, it corresponds to the game effect lamps 130 to 134 (see FIG. 4) and the winning lines L1, L2, L2 ′, L3, and L3 ′ built in the various game effect lamp portions 41 to 45. The reel lamp 55 or the like to be turned on is turned on, and effects such as output of sound effects from the speakers 136a, 136b, and 137 are executed. Then, a predetermined number of medals corresponding to the winning contents are paid out as credits to the player, and the credit number displayed on the credit display unit 31 is added and updated. When the number of credits reaches the upper limit, medals are paid out directly from the medal payout holes. The payout number of these medals is displayed on the payout display section 33.
[0059]
In particular, when a combination of predetermined special symbols is displayed and a big win (special prize) is awarded, medals are paid out, which is different from the normal gaming state and advantageous to the player. That is, a special gaming state in which a large number of medals can be obtained occurs, and a big bonus (hereinafter referred to as BB) or a regular bonus (hereinafter referred to as RB) as described later is given to the player as a gaming value. It has become.
[0060]
The “game value” given to the player by winning in this way is not limited to the valuable value such as medals and credits, but is given to the player in the case of winning a big win as described above. All the benefits related to the game such as BB and RB to be played are included.
[0061]
In the slot machine 1 according to the present embodiment, for example, a symbol “BAR-BAR-BAR” is displayed on any of the pay lines L1, L2, L2 ′, L3, L3 ′ activated according to the number of bets. If it is aligned, it means that it has won the RB that is a big hit, and for example, 15 medals are paid out as a consideration for the fact that the symbols of “BAR-BAR-BAR” are aligned, and it is a gaming state advantageous to the player. An RB (regular bonus) state occurs, and a regular bonus game described below is given to the player as a game value. In this RB, a Jac game in which a predetermined number of medals are paid out as a result of a collection of plum symbols is generated with a high probability of receiving a Jac prize 12 times at a maximum. It is executed once, or the Jac prize is generated eight times before the Jac game reaches 12 times, or the game ends when one of the conditions is satisfied. Therefore, the player can get a chance to win up to 8 Jac prizes in 12 Jac games.
[0062]
On the other hand, if "Black 7-Black 7-Black 7" or "White 7-White 7-White 7" is aligned on the activated pay lines L1, L2, L2 ', L3, L3' For example, 15 medals were paid out as a reward for winning a certain BB (Big Bonus) and having a pattern of “Black 7-Black 7-Black 7” or “White 7-White 7-White 7”. At the same time, a BB (Big Bonus) state, which is a special gaming state advantageous to the player, occurs, and a small role game described below is given to the player as a gaming value. More specifically, in this BB, the winning combination of a small role (with watermelons, bells, and plums in the embodiment) with a high probability and a payout of a predetermined number of medals is a high probability. The generated small role game is provided up to 30 times, and if the JacIn prize is won with a collection of plum symbols before the small role game is executed 30 times, it is in a special game state. The above-mentioned RB state occurs and a regular bonus game is provided. This RB has a predetermined maximum number of times that can be generated in the BB, and can be generated up to three times in this embodiment. And this BB is the case where 30 small role games are executed and ended, or the case where 3 RBs are provided before the small role game is executed 30 times and the third RB ends. The process ends when at least one of the conditions is satisfied.
[0063]
Further, in the case of a normal gaming state (normal game) other than the special gaming state, when a predetermined prize is established on one active line where the same type of symbols are activated, the symbol A predetermined number of medals determined according to the type of the player are awarded to the player. In addition, the symbol of “cherry” drawn on each reel 51L, 51C, 51R is a mark called a single symbol, and when this single symbol is stopped and displayed on one valid line, two symbols are displayed. A medal is awarded to the player. If there are multiple activated lines that are activated according to the number of bets, as described above, if a combination of symbols from which medals are paid out is simultaneously established on multiple winning lines, In principle, medals corresponding to the total number of medals given by the combination of symbols on the line are given. However, since the upper limit of 15 medals given to a player in one game is determined, when the number exceeds 15, the 16th and subsequent medals become invalid.
[0064]
In this embodiment, black 7-black 7-black 7 (black 7 award), white 7-white 7-white 7 (white 7 award), BAR-BAR-BAR (BAR award), watermelon in the normal gaming state -Watermelon-Watermelon (Watermelon Award), Cherry (Cherry Award), Bell-Bell-Bell (Bell Award), Plum-Plum-Plum (Replay; Replay), etc. , Or the white 7 symbol and the BAR symbol only as a special symbol that is the target of the jackpot prize (BB, RB) as a special prize that is a big prize for the player, other watermelon, cherry, bell or Plum (replay) is a symbol that is a target of a small role winning as a normal winning, which is a small profit for a player.
[0065]
The combination of symbols that are the subject of each award and the number of payout medals (including the winning probability (outtake rate) etc.) corresponding to the combination of the symbols correspond to those in the normal game, BB, and RB. These settings are registered in a winning determination table stored in the ROM 213 of the control unit 210 described later.
[0066]
FIG. 4 is a block diagram for explaining a connection state between various boards and electrical components provided in the slot machine 1. FIG. 5 illustrates the configuration of the control unit 210 provided on the game control board 200 as the main control board and the configuration of the control unit 230 provided on the effect control board 201 as the sub control board. 7 is a circuit diagram for explaining the configuration of the power supply board 202, and FIG. 8 is a circuit diagram for explaining the configuration around the CPU in the game control board 200. FIG. These are circuit diagrams for explaining a configuration around a CPU in the effect control board 201. FIG.
[0067]
Of the various boards provided in the slot machine 1, the game state is mainly controlled by the game control board 200, and the effect control according to the game state is performed by the effect control board 201. Further, power is supplied to the power supply board 202 from the outside of the slot machine 1. Connected to the power supply board 202 are a power cord 84 for receiving a power supply of AC 100V and a main switch 80.
[0068]
The game control board 200 is wire-connected to the effect control board 201, the power supply board 202, and the reel relay board 203, and is connected to the external output board 205 via the reel relay board 203 and the reel via the effect control board 201. It is connected to the lamp relay board 204.
[0069]
The control unit 210 of the game control board 200 is a RB signal indicating that the gaming state is the RB state, a BB signal indicating that the gaming state is the BB state, and a reel corresponding to each of the reels 51L, 51C, and 51R. A reel control signal (motor phase signal) for controlling the motors 54L, 54C, 54R, a medal IN signal indicating the number of medals used for setting the bet number, and medals (payout) to the player due to the occurrence of winning A medal OUT signal indicating the number of credits is controlled from the external output board 205 to the outside of the slot machine 1 via the reel relay board 203. Note that the stop switch signal indicating that the stop switches 103L, 103C, and 103R have been operated is a signal directly output from the stop switches 103L, 103C, and 103R, as will be described later.
[0070]
The game control board 200 is connected to wiring from various switches, sensors, lamps, and displays.
[0071]
For example, the setting switch 83, the setting key switch 82, the second reset switch 81, the payout sensor 61, and the hopper motor 62 that are wired to the power board 202 are relayed by the power board 202 and wired to the game control board 200. The detection signals of the respective switches and sensors are input to the control unit 210 of the game control board 200. Further, the control unit 210 outputs a control signal to the hopper motor 62 when a medal payout condition (occurrence of winning that requires a medal payout, detection signal input from the settlement switch 104) is established, and a predetermined number The payout control for paying out the medals is executed.
[0072]
The reel motors 54L, 54C, 54R connected to the reel relay board 203 and the reel sensor 56 are relayed by the reel relay board 203 and connected to the game control board 200. The detection signal of the reel sensor 56 is: Input to the control unit 210 of the game control board 200. The reel lamp 55 is relayed by the reel lamp relay board 204 and connected to the effect control board 201 by wiring. When the start condition (input of the detection signal of the start switch 102) is satisfied, the control unit 210 of the game control board 200 outputs a control signal to the reel motors 54L, 54C, 54R to start reel fluctuation, and then displays Variable display control is performed to derive and display the results.
[0073]
Among the switches connected to the game control board 200, the single BET switch 100 detects the operation of the single BET button 36a, the MAXBET switch 101 detects the operation of the MAXBET button 36b, and the start switch 102 The left, middle, and right stop switches 103L, 103C, and 103R are switches that detect the operation of the left, middle, and right stop buttons 40L, 40C, and 40R. The settlement switch 104 is a switch that detects an operation of the settlement button 37, and the first reset switch 105 is a switch that detects a reset operation of the slot machine 1 by a key inserted into the keyhole 3 a of the locking device 3.
[0074]
The inserted medal sensor 106 is a sensor that detects a medal inserted into the medal insertion unit 34. The flow path switching solenoid 107 is a solenoid for switching the flow path of medals inserted into the medal insertion section 34 to the hopper tank 57 side or the medal payout hole 9 side.
[0075]
The game number display unit 108 is a display unit constituting the game number display unit 32, the credit display unit 109 is a display unit configuring the credit display unit 31, and the payout display unit 110 is a display unit configuring the payout display unit 33. It is.
[0076]
The insertion instruction lamp 111 is a lamp built in the insertion instruction display unit 30, the one-bet lamp 112 is displayed on the one-bet display unit 21, and the two-bet lamps 113 and 114 are displayed on the two-bet display units 22 and 23. The three betting lamps 115 and 116 are lamps built in the three betting display sections 24 and 25.
[0077]
The game over lamp 117 is a lamp built in the game over display section 26, the start lamp 118 is a lamp built in the start display section 29, and the replay lamp 119 is a lamp built in the replay display section 27. The bonus notification lamp 120 is a lamp built in the stop button unit 39. The BET button lamp 121a is a lamp built into the single BET button 36a, and the BET button lamp 121b is a lamp built into the MAXBET button 36b. The left operation valid lamp 122L is a lamp built in the left stop button 40L, the middle operation valid lamp 122C is a lamp built in the middle stop button 40C, and the right operation valid lamp 122R is connected to the right stop button 40R. The weight lamp 139 is a lamp built in the weight display unit 28.
[0078]
Various lamps and displays connected to the game control board 200 via the power supply board 202, the reel relay board 203, or without these boards are controlled by the control unit 210 mounted on the game control board 200. The The control unit 210 is connected to the game control board 200 or receives detection signals from various switches and sensors connected to the game control board 200 via the power supply board 202 or the reel relay board 203 to control the game state. To do.
[0079]
In particular, the “credit display device 109, game number display device 108, payout display device 110, insertion instruction lamp 111, 1-sheet betting lamp 112 to 3-sheet betting lamp 116, start lamp 118, replay lamp 119 are controlled by the control unit 210. The bonus notification lamp 120, the game overlamp 117, the left, middle, and right operation effective lamps 122L, 122C, 122R, and the weight lamp 139 ”notify information related to the progress of the game, and if they do not function, It can be said that it is an “essential notification device (peripheral device for gaming according to the present invention)” that interferes with playing a game. Since these “essential notification devices” are controlled by the control unit 210 that controls the gaming state, even if the production control board 201 breaks down, at least information necessary for the progress of the game is provided to the player. . For this reason, it is possible to prevent the game from proceeding in a state disadvantageous to the player.
[0080]
As shown in FIG. 5, the control unit 210 provided on the game control board 200 has a CPU (Central Processing Unit) 211 as a main CPU capable of executing a control operation in a predetermined procedure, and a control program for the CPU 211. A ROM (Read Only Memory) 213 to be stored, a RAM (Random Access Memory) 212 as a main memory capable of writing and reading necessary data, and an I / O for consistency of signals between the CPU 211 and an external circuit Port 214. That is, the control unit 210 is constituted by a one-chip microcomputer in which all of the CPU 211, RAM 212, ROM 213, and I / O port 214 are built.
[0081]
The game control board 200 also includes an initial reset circuit 217 that applies a reset pulse to the CPU 211 when the power is turned on, a clock generation circuit 218 that supplies a clock signal to the CPU 211, and a clock signal from the clock generation circuit 218 that is divided. A pulse frequency dividing circuit (interrupt pulse generation circuit) 219 that periodically supplies an interrupt pulse to the CPU 211, a random number generation circuit 221 that continuously generates a random number within a certain range at high speed, and a random number from the random number generation circuit 221 A sampling circuit 222 for sampling and a buffer circuit 220 are provided. Further, the game control board 200 is provided with a switch circuit 215 to which signals from various switches are input, a motor circuit 216, and other solenoid circuits (not shown).
[0082]
As shown in FIG. 6, the RAM 212 has a work area used as a work memory for the CPU 211, and backup areas 1 to 1 that store main backup data as game information capable of specifying the game state at the time of power failure. 3 and a parity data storage area in which parity data for confirming the correctness of the data stored in these backup areas, a power-off flag to be described later, and the like are stored. Of these, the work area is a non-backup RAM area in which data stored during a power failure is not retained, and the backup areas 1 to 3 and the parity data storage area are stored by being energized by a backup power source during a power failure. This is a backup RAM area in which stored data is held.
[0083]
In the ROM 213, in addition to the control program, a sampling value allocation range corresponding to each award includes a set value of each winning probability (a payout rate), a bet number of a game, a gaming state (in a normal game, in a BB, Each RB) is registered correspondingly, and the combination of winning symbols corresponding to each prize, the number of medals to be paid out, and various setting contents set in accordance with the winning are set in each gaming state (in the normal game, in the BB). , At the time of RB), a winning determination table (not shown) respectively registered correspondingly is stored. In this winning determination table, the allocation range of the sampling value of each award is registered as described above, and by setting the allocation range of these sampling values, the winning probability of the award that can be won in the internal lottery process described later, That is, the payout rate of the slot machine 1 is set.
[0084]
Further, the ROM 213 has a symbol number of symbols that moves from the stop operation of each reel 51L, 51C, 51R to the corresponding reel being stopped for each symbol number of each reel 51L, 51C, 51R. Game state (in normal game, BB, RB), internal winning flag setting status, rotation status of other reels, reels 51L, 51C located on active lines L1, L2, L2 ′, L3, L3 ′ , 51R, and reel control tables (not shown) registered according to various situations such as symbol numbers are stored.
[0085]
From the control unit 210 of the game control board 200 to the effect control board 201, the buffer circuit 220 is used to instruct various commands as effect control information that can specify the game state controlled by the control unit 210 and the initialization of the effect state. An initialization command (initialization command) is output. The buffer circuit 220 functions to allow a signal to be output from the inside to the outside of the game control board 200 but to prevent a signal from being input from the outside to the inside of the game control board 200. Therefore, one-way communication from the game control board 200 to the effect control board 201 is ensured between the game control board 200 and the effect control board 201, and a signal is input to the game control board 200 via the command transmission path. It is possible to prevent fraudulent acts that cause unauthorized control operations.
