JP6039195B2 - Slot machine - Google Patents

Description

  The present invention makes it possible to start a game by setting a predetermined number of bets for one game, and the display result is derived to a variable display device that variably displays a plurality of types of identification information each identifiable. The present invention relates to a slot machine in which one game is completed and a winning can be generated according to a display result derived to the variable display device.

  After setting a predetermined number of bets for one game using a game medium such as a medal, a coin, or a game ball similar to a pachinko gaming machine, the player operates the start lever to change the display pattern by the variable display device. The variable display is started, and when the player operates the stop button provided corresponding to each variable display device, the variable display of the display symbols is stopped within the predetermined maximum delay time from the operation timing. When a winning is generated according to the display result derived when the variable display of all the variable display devices is stopped, a predetermined game medium predetermined according to the winning is paid out, and a specific winning is generated. There is a slot machine configured to change the gaming state to a state in which a predetermined gaming value is given to the player.

  As such a slot machine, when power supply stops (instantaneous power failure) in a short period of time, a timer for measuring a predetermined monitoring time (watchdog timer) times out to reset the game control microcomputer Has been proposed (for example, Patent Document 1).

Japanese Patent Laid-Open No. 2007-190095

  In the technique described in Patent Document 1, resetting is performed by executing processing (initialization processing) that periodically clears and restarts the count value of the timer even during execution of the game control processing that controls the progress of the game. It is prevented from being done. Therefore, there is a problem that the control burden for controlling the progress of the game becomes large.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a slot machine capable of appropriately recovering from an instantaneous power supply interruption while reducing the burden of game control.

(1) In order to achieve the above object, a slot machine according to the present invention includes a variable display unit capable of variably displaying a plurality of types of identification information each identifiable, and after variably displaying the variable display unit, deriving the display result by stopping the variable display of the variable display unit, in the display result winning in accordance with the possible occurrence slot machine (e.g., a slot machine 1), in accordance with a control program, initial setting processing ( For example, after executing the security check process and the processes of steps Sa1 to Sa33 and Sa35 to Sa41 ), the control means (for example, the CPU 505) executes the control of the slot machine (for example, the process of steps Sd1 to Sd7 which becomes the game control process). and the like game control microcomputer 100) comprising, monitoring the status of the power that is used in the slot machine, Power supply monitoring means for outputting a detection signal (for example, a power-off signal) based on the fact that a detection condition related to stopping the supply of power to the slot machine is satisfied (for example, the voltage value of the + 30V power supply has decreased to +22 V) For example, a power monitoring circuit 303 and the like, and a time measuring means (for example, a 16-bit up counter 536) for measuring a predetermined monitoring time (for example, timeout time), and the monitoring time has passed by the time measuring means . Reset means (for example, reset controller 504A, watchdog timer 520, etc.) that resets the control means , and the reset means is stored in an operation setting storage area (eg, WDT start register WST). Activation data indicating that the operation of the reset means is to be activated (for example, W The operation is validated by writing T start data) by the control means (for example, by writing “CCH” to the WDT start register WST, the watchdog timer 520 starts measuring the monitoring time and resets due to the occurrence of a timeout. Initialization data (for example, WDT clear data) indicating that the timing means is initialized in a storage area for initialization (for example, WDT clear register WCL) when the operation is enabled. Is written by the control means to initialize the time measuring means (for example, “AAH” is written by the CPU 505 after “55H” is written to the WDT clear register WCL, so that the 16-bit up counter 536 is written to the WDT control circuit 533. Clear the count value of The count operation restart), the control means, the control of the slot machine after performing the power from the monitoring means detecting signal power supply stop process in accordance with (e.g., main-side power-off processing in step S52) CPU505 of the game control microcomputer 100 that executes the processing executed without a standby state (e.g., execution states such as the treatment of an endless loop after executing the processing in step SM23) to Ru power interruption time control means is shifted (for example, step SM23 etc.) viewed including the interruption time control means writes the valid data in the storage area for the operation setting of said reset means upon transition to the standby state, the after transition to the standby state the The initialization data is written in the initialization storage area of the reset means so that the initialization of the timing means is not executed. (For example, when an infinite loop process is executed, the reset operation by the elapse of the time-out time of the watchdog timer 520 activated by writing WDT start data to the WDT start register WST is enabled while the WDT clear register WCL is set to WDT. Clear data is not written) .
According to such a configuration, the setting for enabling or disabling the operation of the reset unit is performed, and the reset unit is performed along with the execution of the power supply stop process according to the detection signal related to the stop of the power supply to the slot machine. Is activated. This eliminates the need for periodic reset means initialization during execution of slot machine control, and properly recovers from instantaneous power supply interruptions while reducing the control burden for executing slot machine control. can do.