[0086]
The effect control information in the present invention is information that triggers execution of a predetermined effect when the sub control board receives the effect control information. In the present embodiment, as described later, when the effect control board 201 receives various commands that can specify the game state, the effect according to the game state specified by the received command is executed. That is, in the effect control board 201, since the reception of various commands transmitted from the game control board 200 triggers the execution of the effect, these various commands for which the gaming state can be specified correspond to the effect control information. In addition, the content of the effect executed by the effect control board 201 is determined by the game control board 200, and an effect control command for instructing execution of the corresponding effect is transmitted to the effect control board 201, and the effect control is performed based on this. In the case where the effect instructed by the substrate 201 is executed, these effect control commands correspond to the effect control information.
[0087]
On the effect control board 201, game effect lamps 130 to 134 as effect means, a liquid crystal display 135, speakers 136a, 136b, 137 built in the sound emitting units 12a, 12b, 13, the title panel 8 and the game Respective fluorescent lamps 138 for illuminating the panel 6 from the inside and small role notification lamps 140a, 140b, 140c are connected to each other, and further, reels incorporated in the reels 51L, 51C, 51R via the reel lamp relay board 204. A lamp 55 is connected.
[0088]
The effect control board 201 includes a control unit 230, a speaker drive circuit 235 for outputting sounds from the speakers 136a, 136b, and 137, a display drive circuit 236 for controlling display of the liquid crystal display 135, and various lamps. And a lamp driving circuit 237 for lighting or blinking.
[0089]
The control unit 230 includes a CPU 231 serving as a sub CPU, a RAM 232 serving as a sub memory capable of writing and writing necessary data, a ROM 233 storing a control program, and an I / O port 234. Similarly to the control unit 210, the control unit 230 is also configured by a one-chip microcomputer.
[0090]
Similar to the control unit 210, the RAM 212 is stored in the work area, the backup areas 1 to 3 in which sub-backup data is stored as effect information that can specify the effect state at the time of power failure, and these backup areas. A parity data storage area for storing parity data for confirming whether the data is correct, the work area is a non-backup RAM area, the backup areas 1 to 3 and the parity data storage area are backups. It is a RAM area.
[0091]
The ROM 233 stores a command table in which data that can specify a game state, an internal winning situation, and the like based on various commands transmitted from the game control board 200 is stored, and is transmitted from the game control board 200. An effect pattern table in which an effect pattern is determined corresponding to a gaming state specified based on various commands is stored. This effect pattern table is classified into each game effect lamp 130 to 134, liquid crystal display 135, each speaker 136a, 136b, 137, each fluorescent lamp 138, and small role notification lamps 140a to 140c, for example, a predetermined game. When the command indicating the state is received, the control unit 230 extracts an effect pattern corresponding to the gaming state, and according to the extracted effect pattern, the game effect lamps 130 to 134, the liquid crystal display 135, the speakers 136a, 136b and 137, each fluorescent lamp 138, small role notification lamps 140a to 140c, reel lamp 55, and the like are controlled.
[0092]
The game effect lamps 130 to 134, the liquid crystal display 135, the speakers 136a, 136b, and 137, the fluorescent lights 138, the small role notification lamps 140a to 140c, and the reel lamp 55 controlled by the effect control board 201 are game control boards. Compared to various displays controlled by 200, even if it does not function, it does not affect the progress of the game itself. Peripheral equipment) ”. For this reason, even if a failure occurs in the effect control board 201, not only a disadvantageous situation is not provided to the player, but the control load of the control unit 210 is reduced.
[0093]
Returning to FIG. 5, the detection signal of the start switch 102 is input to the control unit 210 via the switch circuit 215 and also to the sampling circuit 222. The control unit 210 receives the detection signal of the start switch 102 and outputs a reel control signal via the motor circuit 216. This reel control signal is input to the reel motors 54L, 54C, 54R provided for each of the reels 51L, 51C, 51R via the reel relay substrate 203. The reel control signal is output to the outside of the slot machine 1 via the reel relay board 203 and the external output board 205.
[0094]
Thereby, each reel 51L, 51C, 51R starts to fluctuate. Further, the reel control signal transmission path is branched to the reel motors 54L, 54C, 54R side and the external output board 205 side in the reel relay board 203, and the reel control signal output to the external output board 205 side is Also output from the external output board 205 to the outside of the slot machine 1. As described above, the reel control signal output from the external output board 205 is not a signal processed for external output but a signal itself for driving and controlling the reel motors 54L, 54C, and 54R.
[0095]
On the other hand, the sampling circuit 222 samples one random number from the random number generation circuit 221 at the timing when the detection signal of the start switch 102 is input, and delivers the random number to the CPU 211. The CPU 211 refers to the sampled random number and the winning determination table stored in the ROM 213 to determine whether or not to allow the generation of a winning for each winning combination, and stores the determination result in the RAM 212. . Thereby, an internal lottery process, which will be described later, is performed at a timing substantially equal to the timing at which the start operation is performed, and whether or not the winning combination is won is determined. Thereafter, the control unit 210 controls the reels according to the winning results for each winning combination.
[0096]
The stop switch signals output from the stop switches 103L, 103C, and 103R are transmitted through signal paths that reciprocate between the game control board 200, the reel relay board 203, and the external output board 205, and then the game control board 200 Input to the switch circuit 215. Further, the stop switch signals output from the stop switches 103L, 103C, and 103R are directly output to the outside via the external output board 205.
[0097]
Receiving the input of the stop switch signal, the control unit 210 outputs a reel control signal for stopping the reel motors 54L, 54C, 54R corresponding to the stop switch signal via the motor circuit 216. The reel control signal is input to the reel motors 54L, 54C, and 54R, and is output to the outside of the slot machine 1 via the external output board 205.
[0098]
The signal output from the external output board 205 can be used, for example, when a third party engine performs a type test. In this type test, for example, it is confirmed whether or not each reel 51L, 51C, 51R corresponding to each stop button 40L, 40C, 40R stops within 190 ms from the operation of each stop button 40L, 40C, 40R. In the case of this slot machine 1, since the stop switch signal output from each stop switch 103L, 103C, 103R is directly output from the external output board 205, the timing at which each stop button 40L, 40C, 40R is operated is indicated. Accurately grasp outside the slot machine. Similarly, since the reel control signal output from the motor circuit 216 is output directly from the external output board 205, the start and stop timing of each reel 51L, 51C, 51R can be accurately grasped outside the slot machine. For this reason, using the signal output from the external output board 205, “the respective reels 51L, 51C, 51R corresponding to the stop buttons 40L, 40C, 40R are within 190 ms from the operation of the respective stop buttons 40L, 40C, 40R. In the case of performing the “test of whether or not to stop”, an accurate test result can be obtained. In addition, when the “control unit 210 of the game control board 200 once captures the signal and then outputs the signal to the external output board 205”, the game control board 200 side processes and outputs the signal. However, according to the present embodiment, such an illegal act can be prevented.
[0099]
FIG. 7 is a circuit diagram illustrating a configuration example of the power supply substrate 202. The power supply board 202 generates voltages used by electrical components such as the game control board 200, various switches, sensors, indicators, lamps, motors, solenoids and the like.
[0100]
The transformer 304 converts AC 100V from the AC power source into AC 24V. Further, the rectifier circuit 302 generates a DC voltage of + 30V from AC24V and outputs it to the DC-DC converter 303. The DC-DC converter 303 generates + 24V, + 12V and + 8V as a supply voltage and outputs the generated voltage to the connector 301. The connector 301 is connected to the game control board 200 and the like, and is supplied with voltage power necessary for the game control board 200, the effect control board 201, and various electric components. A main switch 80 (see FIG. 4) for stopping or starting the power supply to the slot machine 1 is installed on the input side of the transformer 304.
[0101]
In the present embodiment, a + 8V DC voltage is supplied to the hopper motor 62 and used as a drive voltage, and is also supplied to the game control board 200 to drive each device of the game control board 200 and the effect control board 201. It is used as a drive voltage for the power source, the switches and sensors, lamps (except for the operation effective lamps 122L, 122C, 122R) directly or indirectly connected to the game control board 200, and the display. Further, the + 12V DC voltage is supplied to the game control board 200 and used as a driving voltage for the operation effective lamps 122L, 122C, 122R. Further, the + 12V DC voltage is supplied to the effect control board 201 via the game control board 200 and used as a driving voltage for the liquid crystal display 135. The + 24V DC voltage is supplied to the game control board 200 and used as a drive voltage for the reel motors 54L, 54C, 54R and the flow path switching solenoid 107. Further, a + 24V DC voltage is supplied to the effect control board 201 via the game control board 200 and used as a drive voltage for a lamp, speaker, or fluorescent lamp that is directly or indirectly connected to the effect control board 201. The
[0102]
As described above, in this embodiment, the voltage that is supplied to the game control board 200 and drives the devices of the game control board 200 and the effect control board 201 is directly or indirectly supplied to the game control board 200. Since it is used as a driving voltage for peripheral devices for gaming, such as connected switches and sensors, lamps, indicators, motors, etc., it becomes unnecessary to separately introduce driving voltages for these peripheral devices for gaming, The configuration of the slot machine 1 can be simplified.
[0103]
FIG. 8 is a circuit diagram showing a configuration example around the CPU 211 in the game control board 200. As shown in FIG. 8, + 8V output from the power supply board 202 is supplied to the DC-DC converter 223. The DC-DC converter 223 generates +5 V and outputs it to the CPU 211, the RAM 212, and the power supply monitoring IC 224. This + 5V is used as a drive voltage for these devices. Further, + 5V generated by the DC-DC converter 223 is output to the effect control board 201 and used as a drive voltage for each device of the effect control board 201 as will be described later.
[0104]
In this embodiment, as described above, + 8V as the supply voltage supplied to the DC-DC converter 223 is used as the drive voltage for the game peripheral device. Without being limited, + 5V as the driving voltage generated by the DC-DC converter 223 may be used as the driving voltage of these gaming peripheral devices. By adopting such a configuration, It is not necessary to introduce a driving voltage for the gaming peripheral device separately, and it is not necessary to provide a generating means for generating a voltage used as a driving voltage for the gaming peripheral device separately from the DC-DC converter 223. Therefore, the configuration of the slot machine 1 can be simplified.
[0105]
Further, the + 5V line from the DC-DC converter 223 branches to form a main backup + 5V line. A large-capacitance capacitor 226 is connected between the main backup + 5V line and the ground level. The capacitor 226 serves as a backup power supply that supplies a voltage so that the RAM 212 can maintain the storage state of the backup RAM area when the voltage supply to the slot machine 1 is cut off. Further, a backflow preventing diode 225 is inserted between the + 5V line and the main backup + 5V line. As a backup power source, a battery that can be charged from a + 5V power source may be used.
[0106]
The power monitoring IC 224 introduces a voltage of + 8V output from the power supply board 202, that is, a voltage that is a source of driving voltage of the CPU 211 that controls the devices of the game control board 200, particularly each part, and uses this + 8V voltage. The occurrence of power interruption is detected by monitoring. In this embodiment, when the + 8V voltage becomes a predetermined value or less, a voltage drop signal is output. This voltage drop signal is input to the non-maskable interrupt terminal (NMI terminal) of the CPU 211. That is, the CPU 211 can confirm the occurrence of the power interruption by the interrupt process based on the input of the voltage drop signal from the power monitoring IC 224.
[0107]
Note that the voltage for the power monitoring IC 224 to detect power-off is a voltage higher than the normal operating voltage of the CPU 211, and in this embodiment, the occurrence of power-off is detected when the voltage drops to + 7.2V. . The power monitoring IC 224 is configured to monitor a voltage higher than a voltage for driving the CPU 211 (+5 V in this embodiment), that is, a voltage of +8 V supplied to the DC-DC converter 223. The monitoring range can be expanded for the voltage required by the CPU 211, and more precise monitoring can be performed.
[0108]
In this embodiment, the CPU 211, RAM 212, and power supply monitoring IC 224 are driven with a power supply voltage of + 5V in a normal state, and the power supply monitoring IC 224 has a voltage higher than + 5V that drives these devices. When the voltage drops to + 7.2V, a voltage drop signal is output. Since a + 5V voltage is supplied to the device such as the CPU 211 for a while after the occurrence of the power interruption is detected, the voltage drops. Based on the input of the signal, the CPU 211 can sufficiently secure the time necessary for performing the main power failure interruption process described later.
[0109]
In the case of the present embodiment, the time required for the CPU 211 of the game control board 200 to complete the main power failure interruption process after receiving the voltage drop signal is about 2 ms, whereas the game The time until the + 8V voltage supplied to the control board 200 drops to + 7.2V and then to + 5V, that is, the time until the drive voltage of the CPU 211 starts to drop after the detection of the power failure is about 100 ms. . Note that the present invention is not limited to this, and at least when the power is cut off, the driving voltage of the CPU 211 in the game control board 200 is set to a time that can be held until the main power failure interruption process is completed. Just do it.
[0110]
In this embodiment, the power monitoring IC 224 monitors the voltage that is the source of the driving voltage of the CPU 211, that is, the voltage of + 8V supplied to the DC-DC converter 223 to generate + 5V that drives the CPU 211. Since a stable voltage is monitored compared to a drive voltage that tends to go up and down depending on the drive status of each device, the occurrence of power interruption is determined with a temporary voltage drop, which will be described later. It is possible to prevent malfunction such as interruption processing at the time of main power failure.
[0111]
Note that the present invention is not limited to this, and a voltage that is a source of a power supply voltage for driving peripheral devices for games such as switches, sensors, lamps, and displays connected to the game control board 200, for example, The voltage supplied to the DC-DC converter 303 may be introduced and monitored in order to generate + 8V, + 12V, and + 24V for driving these gaming peripheral devices. Since a stable voltage is monitored compared to a driving voltage that tends to rise and fall depending on the driving situation, the occurrence of a power interruption is determined with a temporary voltage drop, and the main power interruption interrupt process described later is performed. Malfunctions such as breakage can be prevented.
[0112]
FIG. 9 is a circuit diagram illustrating a configuration example around the CPU 231 in the effect control board 201. As shown in FIG. 9, +5 V generated by the DC-DC converter 223 of the game control board 200 is supplied to the effect control board 201 and used as a drive voltage for the CPU 231 and the RAM 232.
[0113]
In this embodiment, as described above, the power supply board 202 is used as a driving voltage for the peripheral devices for production such as the lamp, the speaker, the fluorescent lamp, the liquid crystal display 135 and the like directly or indirectly connected to the production control board 201. However, the present invention is not limited to this, and as a driving voltage for these staging peripheral devices, the game is not limited to this. + 5V as the drive voltage supplied from the control board 200 may be used. With such a configuration, it is not necessary to separately introduce the drive voltage of the production peripheral device. The configuration can be simplified.
[0114]
Further, the + 5V line from the game control board 200 branches to form a sub-backup + 5V line. A large-capacitance capacitor 240 is connected between the sub-backup + 5V line and the ground level. The capacitor 240 serves as a backup power source that supplies a voltage to the RAM 232 so that the storage state of the backup RAM area can be maintained when the voltage supply to the slot machine 1 is cut off. Further, a backflow preventing diode 239 is inserted between the + 5V line and the sub-backup + 5V line. As a backup power source, a battery that can be charged from a + 5V power source may be used.
[0115]
Further, in this embodiment, the voltage at which the power monitoring IC 224 of the game control board 200 outputs a voltage drop signal, that is, the voltage (+ 7.2V) that triggers the CPU 211 of the game control board 200 to stop the operation, The drive voltage of the CPU 231 and the RAM 232 of the effect control board 201 (+5 V in this embodiment) is set higher, so that the game control board 200 operates at an earlier stage than the effect control board 201 during a power failure. Even if the operation of the game control board 200 stops, the effect control board 201 can operate for a while, so that the effect control board 201 reliably receives various commands transmitted from the game control board 200. In addition, as will be described later, the reception of various commands is triggered by the CPU 231 of the effect control board 201. It is possible to execute the backup process more reliably.
[0116]
In the case of the present embodiment, the time required from when the CPU 211 of the game control board 200 receives the voltage drop signal to the completion of the main power failure interruption process is about 2 ms. After the disconnection is detected, the time until the drive voltage of the CPU 231 of the effect control board 201 starts to drop is about 100 ms. Further, the time required for the CPU 231 of the effect control board 201 to receive various commands from the game control board 200 and execute a sub-backup process described later is about 16 ms. For this reason, even if the operation of the game control board 200 stops after the effect control board 201 receives a command from the game control board 200 immediately before the occurrence of the power interruption, the CPU 231 of the effect control board 201 operates due to a voltage drop. Thus, the sub-backup process can be surely executed before the system stops.
[0117]
Next, various control contents executed by the CPU 211 of the control unit 210 mounted on the game control board 200 in the present embodiment will be described based on the flowcharts of FIGS.
[0118]
As shown in FIG. 10, when the power is turned on, first, it is confirmed whether or not the setting key switch 82 is on (Sa1). That is, it is confirmed whether the power is turned on based on an operation for changing the set value or initializing the gaming state.
[0119]
When the setting key switch 82 is on, a main initialization process as a game information initialization process for initializing the game state is executed (Sa2), and the setting value of the winning probability can be changed. A setting change process is executed (Sa3).
[0120]
In the main initialization process, as shown in FIG. 11, after performing the process of clearing the register and RAM 212 (Sb1), an initialization command for instructing the initialization of the effect state is set in the command table (Sb2). Then, a command transmission process (Sb3) for transmitting the set initialization command to the effect control board 201 is performed, and further a necessary initial value setting process (Sb4) is performed. As will be described in detail later, the presentation state controlled by the presentation control board 201 is also initialized by the transmission of the initialization command. That is, the main initialization process also functions as an initialization command transmission process.
[0121]
Further, in the command transmission processing performed in Sb3, as shown in FIG. 13, the transmission delay time is randomly selected and determined from 0 to 37 ms (Sd1), and the command is transmitted when the determined transmission delay time elapses. The command set on the table is transmitted to the effect control board 201 (Sd2, Sd3).
[0122]
As will be described later, this command sending process is executed in the same manner when various commands that can specify the gaming state are sent, in order to send a command to the effect control board 201 with a predetermined delay. It is processing of.
[0123]
In the setting change process, as shown in FIG. 12, the setting switch 83 or the start switch 102 waits for detection (Sc1, Sc3), and the setting button 67 is operated in this state to detect the setting switch 83. Each time the winning probability setting value is changed by one (Sc1, Sc2). Further, when the start lever 38 is operated in the state of Sc1 and Sc3 and the start switch 102 is detected (Sc3), the set value is determined. Next, the process waits until the setting key switch 82 is turned off (Sc4), and the process ends when the setting key switch 82 is detected to be off. As described above, the setting of the winning probability can be changed by turning on the power with the setting key switch 82 in the on state. In addition, when the power is turned on with the setting key switch 82 in the on state, the gaming state is always initialized. Therefore, when simply resetting the gaming state, the setting key switch 82 is in the power state as the setting key switch on. The processing may be terminated without changing the set value after inputting.
[0124]
Returning to FIG. 10, when the setting key switch 82 is off in Sa1, it is confirmed whether or not it is at the time of recovery from the power failure (Sa4). Whether or not the power failure has been recovered is confirmed by a power-off flag set at the time of power-off.
[0125]
If it is at the time of recovery from a power failure, a data check (parity check in this embodiment) of the backup RAM area in the RAM 212 is performed (Sa5, Sa6). In the case of recovery after an unexpected power failure, the main backup data should have been stored in the backup RAM area of the RAM 212, so the check result is normal.
[0126]
If the check result is normal, the main backup data in the backup areas 1 to 3 in the RAM 212 is compared to check whether the correct data is backed up based on whether or not at least two main backup data match (Sa7, Sa8).
[0127]
If the comparison result is normal, all the registers are restored from the main backup data in the backup area in the RAM 212 (Sa9), the power-off flag is cleared (Sa10), and the routine returns to the routine before the power-off. That is, the game state is restored when the power is turned off.
[0128]
If the result of the data check and the comparison result are not normal, the game state cannot be returned to the state when the power is turned off, so an error code indicating that the game state cannot be returned to the state before the power is turned off is displayed. The information is displayed on the unit 32 and notified to the outside (Sa11), and the same main initialization process as that executed in the step Sa2 described above is executed (Sa12) to initialize the gaming state. The main initialization process is also executed when it is confirmed at Sa4 that the power failure is not restored, that is, when the power-off flag is not set (Sa12).
[0129]
When the setting change process described above is completed, or when the main initialization process in step Sa12 is completed, the process proceeds to a loop process that repeatedly executes the game control process (Sa13).
[0130]
As shown in FIG. 14, in the game control process, first, an initial setting for preparing for the game start is executed (Se1).
[0131]
Next, BET processing for determining the bet amount when the start lever 38 is pressed is executed (Se2). Specifically, one or more credits are used when one or more medals are inserted, or when one or more BET buttons 36a or MAXBET buttons 36b are pressed, waiting in a state where medals or credits can be accepted. When the start lever 38 is pressed, the bet number of medals is determined when the start lever 38 is pressed, and the game is started. Further, when the replay is won in the previous game, the same number of bets as the previous game are set, the pressing operation of the start lever 38 is enabled, and the betting number at the time when the starting lever 38 is pressed. Is confirmed and the game is started.
[0132]
Note that if there are further medals inserted from the state where the maximum bet number (3 BET in this embodiment) is set until the start lever 38 is pressed, this corresponds to the number of medals inserted. The valuable value to be stored is stored as a credit in the RAM 212 and displayed on the credit display unit 31.
[0133]
Next, with the start of the game by pressing the start lever 38 in Se2, it is determined whether or not to accept any of the above-described prizes (BB, RB, or other small role that is a small profit for the player). The internal lottery process is executed (Se3). This internal lottery process is executed in order to determine whether or not to accept any prize in a stage before all the reels 51L, 51C, 51R are stopped. In other words, winning is permitted only when the internal winning flag corresponding to one of the prizes won by the lottery is set. That is, the control unit 210 has a function as a pre-determining unit that determines whether or not any prize is allowed.
[0134]
Next, a reel rotation process for rotating the reels 51L, 51C, and 51R is performed with the end of the internal lottery process of Se3 (Se4). In this reel rotation process, the error check by the reference position check during the rotation of the reels 51L, 51C, 51R is confirmed at any time by timer interruption every predetermined time. In addition, when all the reels 51L, 51C, 51R are rotated, the pressing operation of the stop buttons 40L, 40C, 40R is made effective, the operation valid lamps 122L, 122C, 122R are turned on, and the timer count for stopping the reels is started. To do.
[0135]
Next, the player presses the stop buttons 40L, 40C, 40R, or the player does not press the stop buttons 40L, 40C, 40R from the start of rotation of the reels 51L, 51C, 51R. When the conditions for stopping and displaying the symbols are satisfied after 30 seconds as the predetermined time has elapsed, the stop flag of each reel 51L, 51C, 51R is set, and the press is performed based on the setting of the stop flag. The operation valid lamps 122L, 122C, 122R corresponding to the operated stop buttons 40L, 40C, 40R are turned off, and a reel stop process for stopping the rotation of the corresponding reels 51L, 51C, 51R is performed (Se5).
[0136]
Further, in this embodiment, only when the internal winning flag corresponding to any prize is set by the internal lottery processing described above, the combination of symbols corresponding to the prize is arranged on a predetermined active line. Stop control, and if the internal winning flag corresponding to any award is not set, stop control so that the combination of symbols corresponding to the award will not be aligned on the activated effective line in the end To do. In other words, unless any prize is won internally by the internal lottery process, each prize is not won, and each prize is generated on average during a repeated game.
[0137]
Next, when it is determined in Se5 that the rotation of all the reels 51L, 51C, 51R has been stopped, the display content displayed on the variable display device 50, the content of the internal winning flag that has been won and set in Sa3, etc. And a winning determination process for determining the contents of the winning is executed (Se6). Also, when it is determined that a prize has been won, various settings corresponding to the contents of the prize are executed. As the setting contents, for example, there are settings such as the number of payout medals corresponding to the winning contents, a gaming state, a re-game, and the like.
[0138]
A process based on the set content set corresponding to the winning content determined in Se6 is executed (Se7). Specifically, processing of medal payout processing for the set number of payout medals and game state change (change from normal game state to special game state, or change from special game state to normal game state, etc.) To do.
[0139]
Thus, in the game control process, various controls are performed according to the progress of the game. Further, in this game control process, a process of transmitting various commands that can specify the game state at that time to the effect control board 201 according to the progress of the game is performed. Various commands transmitted to the effect control board 201 are transmitted by a command transmission process in the same manner as the initialization command described above. These various commands are also transmitted with a predetermined delay within a range of 0 to 37 ms.
[0140]
As described above, various commands for the effect control board 201 are transmitted with a delay of a predetermined period, so that a command capable of specifying the gaming state is transmitted in synchronization with the gaming state controlled by the gaming control board 200. Inconvenient, for example, the reel symbol display state and the like are transmitted to the effect control board 201 in synchronism, and the timing for aligning a specific symbol is notified, so-called eye-pressing assistance is executed. The accompanying inconvenience can be prevented.
[0141]
FIG. 15 is a flowchart showing a main power failure interrupt process as a main backup process executed in response to the NMI based on the voltage drop signal from the power monitoring IC 224. That is, the main power failure interrupt process is a process executed when the + 8V power supply voltage supplied to the game control board 200 from the power supply board 202 becomes 7.2 V or less, which is a predetermined voltage due to a power failure. .
[0142]
In the main power failure interruption process, first, interruption is prohibited (Sf1). In the main power failure interrupt process, a checksum generation process is performed to ensure the storage of data in the RAM 212. If another interrupt process is performed during the process, the CPU 211 may fall to a voltage at which the CPU 211 cannot operate before the checksum generation process is completed. Setting is made so as not to occur.
[0143]
Next, it is confirmed whether or not the power-off flag is already set (Sf2). If the power-off flag is already set, the subsequent processing is not performed. As a result, after the power is turned on, before the power-off flag is cleared, that is, before the return of the gaming state is completed, an inconvenience such as an NMI being generated and the main backup data being overwritten can be avoided.
[0144]
If the power-off flag is not set, the following processing is executed.
[0145]
First, all output ports are turned off (Sf3). Then, the contents of each register, that is, main backup data as game information capable of specifying the game state at that time is stored in the backup RAM areas 1 to 3 of the RAM 212 (Sf4 to Sf6). At this time, the same main backup data is stored in the backup RAM areas 1 to 3 in the RAM 212. This makes it possible to more reliably back up the gaming state during a power failure. Further, parity data is generated based on the data of the entire backup RAM area in the RAM 212 (Sf7), and the generated parity data is stored in the parity data storage area (Sf8). Thereafter, the power-off flag is set (Sf9). As described above, this power-off flag is used when determining whether or not to recover from a power failure when power is turned on. Next, the RAM 212 is set in an access prohibited state (Sf10). As the power supply voltage decreases, the levels of various signal lines may become unstable and the contents of the RAM 212 may be altered. If the access to the RAM 212 is prohibited in this way, the contents of the backup RAM The data will never be garbled. Next, a loop process in which no process is performed is entered. That is, the operation is stopped internally. Therefore, the CPU 211 reliably stops operation when the power is turned off. In the main power failure interrupt process of this embodiment, the program is looped at the final part, but a halt (HALT) instruction may be issued.
[0146]
Next, various control contents executed by the CPU 231 of the control unit 230 mounted on the effect control board in the present embodiment will be described based on the flowcharts of FIGS.
[0147]
As shown in FIG. 16, when the power is turned on, first, it is confirmed whether backup data is stored (Sg1). Whether or not the backup data is stored is confirmed by whether or not the data is stored in the backup RAM area of the RAM 232.
[0148]
When the backup data is stored, it waits in a state of waiting for reception of the initialization command transmitted from the game control board 200 until the command reception waiting time elapses (Sg2, Sg3). The command reception waiting time is a time sufficient to reliably receive the initialization command transmitted to the effect control board 201 when the CPU 211 of the game control board 200 executes the main initialization process after the power is turned on. is there.
[0149]
If the initialization command is not received even after the command reception waiting time elapses, a data check (parity check in this embodiment) of the backup RAM area in the RAM 232 is performed (Sg4, Sg5). In the case of recovery after an unexpected power failure, the sub-backup data should have been stored in the backup RAM area of the RAM 232, so the check result is normal.
[0150]
If the check result is normal, the sub-backup data in the backup areas 1 to 3 in the RAM 232 are compared, and it is confirmed whether correct data is backed up based on whether or not at least two sub-backup data match (Sg6, Sg7).
[0151]
If the comparison result is normal, all the registers are restored from the sub-backup data in the backup area in the RAM 232 (Sg8), and the routine before the power interruption is returned to. That is, the production state is restored when the power is turned off.
[0152]
If the result of the data check and the comparison result are not normal, the effect state cannot be returned to the state at the time of power-off, so a sub-initialization process for initializing the effect state is executed (Sg9). When it is confirmed that the sub-backup data is not stored in Sg1, or when an initialization command is received from the game control board 200 in Sg2 and Sg3, that is, the effect state is initialized from the CPU 211 of the game control unit 210. Even when instructed, the sub-initialization process is executed.