(2) in the slot machine of the above (1), the monitoring time measured by said time measuring means, can be set from among a plurality of types of predetermined (e.g. bit number of the reset settings Kres [5-4] And a part for setting a time-out time as shown in FIG. 10B by the value of bit number [3-0]), the control unit performs the operation of the reset unit in accordance with the execution of the power supply stop process. When enabling, a maximum time that can be set as the monitoring time may be set (for example, when the process of step Sm23 is executed, the WDT control circuit 533 sets the timeout time to 225 × TSCLK based on the reset setting KRES. X15, etc.)
In such a configuration, the longest time that can be set as the monitoring time measured by the reset means is set, so that when the power supply is completely stopped for a predetermined period due to a power switch disconnection or the like, it is erroneously reset. Can be prevented.

(3) In the slot machine of the above (1) or (2), the control means indicates that the reset time is reset by the reset means after the monitoring time has elapsed after executing the power supply stop process. the reset information and the reset information storage means for storing (e.g. internal information internal bit number [1] of the register for storing the data CIF, etc.), when the front Symbol Initial setting processing is executed, the reset information storage means There the reset information determining means for determining whether or not stored (e.g., CPU505 for executing the processing of step S72), when it is determined to be stored by the reset information determining means, before Symbol resetting means Including post-reset activation control means (eg, CPU 505 that executes the process of step S74) that invalidates the operation. But good.
In such a configuration, if the reset information is stored when the initial setting process is performed, the operation of the reset unit is invalidated to prevent inadvertent resetting.

(4) In the slot machine according to any one of (1) to (3), the control unit writes the plurality of data having different values in the initialization storage area in a predetermined order, so that the reset unit the time measured may be initialized (e.g., in the process of step Sa 3 5C, like parts sequentially writing "AAH" and "55H" to the WDT clear register WCL).
In such a configuration, the time measured by the reset means is not initialized unless a plurality of data having different values are written in a predetermined order. Therefore, the measurement time is erroneously initialized due to noise or the like when the power supply instantaneously stops. Can be prevented.

It is a front view of the slot machine to which the present invention is applied. It is an internal structure figure of a slot machine. It is a figure which shows the symbol arrangement | sequence of a reel. It is a block diagram which shows the structure of a slot machine. It is a block diagram which shows the structural example of a power supply board. It is a timing diagram which shows typically the state of a reset signal and a power-off signal. It is a block diagram which shows the structural example of the microcomputer for game control. It is a figure which shows an example of the address map in the microcomputer for game control. It is a figure which illustrates the main part of a program management area and a built-in register area. It is a figure which shows an example of the setting content in a header and reset setting. It is a figure which shows an example of the setting content in interruption initial setting, 16-bit random number initial setting 1st, 16-bit random number initial setting 3rd. It is a figure which shows an example of the setting content in security time setting. It is a figure which shows the structural example etc. of an internal information register. It is a block diagram which shows the structural example of a watchdog timer. It is a figure which shows the structural example etc. of a WDT start register. It is a figure which shows the structural example etc. of a WDT clear register. It is a block diagram which shows the structural example of a random number circuit. It is a figure which shows the structural example etc. of a random number sequence change register. It is a figure which shows the operation example which changes a random number sequence update rule with software. It is a figure which shows the operation example which changes a random number sequence update rule automatically. It is a figure which shows the structural example of a random number maximum value setting register. It is a figure which shows the structural example etc. of a hard latch selection register. It is a figure which shows the structural example etc. of a random number hard latch flag register. It is a figure which shows the structural example etc. of a hard latch interrupt control register. It is a figure which shows the structural example etc. of a random number soft latch register. It is a figure which shows the structural example etc. of a random number soft latch flag register. (A) is a block diagram showing the connection between the main control unit and the SRAM, (b) is a timing chart showing the output status of the signal at the time of reading, and (c) is the signal at the time of writing. It is a timing chart which shows an output condition. It is explanatory drawing of a game control program. It is a flowchart which shows an example of a security check process. It is a flowchart which shows the control content of the starting process (main) which a main control part performs at the time of starting. It is a flowchart which shows the control content of the starting process (main) which a main control part performs at the time of starting. It is a flowchart which shows the control content of the starting process (main) which a main control part performs at the time of starting. It is a flowchart which shows the control content of the game control process which a main control part performs. It is a flowchart which shows the control content of the timer interruption process (main) which a main control part performs for every fixed interval. It is a flowchart which shows the control content of the timer interruption process (main) which a main control part performs for every fixed interval. It is a flowchart which shows the control content of the power interruption process (main) performed according to having detected the power interruption in the timer interruption process (main). It is a flowchart which shows an example of the process which sets a watchdog timer. It is explanatory drawing which shows the storage state of the data when storing in the backup RAM when storing the backup data for every program module in a game control program. It is a figure for demonstrating the kind of symbol combination, symbol combination, and the payout number of medals at the time of winning a prize. It is a figure for demonstrating the technical matter relevant to the kind of replay, a symbol combination, and a small part. It is a figure for demonstrating the symbol combination of a transfer turn. It is a figure for demonstrating a game state and transition of RT. It is a figure for demonstrating the navigation object combination in AT. It is a figure for demonstrating the reel control at the time of several re-game player winning. It is a figure for demonstrating the reel control at the time of several small part winning. It is a timing chart which shows the operation example in a random number circuit. 6 is a timing chart illustrating an example of a read operation of a hard latch random number register. It is a timing chart which shows the operation example when a power supply voltage falls during execution of game control. It is a timing chart which shows the operation example when the stability of a power supply voltage cannot be confirmed at the time of power activation. It is explanatory drawing which shows the storage state when backup data is stored in backup RAM, when (A) bus width of work RAM and back wrap RAM corresponds, and (B) bus width differs. It is explanatory drawing which shows the difference with the case where (A) data conversion is not performed and the case where (B) data conversion is performed when the bus widths of work RAM and backlap RAM differ. It is explanatory drawing which shows the storage state of the data in backup RAM when data conversion is performed when the bus width of work RAM and backlap RAM differs.