[0153]
In the sub-initialization process, as shown in FIG. 17, after the process of clearing the register and RAM 232 (Sh1), the necessary initial value setting process (Sh2) is performed. Further, the output state of various lamps, display devices, speakers, and the like controlled by the effect control board 201 is set to the initial state (Sh3). That is, with the initialization of the register and RAM 232, the output state of the effect peripheral device is also initialized.
[0154]
When the sub-initialization process is completed, it enters a state of waiting for receiving various commands transmitted from the game control board 200 (Sg10), and every time a command is received from the game control board 200, the effect state at that time is used as sub backup data. After executing the sub-backup process to save (Sg11), according to the game state specified by the received command, the output state of the peripheral devices for presentation such as various lamps, indicators, speakers, etc. is controlled, and various presentations are performed. The process proceeds to a loop process for performing the effect control process (Sg12) to be performed.
[0155]
FIG. 18 is a flowchart showing a sub-backup process that is executed every time a command indicating a gaming state is received from the gaming control board 200.
[0156]
In the sub-backup process, first, interrupt prohibition is set (Si1). In the sub-backup processing, checksum generation processing is performed to ensure the storage of data in the RAM 232. If another interrupt process is performed during the process, it is possible that a power failure will occur and the CPU 231 will not operate before the checksum generation process is completed. First, settings are made so that no other interruption occurs.
[0157]
Next, the contents of each register, that is, sub-backup data as effect information that can specify the effect state at that time is stored in the backup RAM areas 1 to 3 of the RAM 232 (Si2 to Si4). At this time, the same sub-backup data is stored in the backup RAM areas 1 to 3 of the RAM 232. This makes it possible to more reliably perform the production state backup. Further, parity data is generated based on the data in the entire backup RAM area in the RAM 232 (Si5), and the generated parity data is stored in the parity data storage area (Si6). Thereafter, the prohibition of interruption is canceled, and the process proceeds to the effect control process of Sg13.
[0158]
As described above, in the slot machine 1 of the present embodiment, the + 5V voltage generated by the DC-DC converter 223 is used as the voltage for driving the CPU 211 of the game control board 200, and the same + 5V voltage is produced. Since it is also used as a voltage for driving the CPU 231 of the control board 201, the voltage for driving the CPU 231 does not become higher than the voltage for driving the CPU 211, and the malfunction or breakage of the CPU mounted on each board. Can be prevented.
[0159]
Also, in the slot machine 1 of the present embodiment, the effect state controlled by the effect control board 201 is backed up in the RAM 232 of the effect control board 201, and information on the effect state is backed up in the game control board 200. Since there is no need, the burden of the backup capacity of the game control board 200 can be greatly reduced.
[0160]
Further, when the game control board 200 initializes the register and RAM 212 after the power is turned on to initialize the game state, an initialization command is transmitted to the effect control board 201, and the effect control board 201 also receives the register and RAM 232. If the production control board 201 can be restored to the production state before the power is turned off after the power is turned on, the production state is initialized and the production state is initialized. Since it is possible to return to the effect state before the power is turned off based on the sub-backup data stored in the RAM 232, the effect control board 201 can independently return without receiving an instruction from the game control board 200, and the game control board The production control board 201 can be returned without imposing a burden on the 200.
[0161]
Further, in the slot machine 1 of the present embodiment, when a winning probability, that is, a payout rate setting operation is performed, the game control board 200 performs a main initialization process, and accordingly, the effect control board 201. Since the initialization command is transmitted to the effect control board 201, the sub-initialization process is also performed on the effect control board 201. Therefore, when the set value is changed, both the game control board 200 and the effect control board 201 are set to the initial state. It is possible to restore the consistency between the two.
[0162]
Further, in the slot machine 1 of the present embodiment, when an operation for initializing the gaming state is performed, the game control board 200 performs a main initialization process, and accordingly, the effect control board 201 An initialization command is transmitted to the effect control board 201, so that the sub-initialization process is performed. Therefore, when the set value is changed, both the game control board 200 and the effect control board 201 are returned to the initial state. And consistency between the two can be achieved.
[0163]
Further, in the slot machine 1 of this embodiment, when the game state controlled by the game control board 200 can be returned to the state before the power is turned off when the power is turned on, the state is automatically returned to the state before the power is turned off. Thus, it is not necessary to perform an extra operation, so that the game state can be easily restored.
[0164]
In the slot machine 1 of the present embodiment, when the game state controlled by the game control board 200 cannot be restored to the state before the power is turned off when the power is turned on, this is indicated in the game number display section 32 as an error code. It can be displayed, can notify the outside that an error has occurred, and can respond quickly. In the present embodiment, the error notification is performed in the game number display section 32, but the present invention is not limited to this, and for example, an error occurrence is displayed on another display. Alternatively, the occurrence of an error may be notified by lighting a lamp or outputting a notification sound.
[0165]
In the slot machine 1 according to the present embodiment, when the sub-initialization process is performed in the effect control board 201, the registers and the RAM 232 are initialized, and the lamp and display controlled by the effect control board 201 are displayed. The output state of the peripheral devices for presentation such as a device and a speaker is also set to the initial state. In the game control board 200, only the initialization command is transmitted to the presentation control board 201. The output state can be controlled to the initial state.
[0166]
Further, in the slot machine 1 of the present embodiment, when the effect control board 201 receives a command that is the effect control information from the game control board 200, a sub-backup process for saving the effect state at that time is executed. Since the sub-backup process is performed in response to the reception of a command that triggers the performance, the performance control board 201 can be backed up reliably.
[0167]
The present invention is not limited to this, and at least a predetermined trigger other than when the power is turned off, for example, the sub-backup process may be executed by an interrupt process executed at predetermined intervals. The sub-backup process may be executed when a specific effect is executed.
[0168]
In the slot machine 1 of the present embodiment, the sub-backup process is executed every time the effect control board 201 receives a command from the game control board 200, and the effect state performed by the effect control board 201 is changed. Backup can be performed more reliably.
[0169]
The present invention is not limited to this. For example, when a command indicating a specific gaming state is received or each time a command is received a predetermined number of times, the sub-backup process may be performed.
[0170]
Further, in the slot machine 1 of the present embodiment, the effect control board 201 executes the power backup, that is, the sub backup process is triggered by the detection of the voltage signal from the power monitoring means, the power cut command from the game control board 200, or the like. In the normal state, the sub-backup process is executed repeatedly at the time of a power failure even though the latest backup data exists based on the sub-backup process executed every time a command is received. Therefore, it is possible to reduce the processing load of the CPU 231.
[0171]
Although the embodiments of the present invention have been described with reference to the drawings, the present invention is not limited to these embodiments, and modifications and additions within the scope of the present invention are included in the present invention. Needless to say.
[0172]
For example, in the embodiment, the gaming state is backed up on the gaming control board 200 and the presentation state is backed up on the presentation control board 201 so that the next time the power is turned on, the gaming state and the production state at the time of power failure can be restored. However, the present invention is not limited to this, and the game state and effect state may be initialized when the power is turned off.
[0173]
In the above embodiment, the power monitoring IC 224 of the game control board 200 is configured to determine whether the power has been cut off. However, the present invention is not limited to this. For example, the power monitoring IC is connected to the power board 202. May be provided to determine the occurrence of power interruption.
[0174]
Further, in the above embodiment, it is determined that the power supply is cut off when the voltage supplied to the game control board 200 drops to a predetermined value of +7.2 V. However, the present invention is not limited to this. Instead, for example, when the voltage supplied to the power supply board 202 or the game control board 200 falls below a certain voltage for a predetermined period (for example, 20 ms), the occurrence of power interruption may be determined.
[0175]
In the embodiment, a normal slot machine capable of playing a game using medals and credits is used as a gaming machine. However, the present invention is not limited to this, and a game using a pachinko ball is used. It is also applicable to slot machines that perform gambling, complete credit type slot machines that can be played using credits without medals being discharged to the outside, and image type slot machines that display variable display devices as images Needless to say, the types of these gaming machines are not limited.
[0176]
Each element in the first embodiment corresponds to the present invention as follows.
[0177]
  Claim 1 of the present invention provides
  A gaming machine (slot machine 1) capable of executing a predetermined game (game),
  Control the gaming stateMain CPU (CPU 211)When,
  A main memory (RAM 212) used as a work memory of the main CPU (CPU 211);
  Control the productionSub CPU (CPU 231)When,
  A sub memory (RAM 232) used as a work memory of the sub CPU (CPU 231);
  A power-off determining means (power monitoring IC 224) for determining the occurrence of power-off when a predetermined power-off condition is satisfied;
  Initialization operation means (setting key switch 82) operated when initializing data stored in the main memory (RAM 212);
  With
  The main memory (RAM 212) has a main backup area (backup RAM area) in which main backup data for returning the gaming state is stored,
  The sub memory (RAM 232) includes a work area used as a work memory for the sub CPU (CPU 231) and a first sub backup area (a backup area for the RAM 232) in which sub backup data for returning the performance state is stored. 1) to 2), and a second sub-backup area (parity data storage area of the RAM 232) in which data for determining whether the data in the first sub-backup area is correct (parity data) is stored, and
  The main CPU (CPU 211)
  Control information transmission processing for transmitting, to the sub CPU (CPU 231), control information (command) that can specify the control state of the main CPU at that time according to the gaming state controlled by the main CPU (CPU 211);
  A main backup process for storing the main backup data in the main backup area (the backup RAM area of the RAM 212) when the power interruption determining means (the power monitoring IC 224) determines the occurrence of a power interruption;
  An initialization operation determination process for determining whether or not the initialization operation means (setting key switch 82) is operated when the power is turned on;
  Based on the main backup data stored in the main backup area (the backup RAM area of the RAM 212) when it is determined by the initialization operation determination process that the initialization operation means (setting key switch 82) is not operated. Gaming state return processing to return to the gaming state before power off,
  When it is determined that the initialization operation means (setting key switch 82) is operated by the initialization operation determination process, the main backup data stored in the main backup area (the backup RAM area of the RAM 212) is initialized. Main backup data initialization process,
  When the main backup data stored in the main backup area (the backup RAM area of the RAM 212) is initialized by the main backup data initialization process, specific control information (initialization) is given to the sub CPU (CPU 231). Command) to transmit specific control information,
  And
  The sub CPU (CPU 231)
  When the control information (command) transmitted from the main CPU (CPU 211) is received, an effect is executed to execute an effect corresponding to the control state of the main CPU (CPU 211) specified by the received control information (command). Execution process,
  Only when the control information (command) transmitted from the main CPU (CPU 211) is received, the first sub-backup area (backup areas 1-3 of the RAM 232) Sub-backup data update processing for updating the previous sub-backup data stored in the latest sub-backup data for returning to the effect state when the control information (command) is received,
  Each time the control information (command) transmitted from the main CPU (CPU 211) is received and the sub-backup process is performed, the data in the first sub-backup area (the backup areas 1 to 3 in the RAM 232) is used. Correctness determination data (parity data) is calculated, and the previous correctness determination data stored in the second sub-backup area (parity data storage area of the RAM 232) is calculated as the latest correctness determination data (parity). Data) for updating the correctness / incorrectness to be updated to (data),
  When the power is turned on, the first sub-backup area (the backup areas 1 to 3 of the RAM 232) is based on the correctness / incorrectness determination data (parity data) stored in the second sub-backup area (the parity data storage area of the RAM 232). ) To determine whether or not the data of the production state is normal,
  On the condition that it is determined to be normal by the effect state return availability determination process, based on the sub-backup data stored in the first sub-backup area (the backup areas 1 to 3 of the RAM 232) Production state return processing for returning to the production state;
  Specific control information reception determination processing for determining whether or not the specific control information (initialization command) is received from the main CPU (CPU 211) at power-on;
  And
  When the sub CPU (CPU 231) determines that the specific control information (initialization command) is received from the main CPU (CPU 211) in the specific control information reception determination process, the sub CPU (CPU 231) supplies power based on the sub backup data. Regardless of whether or not it is possible to return to the effect state before the interruption, based on the sub-backup data stored in the first sub-backup area (backup areas 1 to 3 of the RAM 232) by the effect state return process. Do not return to the production state before the power was turned off.
[0178]
  Claim 2 of the present invention provides
  In order to drive an IC that is mounted on the main control board (game control board 200) and is lower than the supply voltage (+ 8V) from the supply voltage (+ 8V) supplied to the main control board (game control board 200). Drive voltage generating means (DC-DC converter 223) for generating a drive voltage (+ 5V) of
  The drive voltage (+ 5V) generated by the drive voltage generating means (DC-DC converter 223) is used as a voltage for driving the main CPU (CPU 211), and the drive voltage (+ 5V) is used for the sub-control board. The drive voltage (+ 5V) supplied to the (effect control board 201) and supplied from the main control board (game control board 200) is used as a voltage for driving the sub CPU (CPU 231).
  The supply voltage (+ 8V)Main CPU (CPU 211)Is used as a voltage to drive the gaming peripheral device controlled by.
[0179]
  Claim 3 of the present invention provides
  In order to drive an IC that is mounted on the main control board (game control board 200) and is lower than the supply voltage (+ 8V) from the supply voltage (+ 8V) supplied to the main control board (game control board 200). Drive voltage generating means (DC-DC converter 223) for generating a drive voltage (+ 5V) of
  The drive voltage (+ 5V) generated by the drive voltage generation means (DC-DC converter 223) is a voltage for driving the main CPU (CPU 211) andSaidMain CPU (CPU 211)Used as a voltage to drive gaming peripherals controlled byAt the same time, the drive voltage (+ 5V) is also supplied to the sub control board (production control board 201), and the drive voltage (+ 5V) supplied from the main control board (game control board 200) is the sub CPU (CPU 231). ) Is used as a driving voltage.
[0180]
  Claim 4 of the present invention provides
  In order to drive an IC that is mounted on the main control board (game control board 200) and is lower than the supply voltage (+ 8V) from the supply voltage (+ 8V) supplied to the main control board (game control board 200). Drive voltage generating means (DC-DC converter 223) for generating a drive voltage (+ 5V) of
  The drive voltage (+ 5V) generated by the drive voltage generating means (DC-DC converter 223) is used as a voltage for driving the main CPU (CPU 211), and the drive voltage (+ 5V) is used for the sub-control board. The drive voltage (+ 5V) supplied to the (effect control board 201) and supplied from the main control board (game control board 200) is used as a voltage for driving the sub CPU (CPU 231).
  The drive voltage (+ 5V) supplied from the main control board (game control board 200) to the sub control board (production control board 201) is:Sub CPU (CPU 231)Is used as a voltage for driving a peripheral device for performance controlled by the.
[0186]
  Claims of the invention5SaidMain CPU (CPU 211)In the main backup process performed byMain backup dataTheIn the main backup area (the backup RAM area of the RAM 212)Process to save multiple.
  According to a sixth aspect of the present invention, a plurality of the same sub-backup data is stored in the first sub-backup area (the backup areas 1 to 3 of the RAM 232), and the sub-backup performed by the sub-CPU (CPU 231). In the data update process, all the previous sub-backup data stored in the first sub-backup area (backup areas 1 to 3 of the RAM 232) are updated to the latest sub-backup data.
[0187]
(Example 2)
A second embodiment of the present invention will be described with reference to the drawings. FIG. 19 is a front view of a pachinko machine 600 that is an example of a gaming machine to which the present invention is applied.
[0188]
As shown in FIG. 19, the pachinko machine 600 has a glass door frame 602 formed in a frame shape. There is a hitting ball supply tray 603 on the lower surface of the glass door frame 602. Under the hitting ball supply tray 603, there are provided an extra ball receiving tray 604 for storing premium balls overflowing from the hitting ball supply tray 603 and a hitting operation handle (operation knob) 605 for firing the hitting ball. A game board 606 is detachably attached to the rear of the glass door frame 602. A game area 607 is provided on the front surface of the game board 606.
[0189]
Near the center of the game area 607, a variable display device 608 including a variable display portion 609 for variably displaying a plurality of types of symbols and a variable display 610 using 7 segment LEDs is provided. In this embodiment, the variable display portion 609 has three symbol display areas of “left”, “middle”, and “right”. A passing gate 611 for guiding a hit ball is provided on the side of the variable display device 608. The hit ball that has passed through the passage gate 611 is guided to the start winning opening 614 through the ball outlet 613. In the path between the passing gate 611 and the ball outlet 613, there is a gate switch 612 (see FIG. 20) that detects a hit ball that has passed through the passing gate 611. Also, the winning ball that has entered the start winning opening 614 is led to the back of the game board 606 and detected by the start opening switch 617 (see FIG. 20). A variable winning ball device 615 that opens and closes is provided below the start winning opening 614. The variable winning ball device 615 is opened by a solenoid 616 (see FIG. 20).
[0190]
An open / close plate 620 that is opened by a solenoid 621 (see FIG. 20) in a specific gaming state (big hit state) is provided below the variable winning ball device 615. Of the winning balls guided from the opening / closing plate 620 to the back of the game board 606, the winning ball entering one (V zone) is detected by the V count switch 622 (see FIG. 20). The winning ball from the opening / closing plate 620 is detected by a count switch 623 (see FIG. 20). At the bottom of the variable display device 608, a start winning memory display 618 having four display portions for displaying the number of winning balls that have entered the start winning opening 614 is provided. In this embodiment, with the upper limit being four, every time there is a start prize, the start prize storage display 618 increases the number of lit display units one by one. Each time variable display on the variable display unit 609 is started, the number of display units that are lit is reduced by one.
[0191]
The game board 606 is provided with a plurality of winning ports 619 and 624, and winning of the game balls to the winning ports 619 and 624 is detected by winning port switches 619a and 624a (see FIG. 20). Decorative lamps 625 blinking and displayed during the game are provided around the left and right sides of the game area 607, and an outlet 626 for collecting the hit balls that have not won is provided at the bottom. Two speakers 627 that emit sound effects are provided on the left and right upper portions outside the game area 607. On the outer periphery of the game area 607, a game effect LED 628a and game effect lamps 628b and 628c are provided.
[0192]
A prize ball lamp 651 that is turned on when the prize ball is paid out is provided on the left side outside the game area 607, and a ball break lamp 652 that is turned on when the supply ball is cut is provided on the right side. Further, FIG. 19 also shows a card unit 700 that is installed adjacent to the pachinko machine 600 and allows a ball lending by inserting a prepaid card.
[0193]
In the card unit 700, a usable indication lamp 751 indicating whether or not the card is in a usable state, and when the remaining amount information recorded in the prepaid card has a fraction (a number less than 100 yen), the fraction is indicated as a hitting tray. A fraction display switch 752 for displaying on a frequency display LED provided in the vicinity of 603, a connection table direction indicator 753 indicating which side of the pachinko machine 600 corresponds to the left or right side of the card unit 700, in the card unit 700 A card insertion display lamp 754 indicating that a prepaid card is inserted, a card insertion slot 755 into which a prepaid card as a recording medium is inserted, and a card reader / writer mechanism provided on the back surface of the card insertion slot 755. A card unit lock 756 is provided to release the card unit 700 for inspection. It has been.
[0194]
The hit ball fired from the hit ball launching device enters the game area 607 through the hit ball rail, and then descends the game area 607. When the hit ball is detected by the gate switch 612 through the passing gate 611, the display number of the variable display 610 is continuously changed. Further, when the hit ball enters the start winning opening 614 and is detected by the start opening switch 617, the symbol in the variable display portion 609 starts rotating if the variation of the symbol can be started. If it is not in a state where the change of the symbol can be started, the start winning memory is increased by one.
[0195]
The rotation of the image in the variable display unit 609 stops when a certain time has elapsed. If the combination of images at the time of the stop is a combination of jackpot symbols, the game shifts to a jackpot gaming state. That is, the opening / closing plate 620 is opened until a predetermined time elapses or a predetermined number (for example, 10) of hit balls wins. When the hit ball enters the specific winning area while the opening / closing plate 620 is opened and is detected by the V count switch 622, a continuation right is generated and the opening / closing plate 620 is opened again. The generation of the continuation right is allowed a predetermined number of times (for example, 15 rounds).
[0196]
When the combination of images in the variable display unit 609 at the time of stoppage is a combination of jackpot symbols with probability fluctuations, the probability of the next jackpot increases. That is, it becomes a more advantageous state for the player in a high probability state. Further, when the stop symbol on the variable display 610 is a predetermined symbol (winning symbol), the variable winning ball device 615 is opened for a predetermined time. Further, in the high probability state, the probability that the stop symbol in the variable display 610 becomes a winning symbol is increased, and the opening time and the number of times of opening of the variable winning ball device 615 are increased.
[0197]
In this embodiment, the operation of turning on the power while pressing the reset button (not shown) provided on the back surface of the pachinko machine 600 detects that a reset switch 629 (see FIG. 20), which will be described later, is on, and the gaming state Initialization, that is, initialization of the contents stored in the RAM 212, and detection of the setting switch 630 (see FIG. 20) by operating a setting button (not shown) provided in the vicinity of the reset button becomes effective. By operating this setting button, the jackpot lottery probability for determining whether or not to shift to the aforementioned jackpot gaming state, that is, the change of the payout rate by control can be executed. That is, the operation of turning on the power while the reset button is pressed functions as the operation of clearing the main memory and the operation of setting the payout rate in the present invention.
[0198]
FIG. 20 is a block diagram showing a configuration of the pachinko machine 600. The pachinko machine 600 according to the present embodiment has a game control board (main board) 631 on which a game control microcomputer for controlling a game state is mounted, a prize ball control for performing a prize ball payout control by a ball payout device 697, and the like. A prize ball control board 638 on which a microcomputer (basic circuit) 653 is mounted, a variable display control board 680 on which a variable display control microcomputer 681 (see FIG. 21) for controlling the variable display unit 609 is mounted, a speaker Sound control board 670 on which sound control microcomputer 671 (see FIG. 21) for controlling sound output from 627 is mounted, lighting of game effect lamps / LEDs 628a, 628b, 628c, prize ball lamp 651 and out-of-ball lamp 652 A lamp control microcomputer 636 (see FIG. 21) for controlling the state is mounted. Flop control board 635, and a firing control board 691 on which a circuit is provided for controlling the driving of the ball firing motor 694 in response to the detection status of the operation knob 605.
[0199]
Of these boards, the main board 631 is a board for controlling the gaming state. That is, it corresponds to the main control board of the present invention. In addition, the variable display control board 680, the sound control board 670, and the lamp control board 635 are outputs of variable display devices, speakers, lamps, and the like, which are the peripheral devices for presentation in accordance with the gaming state controlled by the main board 631. It is a board that controls the state and controls the effect state according to the gaming state. That is, it corresponds to the sub-control board of the present invention.
[0200]
The main board 631 includes a basic circuit 653 for controlling the pachinko machine 600 according to a program, a switch circuit 658 for giving an input signal from a switch connected to the main board 631 to the basic circuit 653, and a solenoid connected to the main board 631. Are mounted according to a command from the basic circuit 653, and a lamp connected to the main board 631 and a lamp / LED circuit 660 for driving the LED.
[0201]
Further, according to the data given from the basic circuit 653, the jackpot information indicating the occurrence of the jackpot, the effective start information indicating the number of start winning balls used for starting the image display of the variable display unit 609, and the fact that the probability variation has occurred. An information output circuit 664 for outputting probability variation information and the like to a host computer such as a hall management computer is included.
[0202]
The basic circuit 653 includes a ROM 654 that stores a game control program and the like, a RAM 655 as a main memory used as a work memory, a CPU 656 as a main CPU that performs a control operation in accordance with the control program, and an I / O port 657. .
[0203]
In addition, the RAM 655 included in the basic circuit 653 of the present embodiment is similar to the RAM 212 (see FIG. 6) included in the control unit 210 of the game control board 200 of the first embodiment described above, and the work area, the backup areas 1 to 3 and a parity data storage area, of which the work area is a non-backup RAM area, and the backup areas 1 to 3 and the parity data storage area are backup RAM areas.
[0204]
Further, the main board 631 is provided with an initial reset circuit 665 for resetting the basic circuit 653 when power is turned on, and any one of the I / O ports 657 by decoding an address signal given from the basic circuit 653. An address decode circuit 667 for outputting a signal for selection is provided.
[0205]
From the main board 631 to the prize ball control board 638, a prize ball control command for instructing payout of prize balls and the like is output via a buffer circuit (not shown). In addition, from the main board 631 to the variable display control board 680, the sound control board 670, and the lamp control board 635, various commands and initial stage of the production state that can specify the game state controlled by the basic circuit 653 via the buffer circuit described above. An initialization command (initialization instruction) for instructing initialization is output. The buffer circuit functions to allow a signal to be output from the inside of the main board 631 to the outside, but to prevent a signal from being input from the outside to the inside of the main board 631. Therefore, one-way communication from the main board 631 to the external board is ensured between the main board 631 and the external board, and illegal control is performed by inputting a signal to the main board 631 through the command transmission path. It is possible to prevent fraudulent acts that cause movement.
[0206]
The prize ball control microcomputer mounted on the prize ball control board 638 drives the ball payout device 697 based on the prize ball control command transmitted from the main board 631, and pays out the designated number of prize balls. To do.
[0207]
The prize ball control board 638 is connected to the adjacent card unit 700 so as to be capable of two-way communication. The prize ball control microcomputer drives the ball payout device 697 based on a ball rental request from the card unit 700. Then, the required number of game balls are lent out.
[0208]
As shown in FIG. 21, the variable display control board 680 is equipped with a variable display control microcomputer 681 and a display drive circuit 682 for controlling the display of the liquid crystal display constituting the variable display unit 609. Yes.
[0209]
The variable display control microcomputer 681 includes a CPU 681a as a sub CPU, a RAM 681b as a sub memory, a ROM 681c, and an I / O port 681d.
[0210]
The ROM 681c stores a character table that defines a variable display pattern corresponding to the command transmitted from the main board 631, and the CPU 681a sends a command indicating the winning status of the big win lottery executed at the time of starting winning a prize to the main board 631. Is received, the variable display pattern corresponding to the winning situation specified by the command is extracted, and variable display control based on the extracted variable display pattern is performed.
[0211]
On the sound control board 670, a sound control microcomputer 671 and a sound drive circuit 672 for driving the speaker 627 are mounted.
[0212]
The sound control microcomputer 671 includes a CPU 671a as a sub CPU, a RAM 671b as a sub memory, a ROM 671c, and an I / O port 671d.
[0213]
The ROM 671c stores an audio table that defines an output pattern corresponding to a command transmitted from the main board 631. When the CPU 671a receives a command indicating a predetermined gaming state from the main board 631, the command is displayed. An output pattern corresponding to the gaming state specified by is extracted, and voice output control is performed based on the extracted output pattern.
[0214]
The lamp control board 635 is equipped with a lamp control microcomputer 636, a game effect lamp / LEDs 628 a, 628 b, 628 c, a prize ball lamp 651, and a lamp driving circuit 637 for driving the ball-out lamp 652. .
[0215]
The lamp control microcomputer 636 includes a CPU 636a as a sub CPU, a RAM 636b as a sub memory, a ROM 636c, and an I / O port 636d.
[0216]
The ROM 636c stores a lamp control table that determines a lighting pattern corresponding to a command transmitted from the main board 631. When the CPU 636a receives a command indicating a predetermined gaming state from the main board 631, A lighting pattern corresponding to the gaming state specified by the command is extracted, and lighting control of the lamps / LEDs 628a, 628b, 628c, the prize ball lamp 651 and the ball-out lamp 652 is performed based on the extracted lighting pattern.
[0217]
Further, the RAMs 681a, 671a, and 636a of the variable display control microcomputer 681, the sound control microcomputer 671, and the lamp control microcomputer 636 are the RAM 232 included in the control unit 230 of the effect control board 201 of the first embodiment. As in FIG. 6, the work area, backup areas 1 to 3, and parity data storage area are configured. Of these, the work area is a non-backup RAM area, and the backup areas 1 to 3 and the parity are stored. The data storage area is a backup RAM area.
[0218]
FIG. 22 is a block diagram showing the configuration of the power supply board 910 of the pachinko machine 600. The power supply board 910 is installed independently of control boards such as the main board 631, the variable display control board 680, the sound control board 670, the lamp control board 635, and the prize ball control board 638, and each control board in the pachinko machine 600 and Generates voltage used by mechanical components. In this embodiment, AC24V, DC + 30V, DC + 21V, DC + 12V and DC + 8V are generated.
[0219]
The transformer 911 converts AC voltage from the AC power source into AC 24V. The AC 24V voltage is output to the connector 915. Further, the rectifier circuit 912 generates a DC voltage of +30 V from AC 24 V and outputs it to the DC-DC converter 913 and the connector 915. The DC-DC converter 913 generates + 21V, + 12V, and + 8V and outputs them to the connector 915. The connector 915 is connected to, for example, a relay board, and power of a voltage necessary for each control board and mechanism component is supplied from the relay board. A power switch (not shown) for stopping or starting the power supply to the pachinko machine 600 is installed on the input side of the transformer 911.