  Examples of the present invention will be described below.

  An embodiment of a slot machine to which the present invention is applied will be described with reference to the drawings. A slot machine 1 according to the present embodiment includes a housing 1a having an open front surface, and a pivotable pivot at a side end of the housing 1a. The front door 1b is supported.

  Inside the casing 1a of the slot machine 1 of the present embodiment, as shown in FIG. 2, reels 2L, 2C and 2R (hereinafter referred to as a left reel, a middle reel and a right reel) in which a plurality of types of symbols are arranged on the outer periphery ) Are juxtaposed in the horizontal direction, and as shown in FIG. 1, three consecutive symbols out of the symbols arranged on the reels 2L, 2C, 2R can be seen from the see-through window 3 provided on the front door. Is arranged.

  As shown in FIG. 3, on the outer periphery of the reels 2L, 2C, and 2R, “black 7”, “net 7 (shaded 7 in the figure)”, “white 7”, “BAR”, “replay”, A plurality of types of mutually distinguishable symbols such as “plum”, “watermelon”, “cherry”, “bell”, and “orange” are drawn in a predetermined order. The symbols drawn on the outer peripheries of the reels 2L, 2C, and 2R are displayed in upper, middle, and lower three stages in the see-through window 3 provided in the approximate center of the reel panel 1c of the front door 1b.

  The reels 2L, 2C, and 2R are provided in correspondence with each other and rotated by reel motors 32L, 32C, and 32R (see FIG. 4), so that the symbols of the reels 2L, 2C, and 2R are continuously formed in the see-through window 3. In addition to being displayed while changing, by stopping the rotation of the reels 2L, 2C, and 2R, three consecutive symbols are derived and displayed on the fluoroscopic window 3 as display results.

  Inside the reels 2L, 2C, and 2R are reel sensors 33L, 33C, and 33R that detect a reference position for each of the reels 2L, 2C, and 2R, and a reel LED 55 that irradiates the reels 2L, 2C, and 2R from the back side. , Is provided. The reel LED 55 includes 12 LEDs corresponding to three consecutive symbols on the reels 2L, 2C, and 2R, and each symbol can be irradiated independently.

  At the position corresponding to each reel 2L, 2C, 2R on the front door 1b, a horizontally long rectangular see-through window 3 that allows the reels 2L, 2C, 2R to be seen through from the front side is provided. The reels 2L, 2C, 2R can be visually recognized from the player side.

  The front door 1b uses a medal insertion unit 4 into which medals can be inserted, a medal payout exit 9 from which medals are paid out, and credits (the number of medals stored as a player's own game value). The MAXBET switch 6 that is operated when setting the maximum bet number (3 in any game state in this embodiment) among the prescribed number of bets determined according to the game state, is stored as credits. Settlement switch 10 operated when paying out medals used for setting medals and betting numbers (returning medals used for setting credits and betting numbers), start switch operated when starting a game 7. Stop switches 8L, 8C, 8R operated when stopping the rotation of the reels 2L, 2C, 2R, and an effect switch 56 for use in effects. It is provided so as to be operated by the skill person.