[0220]
In this embodiment, an AC voltage of 24 V AC is supplied to the prize ball control board 638 and used as a voltage for transmitting and receiving signals between the pachinko machine 600 and the card unit 700. The + 8V DC voltage is supplied to the prize ball control board 638 and the launch control board 691 and used as a driving voltage for the ball dispensing device 697 and the drive motor 604, and is also supplied to the main board 631 to be used as the main board 631. In addition, it is directly or indirectly connected to a main power source 631 or a main power source for driving each device mounted on the prize ball control board 638, the variable display control board 680, the sound control board 670, and the lamp control board 635. Used as a driving voltage for switches, sensors, lamps, solenoids, and indicators. The + 12V DC voltage is supplied to the variable display control board 680 via the main board 631 and used as a driving voltage for the liquid crystal display. The + 21V DC voltage is supplied to the sound control board 670 and the lamp control board 635 via the main board 631 and used as a driving voltage for the lamp, LED, and speaker.
[0221]
As described above, in this embodiment, the voltage supplied to the main board 631 to drive the devices mounted on the main board 631, the prize ball control board 638, the variable display control board 680, the sound control board 670, and the lamp control board 635. Is used as a driving voltage for peripheral devices for games such as switches, sensors, lamps, solenoids, indicators, etc., which are directly or indirectly connected to the main board 631. Since it is not necessary to separately introduce the driving voltage of the game peripheral device, the configuration of the pachinko machine 600 can be simplified.
[0222]
FIG. 23 is a circuit diagram showing a configuration example around the CPU 656 in the main board 631. As shown in FIG. 23, + 8V output from the power supply board 910 is supplied to the DC-DC converter 902. The DC-DC converter 921 generates +5 V and outputs it to the CPU 656, the RAM 655, and the power supply monitoring IC 902. This + 5V is used as a drive voltage for these devices. Further, + 5V generated by the DC-DC converter 921 is output to the variable display control board 680, the sound control board 670, and the lamp control board 635, and as described later, as a drive voltage for devices mounted on these boards. used.
[0223]
In the present embodiment, as described above, +8 V as the supply voltage supplied to the DC-DC converter 902 is used as the drive voltage of the game peripheral device. Without being limited, + 5V as the drive voltage generated by the DC-DC converter 902 may be used as the drive voltage of these game peripheral devices. By adopting such a configuration, It is not necessary to introduce a driving voltage for the gaming peripheral device separately, and it is not necessary to provide a generating means for generating a voltage used as a driving voltage for the gaming peripheral device separately from the DC-DC converter 902. Therefore, the configuration of the pachinko machine 600 can be simplified.
[0224]
The + 5V line from the DC-DC converter 921 branches to form a main backup + 5V line. A large-capacitance capacitor 923 is connected between the main backup + 5V line and the ground level. The capacitor 923 serves as a backup power source that supplies a voltage to the RAM 655 so that the storage state of the backup RAM area can be maintained when the voltage supply to the pachinko machine 600 is cut off. Further, a backflow preventing diode 922 is inserted between the + 5V line and the main backup + 5V line. As a backup power source, a battery that can be charged from a + 5V power source may be used.
[0225]
The power monitoring IC 902 introduces a voltage of + 8V output from the power supply board 910, that is, a voltage that is a source of a driving voltage of the CPU 656 that controls the devices of the main board 631, particularly each part, and monitors this + 8V voltage. To detect the occurrence of power interruption. In this embodiment, when the + 8V voltage becomes a predetermined value or less, a voltage drop signal is output. This voltage drop signal is input to the non-maskable interrupt terminal (NMI terminal) of the CPU 656. That is, the CPU 656 can confirm the occurrence of power interruption by an interrupt process based on the input of the voltage drop signal from the power monitoring IC 902.
[0226]
Note that the voltage for the power monitoring IC 902 to detect power-off is a voltage higher than the normal operating voltage of the CPU 656, and in this embodiment, the occurrence of power-off is detected when the voltage drops to + 7.2V. . The power monitoring IC 902 is configured to monitor a voltage higher than a voltage for driving the CPU 656 (+5 V in this embodiment), that is, a voltage of +8 V supplied to the DC-DC converter 921. The monitoring range can be expanded for the voltage required by the CPU 656, and more precise monitoring can be performed.
[0227]
In this embodiment, the CPU 656, the RAM 655, and the power supply monitoring IC 902 are driven with a power supply voltage of + 5V in a normal state, and the power supply monitoring IC 902 has a voltage higher than + 5V that drives these devices. When the voltage drops to + 7.2V, a voltage drop signal is output. Since a + 5V voltage is supplied to a device such as the CPU 656 for a while after the occurrence of a power interruption is detected, the voltage drops. Based on the input of the signal, the CPU 656 can sufficiently secure the time necessary for performing the main power failure interruption process described later.
[0228]
In the case of the present embodiment, the time required until the CPU 656 of the main board 631 receives the voltage drop signal and completes the main power failure interrupt processing is about 2 ms, whereas the main board 631 The time until the + 8V voltage supplied to 631 drops to + 7.2V and then to + 5V, that is, the time until the drive voltage of the CPU 656 starts to drop after the detection of the power failure is about 100 ms. Note that the present invention is not limited to this, and is set to a time at which the drive voltage of the CPU 656 in the main board 631 can be held until the main power failure interruption process is completed at least when a power interruption occurs. It ’s fine.
[0229]
In this embodiment, the power monitoring IC 902 monitors the voltage that is the source of the driving voltage of the CPU 656, that is, the voltage of +8 V supplied to the DC-DC converter 921 to generate +5 V that drives the CPU 656. Since a stable voltage is monitored compared to a drive voltage that tends to go up and down depending on the drive status of each device, the occurrence of power interruption is determined with a temporary voltage drop, which will be described later. It is possible to prevent malfunction such as interruption processing at the time of main power failure.
[0230]
The present invention is not limited to this, and a voltage that is a source of a power supply voltage for driving gaming peripheral devices such as switches, sensors, lamps, and displays connected to the main board 631, for example, In order to generate + 12V and + 21V for driving these gaming peripheral devices, the voltage supplied to the DC-DC converter 913 may be introduced and monitored, and depending on the driving status of these gaming peripheral devices. Since a stable voltage is monitored in comparison with a drive voltage that tends to go up and down, the occurrence of a power interruption is determined with a temporary voltage drop, and a main power failure interruption process described later is performed. Etc. can be prevented from malfunctioning.
[0231]
FIG. 24 is a block diagram showing a configuration around the CPU for power monitoring and power backup in the variable display control board 680, the sound control board 670, and the lamp control board 635. Since the configuration around the CPU for power supply monitoring and power supply backup in each of these control boards is substantially the same, here, the variable display control board 680 will be described as an example.
[0232]
As shown in FIG. 24, +5 V generated by the DC-DC converter 902 of the main board 631 is supplied to the variable display control board 680 and used as a driving voltage for the CPU 681a and the RAM 681b.
[0233]
In the present embodiment, as described above, the power supply voltage is used as the driving voltage for the peripheral devices for production such as the variable display control board 680, the sound control board 670, and the lamp, LED, speaker, liquid crystal display, etc. controlled by the lamp control board 635. Although + 12V and + 21V voltages supplied from the substrate 910 via the main substrate 631 are used, the present invention is not limited to this, and as drive voltages for these staging peripheral devices, + 5V as the driving voltage supplied from the main board 631 may be used. With such a configuration, it is not necessary to separately introduce the driving voltage of the peripheral device for presentation, so the pachinko machine 600 The configuration can be simplified.
[0234]
The + 5V line from the main board 631 branches to form a sub-backup + 5V line. A large-capacitance capacitor 925 is connected between the sub-backup + 5V line and the ground level. The capacitor 925 serves as a backup power source that supplies a voltage so that the storage state of the backup RAM area can be maintained for the RAM 681b when the voltage supply to the pachinko machine 600 is cut off. Further, a backflow preventing diode 924 is inserted between the + 5V line and the sub-backup + 5V line. As a backup power source, a battery that can be charged from a + 5V power source may be used.
[0235]
In this embodiment, the voltage at which the power monitoring IC 902 of the main board 631 outputs a voltage drop signal, that is, the voltage (+ 7.2V) that triggers the CPU 656 of the main board 631 to stop operating is variably displayed. The drive voltage of the CPU 681a and the RAM 691b of the control board 680 is set higher than the drive voltage (+5 V in this embodiment), so that the main board 631 stops operating at an earlier stage than the variable display control board 680 in the event of a power failure. In other words, even if the operation of the main board 631 stops, the variable display control board 680 can operate for a while, so that the variable display control board 680 can reliably receive various commands transmitted from the main board 631. At the same time, as will be described later, the sub-display performed by the CPU 681a of the variable display control board 680 is triggered by receiving various commands. It is possible to execute the backup process more reliably.
[0236]
In the case of the present embodiment, the time required from the CPU 656 of the main board 631 receiving the voltage drop signal to the completion of the main power failure interruption process is about 2 ms, whereas the power supply is cut off. After the detection, the time until the drive voltage of the CPU 681a of the variable display control board 680 starts to drop is about 100 ms. The time required for the CPU 681a of the variable display control board 680 to receive various commands from the main board 631 and execute a sub-backup process described later is about 16 ms. Therefore, even if the operation of the main board 631 stops after the variable display control board 680 receives a command from the main board 631 immediately before the occurrence of the power interruption, the CPU 681a of the variable display control board 680 operates due to the voltage drop. Thus, the sub-backup process can be surely executed before the system stops.
[0237]
Next, various control contents executed by the CPU 656 mounted on the main board 631 in this embodiment will be described below. The control contents of the CPU 656 are almost the same as the control contents other than the game control process (see FIGS. 10 to 13 and 15) among the control contents performed by the CPU 211 of the above-described embodiment, and will be described briefly here. .
[0238]
When the power is turned on, the CPU 656 first checks whether the power is turned on based on an operation for changing the set value or initializing the game state, that is, whether the reset switch 629 is on. When the reset switch 629 is on, a main initialization process is executed as a game information initialization execution process for initializing the gaming state, and a setting change process that can change the setting value of the jackpot probability Execute.
[0239]
In the main initialization process, a command transmission process for transmitting an initialization command to the variable display control board 680, the sound control board 670, and the lamp control board 635 is performed. By transmitting the initialization command, the effect state controlled by the variable display control board 680, the sound control board 670, and the lamp control board 635 is also initialized.
[0240]
If the reset switch 629 is off when the power is turned on, it is confirmed whether or not the power supply is restored from a power failure.
[0241]
In the case of recovery from a power failure, the backup RAM area data in the RAM 655 is checked and the main backup data in the backup areas 1 to 3 is compared to determine whether at least two main backup data match. Check if correct data is backed up.
[0242]
If these results are normal, all the registers are restored from the main backup data in the backup area in the RAM 655, and the routine returns to the routine before power-off. That is, the game state is restored when the power is turned off.
[0243]
Further, if the result of the data check and the comparison result are not normal, the gaming state cannot be returned to the state when the power is turned off, so the main initialization process is executed to initialize the gaming state. Even when it is confirmed that the power failure is not restored, the main initialization process is executed.
[0244]
When the above-described setting change process is completed or when the main initialization process is completed, the above-described update process of the random number value used for the big hit lottery and the timer interrupt process executed every predetermined period (2 ms in this embodiment) The presence or absence of the timer interrupt flag set by the above is confirmed, and if the timer interrupt flag is set, the process proceeds to a loop process that repeatedly executes the game control process.
[0245]
Further, when a power failure occurs and an NMI based on a voltage drop signal from the power supply monitoring IC 902 is input, a main power failure interrupt process is executed. In the main power failure interrupt process, the contents of each register, that is, main backup data as game information that can specify the game state at that time is stored in the backup RAM areas 1 to 3 of the RAM 655, and the entire backup RAM area Parity data is generated based on the data and stored in the parity data storage area. At this time, the same main backup data is stored in the backup RAM areas 1 to 3. This makes it possible to more reliably back up the gaming state during a power failure.
[0246]
Next, various control contents executed by the CPUs 681a, 671a, and 636a mounted on the variable display control board 680, the sound control board 670, and the lamp control board 635 in the present embodiment will be described below. Note that the control contents of the CPUs 681a, 671a, and 636a are almost the same as the control contents (FIGS. 16 to 18) performed by the CPU 231 of the above embodiment, and will be described briefly here.
[0247]
When the power is turned on, the CPUs 681a, 671a, and 636a first check whether backup data is stored. When the backup data is stored, it waits in a state of waiting for reception of the initialization command transmitted from the main board 631 until the command reception waiting time elapses.
[0248]
If the initialization command is not received even after the command reception waiting time elapses, the backup RAM area data is checked in the RAMs 681b, 671b, and 636b, and the sub-backup data in the backup areas 1 to 3 are compared, and at least 2 It is confirmed whether correct data is backed up based on whether the two sub-backup data match.
[0249]
If these results are normal, all the registers are restored from the sub-backup data in the backup area in the RAMs 681b, 671b, and 636b, and the process returns to the routine before power-off. That is, the production state is restored when the power is turned off.
[0250]
If the result of the data check and the comparison result are not normal, the effect state cannot be returned to the state when the power is turned off, so the sub-initialization process is executed to initialize the effect state. Even when it is confirmed that the backup data is not saved, the sub-initialization process is executed.
[0251]
In the sub-initialization process, the output state of the display, lamp, speaker, and the like controlled by the variable display control board 680, the sound control board 670, and the lamp control board 635 is set as the initial state. That is, with the initialization of the registers and RAMs 681b, 671b, and 636b, the output state of the production peripheral device is also initialized.
[0252]
When the sub-initialization process is completed, a state of waiting for reception of various commands transmitted from the main board 631 is entered, and each time a command is received from the main board 631, a sub-backup process for storing the current presentation state as sub-backup data. After executing, a loop that controls the output state of various peripheral devices such as various lamps, indicators, speakers, etc. according to the gaming state specified by the received command, and executes effect control processing for performing various effects Transition to processing.
[0253]
In the sub-backup process that is executed each time a command indicating a gaming state is received from the main board 631, the contents of each register, that is, sub-backup data as presentation information that can specify the presentation state at that time are stored in the RAMs 681b, 671b, and 636b. Are stored in the backup RAM areas 1 to 3, and parity data is generated based on the data in the entire backup RAM area and stored in the parity data storage area. At this time, the same main backup data is stored in the backup RAM areas 1 to 3. This makes it possible to more reliably back up the gaming state during a power failure.
[0254]
As described above, in the pachinko machine 600 of the present embodiment, the + 5V voltage generated by the DC-DC converter 921 is used as a voltage for driving the CPU 656 of the main board 631, and the same + 5V voltage is variably displayed. Since it is also used as a voltage for driving the CPUs 681a, 671a, 636a of the control board 680, the sound control board 670, and the lamp control board 635, the voltage for driving the CPUs 681a, 671a, 636a is higher than the voltage for driving the CPU 656. Therefore, it is possible to prevent malfunction and damage of the CPU mounted on each board.
[0255]
In the pachinko machine 600 according to the present embodiment, the variable display control board 680, the sound control board 670, and the presentation state controlled by the lamp control board 635 are the variable display control board 680, the sound control board 670, the RAMRAM 681b of the lamp control board 635, 671b and 636b are backed up, and it is not necessary to back up the information about the production state in the main board 631, so that the burden on the backup capacity of the main board 631 can be greatly reduced.
[0256]
Further, when the game state is initialized by initializing the register and RAM 655 on the main board 631 after the power is turned on, an initialization command is transmitted to the variable display control board 680, the sound control board 670, and the lamp control board 635. In addition, the variable display control board 680, the sound control board 670, and the lamp control board 635 also initialize the register and the RAMs 681b, 671b, and 636b to initialize the presentation state, so that the consistency of each board can be achieved. At the same time, when the variable display control board 680, the sound control board 670, and the lamp control board 635 can be restored to the effect state before the power is turned off after the power is turned on, the sub-backup data stored in the RAMs 681b, 671b, 636b is stored. Therefore, the variable display control board 680 and the sound control board 67 can be restored to the effect state before the power is turned off. The lamp control board 635 can be independently restored without receiving an instruction from the main board 631, and the variable display control board 680, the sound control board 670, and the lamp control board 635 can be restored without imposing a burden on the main board 631. Can be made.
[0257]
Further, in the pachinko machine 600 according to the present embodiment, when an operation for setting a big hit probability, that is, a payout rate is performed, a main initialization process is performed on the main board 631, and a variable display control board 680 is accordingly accompanied. Since the initialization command is transmitted to the sound control board 670 and the lamp control board 635, the sub-initialization process is also performed on the variable display control board 680, the sound control board 670, and the lamp control board 635. When the set value is changed, the main board 631, the variable display control board 680, the sound control board 670, and the lamp control board 635 can all be returned to the initial state, and the consistency of each board can be achieved.
[0258]
Further, in the pachinko machine 600 according to the present embodiment, when an operation for initializing the gaming state is performed, the main substrate 631 performs a main initialization process, and accordingly, the variable display control substrate 680, Since an initialization command is transmitted to the sound control board 670 and the lamp control board 635, the sub-initialization process is also performed on the variable display control board 680, the sound control board 670, and the lamp control board 635. When the state initialization operation is performed, all of the main board 631, the variable display control board 680, the sound control board 670, and the lamp control board 635 can be returned to the initial state, and the consistency of each board is achieved. be able to.
[0259]
Further, in the pachinko machine 600 according to the present embodiment, when the game state controlled by the main board 631 can be returned to the state before the power is turned off when the power is turned on, the state is automatically returned to the state before the power is turned off. Thus, since it is not necessary to perform an extra operation, it is possible to easily return the gaming state.
[0260]
In the pachinko machine 600 according to the present embodiment, when the game state controlled by the main board 631 cannot be restored to the state before the power is turned off when the power is turned on, the fact is displayed on the variable display unit 609 as an error code. Thus, it is possible to notify the outside that an error has occurred, and it is possible to respond quickly. In the present embodiment, error notification is performed in the variable display unit 609. However, the present invention is not limited to this. For example, an error occurrence is displayed on another display. Alternatively, the occurrence of an error may be notified by turning on a lamp or outputting a notification sound.
[0261]
In the pachinko machine 600 according to the present embodiment, when the sub-initialization process is performed on the variable display control board 680, the sound control board 670, and the lamp control board 635, the registers and the RAMs 681b, 671b, and 636b are initialized. In addition, the output state of the display peripherals such as the display, lamps, and speakers controlled by the variable display control board 680, the sound control board 670, and the lamp control board 635 is set to the initial state. The main board 631 can control the output state of the production peripheral device to the initial state only by transmitting the initialization command to the variable display control board 680, the sound control board 670, and the lamp control board 635.
[0262]
In the pachinko machine 600 according to the present embodiment, the variable display control board 680, the sound control board 670, and the lamp control board 635 receive the command as the production control information from the main board 631 as an opportunity. The sub-backup process for saving the state is executed, and the sub-backup process is performed in response to the reception of a command that triggers the production. Therefore, the variable display control board 680, the sound control board 670, the lamp control The substrate 635 can be backed up reliably.
[0263]
The present invention is not limited to this, and at least a predetermined trigger other than when the power is turned off, for example, the sub-backup process may be executed by an interrupt process executed at predetermined intervals. The sub-backup process may be executed when a specific effect is executed.
[0264]
In the pachinko machine 600 according to the present embodiment, the sub-backup process is executed each time the variable display control board 680, the sound control board 670, and the lamp control board 635 receive a command as effect control information from the main board 631. Thus, it is possible to more reliably back up the presentation state performed by the variable display control board 680, the sound control board 670, and the lamp control board 635.
[0265]
The present invention is not limited to this. For example, when a command indicating a specific gaming state is received or each time a command is received a predetermined number of times, the sub-backup process may be performed.
[0266]
In the pachinko machine 600 according to the present embodiment, the variable display control board 680, the sound control board 670, and the lamp control board 635 are turned off, that is, the voltage signal is detected from the power supply monitoring unit, and the power supply from the main board 631 is turned off. The sub-backup process is not executed in response to a command, etc., and the sub-backup process that is executed every time a command is received is normally sub- Since it is possible to reduce unnecessary processing such as executing backup processing redundantly, the processing load on the CPUs 681a, 671a, and 636a can be reduced.
[0267]
As described above, the second embodiment of the present invention has been described with reference to the drawings. However, the present invention is not limited to these embodiments, and modifications and additions within the scope of the present invention are included in the present invention. Needless to say.
[0268]
For example, in the above-described embodiment, the game state is backed up on the main board 631, and the presentation state is backed up on the variable display control board 680, the sound control board 670, and the lamp control board 635. However, the present invention is not limited to this, and the game state and the production state may be initialized by turning off the power.
[0269]
In the above-described embodiment, the power monitoring IC 902 of the main board 631 is configured to determine whether the power is cut off. However, the present invention is not limited to this, and for example, the power monitoring IC is attached to the power board 910. It may be provided to determine the occurrence of power interruption.
[0270]
In the above embodiment, it is determined that the power supply has been cut off when the voltage supplied to the main board 631 drops to a predetermined value of +7.2 V. However, the present invention is not limited to this. For example, when the voltage supplied to the power supply substrate 910 or the main substrate 631 is equal to or lower than a certain voltage for a predetermined period (for example, 20 ms), the occurrence of power interruption may be determined.
[0271]
Further, in the above embodiment, a normal pachinko machine capable of performing a game using a pachinko ball is used as a gaming machine, but the present invention is not limited to this, and an enclosure in which the pachinko ball circulates is used. Needless to say, the present invention can be applied to a pachinko machine of an image type, and further to an image-type pachinko machine, and the type of these gaming machines is not limited.
[0272]
Each element in the second embodiment corresponds to the present invention as follows.
[0273]
  Claim 1 of the present invention provides
  A gaming machine (pachinko machine 600) capable of executing a predetermined game (game),
  Control the gaming stateMain CPU (CPU 656)When,
  A main memory (RAM 655) used as a work memory of the main CPU (CPU 656);
  Control the productionSub CPU (CPU 681a, 671a, 636a)When,
  A sub memory (RAM 681b, 671b, 636b) used as a work memory of the sub CPU (CPU 681a, 671a, 636a);
  A power-off determining means (power monitoring IC 902) for determining the occurrence of a power-off when a predetermined power-off condition is satisfied;
  Initialization operation means (reset switch 630) operated when initializing data stored in the main memory (RAM 655);
  With
  The main memory (RAM 655) has a main backup area (a backup RAM area of the RAM 655) in which main backup data for returning the gaming state is stored.
  The sub memory (RAM 681b, 671b, 636b) stores a work area used as a work memory of the sub CPU (CPU 681a, 671a, 636a) and a first backup data for returning the production state. A second sub-backup area (RAM 681b, 671b) in which the sub-backup area (the backup areas 1 to 3 of the RAMs 681b, 671b, 636b) and the data for parity determination (parity data) of the data in the first sub-backup area are stored. , 636b parity data storage area), and
  The main CPU (CPU 656)
  Control information for transmitting to the sub CPUs (CPUs 681a, 671a, 636a) control information (commands) that can specify the control state of the main CPU at that time according to the gaming state controlled by the main CPU (CPU 656). Send processing and
  A main backup process for storing the main backup data in the main backup area (a backup RAM area of the RAM 655) when the power interruption determining means (the power monitoring IC 902) determines the occurrence of a power interruption;
  An initialization operation determination process for determining whether or not the initialization operation means (reset switch 630) is operated at power-on;
  Based on the main backup data stored in the main backup area (the backup RAM area of the RAM 655) when it is determined that the initialization operation means (reset switch 630) is not operated by the initialization operation determination process. A game state return process for returning to the game state before power-off,
  When it is determined by the initialization operation determination process that the initialization operation means (reset switch 630) is operated, the main backup data stored in the main backup area (the backup RAM area of the RAM 655) is initialized. Main backup data initialization processing,
  When the main backup data stored in the main backup area (the backup RAM area of the RAM 655) is initialized by the main backup data initialization process, specific control is performed for the sub CPUs (CPUs 681a, 671a, 636a). Specific control information transmission processing for transmitting information (initialization command);
  And
  The sub CPUs (CPUs 681a, 671a, 636a)
  When the control information (command) transmitted from the main CPU (CPU 656) is received, the effect that executes the effect according to the control state of the main CPU (CPU 656) specified by the received control information (command) Execution process,
  Only when the control information (command) transmitted from the main CPU (CPU 656) is received, the previous sub stored in the first sub backup area (the backup areas 1 to 3 of the RAMs 681b, 671b, 636b). Sub-backup data update processing for updating backup data to the latest sub-backup data for returning to the presentation state when the control information (command) is received;
  Each time the control information (command) transmitted from the main CPU (CPU 656) is received and the sub-backup processing is performed, the first sub-backup area (the backup areas 1 to 3 of the RAMs 681b, 671b, 636b) Correct / error determination data (parity data) is calculated using the data, and the previous correct / error determination data stored in the second sub-backup area (the parity data storage area of the RAMs 681b, 671b, 636b) is calculated. Data update processing for correct / incorrect judgment updating to the latest correct / incorrect judgment data (parity data);
  When the power is turned on, the first sub-backup area (RAMs 681b, 671b) is based on the correctness / incorrectness determination data (parity data) stored in the second sub-backup area (parity data storage areas of the RAMs 681b, 671b, 636b). , 636b backup areas 1 to 3) for determining whether or not the data in the production area is normal,
  Based on sub-backup data stored in the first sub-backup area (the backup areas 1 to 3 of the RAMs 681b, 671b, and 636b) on the condition that it is determined to be normal by the effect state return availability determination process. Production state return processing for returning to the production state before power off,
  Specific control information reception determination processing for determining whether or not the specific control information (initialization command) is received from the main CPU (CPU 656) at power-on;
  And
  When the sub CPU (CPU 681a, 671a, 636a) determines that the specific control information (initialization command) is received from the main CPU (CPU 656) in the specific control information reception determination process, the sub backup data Regardless of whether or not it is possible to return to the effect state before the power is turned off based on the above, the effect state return process saves the first sub-backup area (the backup areas 1 to 3 of the RAMs 681b, 671b, and 636b). It is not possible to return to the production state before the power is turned off based on the sub backup data.
[0274]
  Claim 2 of the present invention provides
  The IC is mounted on the main control board (game control board 631) and drives the IC lower than the supply voltage (+ 8V) from the supply voltage (+ 8V) supplied to the main control board (game control board 631). Drive voltage generating means (DC-DC converter 921) for generating a drive voltage (+ 5V) of
  The drive voltage (+ 5V) generated by the drive voltage generating means (DC-DC converter 921) is used as a voltage for driving the main CPU (CPU 656), and the drive voltage (+ 5V) is used for the sub-control board. (Variable display control board 680, sound control board 670, lamp control board 635) are also supplied, and the drive voltage (+ 5V) supplied from the main control board (game control board 631) is the sub CPU (CPU 681a, 671a). 636a) is used as a driving voltage,
  The supply voltage (+ 8V) is used as a voltage for driving a game peripheral device controlled by the main control board (game control board 631).
[0275]
  Claim 3 of the present invention provides
  The IC is mounted on the main control board (game control board 631) and drives the IC lower than the supply voltage (+ 8V) from the supply voltage (+ 8V) supplied to the main control board (game control board 631). Drive voltage generating means (DC-DC converter 921) for generating a drive voltage (+ 5V) of
  The drive voltage (+ 5V) generated by the drive voltage generation means (DC-DC converter 921) is a voltage for driving the main CPU (CPU 656) andSaidMain CPU (CPU 656)Used as a voltage to drive gaming peripherals controlled byAt the same time, the drive voltage (+ 5V) is also supplied to the sub control board (variable display control board 680, sound control board 670, lamp control board 635), and the drive supplied from the main control board (game control board 631). The voltage (+ 5V) is used as a voltage for driving the sub CPUs (CPUs 681a, 671a, 636a).
[0276]
  Claim 4 of the present invention provides
  The IC is mounted on the main control board (game control board 631) and drives the IC lower than the supply voltage (+ 8V) from the supply voltage (+ 8V) supplied to the main control board (game control board 631). Drive voltage generating means (DC-DC converter 921) for generating a drive voltage (+ 5V) of
  The drive voltage (+ 5V) generated by the drive voltage generating means (DC-DC converter 921) is used as a voltage for driving the main CPU (CPU 656), and the drive voltage (+ 5V) is used for the sub-control board. (Variable display control board 680, sound control board 670, lamp control board 635) are also supplied, and the drive voltage (+ 5V) supplied from the main control board (game control board 631) is the sub CPU (CPU 681a, 671a). 636a) is used as a driving voltage,
  The drive voltage (+ 5V) supplied from the main control board (game control board 631) to the sub control board (variable display control board 680, sound control board 670, lamp control board 635) is:Sub CPU (CPU 681a, 671a, 636a)Is used as a voltage for driving a peripheral device for performance controlled by the.
[0282]
  Claims of the invention5SaidMain CPU (CPU 656)In the main backup process performed byMain backup dataTheIn the main backup area (backup RAM area of the RAM 655)Process to save multiple.
  According to a sixth aspect of the present invention, a plurality of identical sub-backup data is stored in the first sub-backup area (the backup areas 1 to 3 of the RAMs 681b, 671b, and 636b), and the sub-CPUs (CPUs 681a, 671a) are stored. 636a) in the sub-backup data update process, all of the previous sub-backup data stored in the first sub-backup area (backup areas 1-3 of RAMs 681b, 671b, 636b) are updated to the latest Update to sub-backup data.
[0283]
【The invention's effect】
The present invention has the following effects.
[0284]
  (A) According to the invention of claim 1,Since the sub CPU is backed up every time control information transmitted from the main CPU is received, the sub CPU can be backed up reliably. Further, when the initialization operation means is operated when the power is turned on to initialize the backup data of the main CPU, specific control information is transmitted to the sub CPU so that the sub CPU also initializes the backup data. Therefore, consistency between the two can be achieved.
[0285]
  (B) According to the invention of claim 2,The drive voltage generated by the drive voltage generation means is used as a voltage for driving the main CPU, and the same drive voltage is also used as a voltage for driving the sub CPU. The voltage for driving the sub CPU does not become higher, and it is possible to prevent malfunction and breakage of the CPU mounted on each board. Also,Since it is not necessary to separately introduce a voltage for driving the peripheral device for gaming, the configuration of the gaming machine can be simplified.
[0286]
  (C) According to the invention of claim 3,The drive voltage generated by the drive voltage generation means is used as a voltage for driving the main CPU, and the same drive voltage is also used as a voltage for driving the sub CPU. The voltage for driving the sub CPU does not become higher, and it is possible to prevent malfunction and breakage of the CPU mounted on each board. Also,It is not necessary to separately introduce a voltage for driving a gaming peripheral device, and it is not necessary to separately provide a generating means for generating a voltage for driving a gaming peripheral device, thereby simplifying the configuration of the gaming machine can do.
[0287]
  (D) According to the invention of claim 4,The drive voltage generated by the drive voltage generation means is used as a voltage for driving the main CPU, and the same drive voltage is also used as a voltage for driving the sub CPU. The voltage for driving the sub CPU does not become higher, and it is possible to prevent malfunction and breakage of the CPU mounted on each board. Also,Since it is not necessary to separately introduce a voltage for driving the performance peripheral device, the configuration of the gaming machine can be simplified.
[0293]
  (eClaim5According to the invention of the item, it is stored in the main backup processMain backup dataCan be stored more accurately.
  (F) According to the invention of claim 6, the sub-backup data updated by the sub-backup data update process can be stored more accurately.
[Brief description of the drawings]
FIG. 1 is a front view showing a slot machine according to a first embodiment to which the present invention is applied.
2 is an internal structural diagram of the slot machine of FIG. 1. FIG.
3 is a rear view of the front door of the slot machine of FIG. 1. FIG.
FIG. 4 is a block diagram illustrating an overall configuration of the slot machine according to the first embodiment.
FIG. 5 is a block diagram showing a circuit configuration in the slot machine of the first embodiment.
FIG. 6 is a diagram illustrating a configuration of a RAM in the slot machine according to the first embodiment.
7 is a circuit diagram showing a configuration of a power supply board in the slot machine of Embodiment 1. FIG.
FIG. 8 is a circuit diagram showing a configuration around a CPU of a game control board in the slot machine of the first embodiment.
FIG. 9 is a circuit diagram showing a configuration around a CPU of an effect control board in the slot machine of the first embodiment.
FIG. 10 is a flowchart showing control contents executed by the control unit of the game control board in the slot machine of the first embodiment.
FIG. 11 is a flowchart showing details of main initialization processing in FIG. 10;
12 is a flowchart showing details of reset processing in FIG. 10;
13 is a flowchart showing details of command transmission processing in FIG. 12;
14 is a flowchart showing details of the game control process in FIG.
FIG. 15 is a flowchart showing a main power failure interrupt process performed by the control unit of the game control board in the slot machine of the first embodiment.
FIG. 16 is a flowchart showing control contents executed by the control unit of the effect control board in the slot machine of the first embodiment.
FIG. 17 is a flowchart showing details of sub-initialization processing in FIG. 16;
18 is a flowchart showing details of sub-backup processing in FIG. 16. FIG.
FIG. 19 is a front view showing a pachinko machine according to a second embodiment to which the present invention is applied.
FIG. 20 is a block diagram illustrating an overall configuration of a pachinko machine according to the second embodiment.
FIG. 21 is a block diagram illustrating a circuit configuration in the pachinko machine according to the second embodiment.
FIG. 22 is a circuit diagram showing a configuration of a power supply board in the pachinko machine according to the second embodiment.
FIG. 23 is a circuit diagram showing a configuration around a CPU of a game control board in the pachinko machine of the second embodiment.
FIG. 24 is a circuit diagram illustrating a configuration around a CPU of a variable display control board (sound control board, lamp control board) in the pachinko machine according to the second embodiment.
[Explanation of symbols]
1 slot machine
2a housing
2b Front door
3 Locking device
3a Keyhole
4 upper decorative frame
5 winning design explanation panel
6 game panels
7 Lower decorative frame
8 Title panel
9 Medal payout hole
10 Ashtray
11 Medal tray
12a, 12b Sound emission part
13 Sound emission part
14 perspective windows
15 Liquid crystal display
20a, 20b Small role notification display section
21 One-sheet betting display
22, 23 Two-sheet betting display section
24, 25 3 sheets bet display section
26 Game over display
27 Replay display section
28 Weight display area
29 Start display
30 Input instruction display section
31 credit display
32 game count display
33 Payout display
34 medal insertion part
35 Medal jam release button
36a Single BET button
36b MAXBET button
37 Checkout button
38 Start lever
39 Stop button unit
40L, 40C, 40R Stop button
41-45 Game effect lamp part
50 Variable display device
51L, 51C, 51R reel
52 reel unit
53 Reel concealment member
54L, 54C, 54R reel motor
55 reel lamp
56 reel sensor
57 Hopper tank
58 Guide rail
59 Overflow tank
60 Full sensor
61 Payout medal sensor
62 Hopper motor
63 Medal outlet
64 power supply unit
65 Main switch
66 Second reset button
67 Setting button
68 Automatic checkout selection switch
69 Stopper selection switch
70 Setting key insertion part
71 medal selector
72 Unauthorized Medal Discharge Department
73 Return medal flow path
80 Main switch
81 Second reset switch
82 Setting key switch
83 Setting switch
84 Power cord
85 Backboard
86, 87 side plate
100 1-sheet BET switch
101 MAXBET switch
102 Start switch
103L, 103C, 103R Stop switch
104 Checkout switch
105 First reset switch
106 medal sensor
107 Flow path switching solenoid
108 game number display
109 credit indicator
110 Payout indicator
111 Input instruction lamp
112 Single betting lamp
113, 114 Two-sheet betting lamp
115, 116 3 betting lamps
117 Game Overramp
118 Start lamp
119 Replay lamp
120 Bonus notification lamp
121a, 121b BET button lamp
122L, 122C, 122R Operation valid lamp
130-134 Game effect lamp
135 Liquid crystal display
136a, 136b, 137 Speaker
138 Fluorescent light
139 Weight lamp
140a, 140b, 140c Small role notification lamp
200 Game control board
201 Production control board
202 Power supply board
203 Reel Relay Board
204 Reel lamp relay board
205 External output board
210 Control unit
211 CPU
212 RAM
213 ROM
214 I / O port
215 Switch circuit
216 Motor circuit
217 Initial reset circuit
218 Clock generation circuit
219 Pulse divider circuit
220 Buffer circuit
221 random number generator
222 Sampling circuit
223 DC-DC converter
224 Power supply monitoring IC
225 diode
226 capacitor
230 Control unit
231 CPDU
232 RAM
233 ROM
234 I / O port
235 Speaker drive circuit
236 Display drive circuit
237 Lamp drive circuit
238 IC for power monitoring
239 diode
240 capacitors
301 connector
302 Rectifier circuit
303 DC-DC converter
304 transformer
500 storage case
550 storage case
600 Pachinko machine
602 Glass door frame
603 Drum supply tray
604 Surplus ball tray
605 Operation knob
606 game board
607 Game area
608 Variable display device
609 Variable display
610 Variable display
611 Passing gate
612 Gate switch
613 ball exit
614 Start prize opening
615 Variable winning ball device
616 Solenoid
617 Start switch
618 Start winning memory indicator
619 Winners
619a prize opening switch
620 Opening and closing plate
621 Solenoid
622 V count switch
623 count switch
625 decorative lamp
626 Out mouth
627 Speaker
628a Game effect LED
628b Game effect lamp
629 Reset switch
630 Setting switch
631 Game control board (main board)
635 Lamp control board
636 Microcomputer for lamp control
636a CPU
636b RAM
636c ROM
636d I / O port
637 Lamp drive circuit
638 Prize ball control board
651 prize ball lamp
652 Out-of-ball lamp
653 Basic circuit
654 ROM
655 RAM
656 CPU
657 I / O port
658 Switch circuit
659 Solenoid circuit
660 lamp LED circuit
664 Information output circuit
665 Initial reset circuit
667 Address decode circuit
670 sound control board
671 Microcomputer for sound control
671a CPU
671b RAM
671c ROM
671d I / O port
672 Audio drive circuit
680 Variable display control board
681 Microcomputer for variable display control
681a CPU
681b RAM
681c ROM
681d I / O port
682 Display drive circuit
691 Launch Control Board
694 Ball launch motor
697 Ball dispenser
700 card unit
751 Available indicator lamp
752 fraction display switch
753 Connecting table direction indicator
754 Card insertion indicator lamp
755 card slot
756 Card unit lock
902 Power supply monitoring IC
910 Power supply board
911 transformer
912 Rectifier circuit
913 DC-DC converter
915 connector
921 DC-DC converter
922 diode
923 capacitor
924 diode
925 capacitor
L1, L2, L2 ', L3, L3' winning line

Claims (6)

A gaming machine capable of performing a predetermined game,
A main CPU for controlling the gaming state;
A main memory used as a work memory of the main CPU;
A sub CPU for controlling the production;
A sub memory used as a work memory of the sub CPU;
A power-off determining means for determining the occurrence of power-off when a predetermined power-off condition is satisfied;
Initialization operation means operated when initializing data stored in the main memory;
With
The main memory has a main backup area for storing main backup data for returning the gaming state,
The sub memory includes a work area used as a work memory of the sub CPU, a first sub backup area in which sub backup data for restoring the presentation state is stored, and data of the first sub backup area And a second sub-backup area in which the data for correctness / incorrectness determination is stored separately.
The main CPU is
Control information transmission processing for transmitting to the sub CPU control information capable of specifying the control state of the main CPU at that time according to the gaming state controlled by the main CPU;
A main backup process for storing the main backup data in the main backup area when the power-off determining unit determines the occurrence of a power-off,
An initialization operation determination process for determining whether or not the initialization operation means is operated when power is turned on;
When the initialization operation determining process determines that the initialization operation means has not been operated, the gaming state return is made to return to the gaming state before the power is turned off based on the main backup data stored in the main backup area. Processing,
A main backup data initialization process for initializing main backup data stored in the main backup area when it is determined that the initialization operation means is operated by the initialization operation determination process;
Specific control information transmission processing for transmitting specific control information to the sub CPU when initializing main backup data stored in the main backup area by the main backup data initialization processing;
And
The sub CPU is
When the control information transmitted from the main CPU is received, an effect execution process for executing an effect according to the control state of the main CPU specified by the received control information;
Only when the control information transmitted from the main CPU is received, the previous sub-backup data stored in the first sub-backup area is restored to the effect state when the control information is received. Sub-backup data update processing to update to the latest sub-backup data,
Each time the control information transmitted from the main CPU is received and the sub-backup process is performed, correctness determination data is calculated using the data of the first sub-backup area, and the second sub-backup area Correct / wrong judgment data update processing for updating the previous true / wrong judgment data stored in the latest correct / wrong judgment data,
An effect state return availability determination process for determining whether or not the data in the first sub-backup area is normal based on the correctness / incorrectness determination data stored in the second sub-backup area when the power is turned on;
An effect state return process for returning to the effect state before the power interruption based on the sub-backup data stored in the first sub-backup area on the condition that the effect is determined to be normal by the effect state return availability determination process When,
Specific control information reception determination processing for determining whether or not the specific control information is received from the main CPU at power-up;
And
If the sub CPU determines that the specific control information has been received from the main CPU in the specific control information reception determination process, is it possible to return to the effect state before the power is turned off based on the sub backup data? Regardless of whether or not, the gaming machine is not restored to the stage before the power is turned off based on the sub-backup data stored in the first sub-backup area by the stage-state restoration process . A drive voltage generating means mounted on the main control board and generating a drive voltage for driving the IC lower than the supply voltage from the supply voltage supplied to the main control board;
The drive voltage generated by the drive voltage generation means is used as a voltage for driving the main CPU, and the drive voltage is also supplied to the sub-control board, and the drive voltage supplied from the main control board is , Used as a voltage for driving the sub CPU,
The gaming machine according to claim 1, wherein the supply voltage is used as a voltage for driving a gaming peripheral device controlled by the main CPU . A drive voltage generating means mounted on the main control board and generating a drive voltage for driving the IC lower than the supply voltage from the supply voltage supplied to the main control board;
The drive voltage generated by the drive voltage generation means is used as a voltage for driving the main CPU and a voltage for driving a game peripheral device controlled by the main CPU , and the drive voltage is applied to the sub-control board. The gaming machine according to claim 1 , wherein the driving voltage supplied from the main control board is used as a voltage for driving the sub CPU . A drive voltage generating means mounted on the main control board and generating a drive voltage for driving the IC lower than the supply voltage from the supply voltage supplied to the main control board;
The drive voltage generated by the drive voltage generation means is used as a voltage for driving the main CPU, and the drive voltage is also supplied to the sub-control board, and the drive voltage supplied from the main control board is , Used as a voltage for driving the sub CPU,
The gaming machine according to claim 1, wherein the drive voltage supplied from the main control board to the sub control board is used as a voltage for driving a peripheral device for presentation controlled by the sub CPU . The gaming machine according to any one of claims 1 to 4 , wherein in the main backup process performed by the main CPU, a process of storing a plurality of identical main backup data in the main backup area is performed. In the first sub-backup area, a plurality of the same sub-backup data is stored, and in the sub-backup data update process performed by the sub-CPU, a plurality of previous sub-backup data are stored in the first sub-backup area. The gaming machine according to claim 1, wherein all of the sub-backup data is updated to the latest sub-backup data.

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