  In this embodiment, among the three reels 2L, 2C, and 2R that have started to rotate, the reel that stops first is referred to as a first stop reel, and the stop is referred to as a first stop. Similarly, the reel that stops second is called the second stop reel, the stop is called second stop, the reel that stops third is called the third stop reel, and the stop is the third stop. Alternatively, it is called final stop.

  The front door 1b also displays a credit indicator 11 that displays the number of medals stored as credits, the number of medals paid out due to the occurrence of a prize, an error code indicating the contents when an error occurs, and the like. Game assist indicator 12, 1BETLED14 that notifies that the bet number is set by 1 by lighting, 2BETLED15 that notifies that the bet number is set by 2 and 2 that the bet number is set by 3 3BET LED 16 to notify, insertion request LED 17 to notify that a medal can be inserted by lighting, start effective LED 18 to notify that the game start operation by the operation of the start switch 7 is effective, wait (the previous game start) Waiting for the start of reel rotation because a certain period has not elapsed since Weight in LED19 for notifying by lighting a a is that during the game display section 13 in the replay LED20 is provided for informing is provided by lighting the effect that during replay game, which will be described later.

  Inside the MAXBET switch 6, there is provided a BET switch valid LED 21 (see FIG. 4) for notifying that the setting operation of the bet amount by the operation of the MAXBET switch 6 is valid, and stop switches 8L, 8C, The left, middle, and right stop valid LEDs 22L, 22C, and 22R (see FIG. 4) are provided inside the 8R to notify that the reel stop operation by the corresponding stop switches 8L, 8C, and 8R is valid by lighting. It has been.

  Further, below the stop switches 8L, 8C, 8R on the front door 1b, a lower panel 1d on which a title of the slot machine 1 and a payout table are printed is provided.

  Inside the front door 1b, there is a reset switch 23 for detecting a reset operation for releasing an error state described later and a stop state described later by a predetermined key operation, while changing a set value and confirming a set value described later. The set value display 24 that displays the set value at that time, and the validity / invalidity of the stop function for controlling the stop state at the end of the BB, which will be described later (a state in which the progress of the game is restricted until a reset operation is performed) A check switch 36a for selecting the automatic settlement function that controls automatic settlement at the end of BB, which will be described later (processing to settle (return) medals stored as credits regardless of the player's operation). An automatic settlement switch 36b for selecting invalidity, and a flow path for medals inserted from the medal insertion unit 4 are provided in a hopper tank 34a (described later with reference to FIG. 2) provided inside the housing 1a. And a medal having a insertion medal sensor 31 for detecting a medal that has been inserted from the medal insertion unit 4 and flowed down to the hopper tank 34a side. A selector (not shown) and a door open detection switch 25 (see FIG. 4) for detecting the open state of the front door 1b are provided.

  As shown in FIG. 2, a reel sensor 33L that can detect the reel reference positions of the reels 2L, 2C, and 2R, the reel motors 32L, 32C, and 32R, and the reels 2L, 2C, and 2R, as shown in FIG. , 33C, 33R (see FIG. 4), an external output board 1000 for outputting an external output signal, a hopper tank 34a for storing medals inserted from the medal insertion section 4, and a hopper tank 34a. A hopper unit 34 including a hopper motor 34b for paying out medals from the medal payout opening 9, a payout sensor 34c for detecting medals paid out by driving the hopper motor 34b, and a power supply box 100 are provided.

  On the side of the hopper unit 34, an overflow tank 35 is provided for storing medals overflowing from the hopper tank 34a. Inside the overflow tank 35, a full sensor 35 a made up of a pair of electrically conductive members spaced apart from each other and provided at a height capable of detecting a predetermined amount of stored medals is provided. It is possible to detect that the medal storage amount stored in the inside when it is conductive by contacting through the medal stored in the inside exceeds a predetermined amount, that is, that the overflow tank is full. It has become.

  The front side of the power supply box 100 functions as a setting key switch 37 for switching to a setting change state or a setting confirmation state, and functions as a reset switch for canceling an error state or a stop state in a normal state. There are provided a reset / setting switch 38 that functions as a setting switch for changing a setting value of a winning probability (outtake rate) of internal lottery to be described later, and a power switch 39 that is operated when the power is turned on / off. .

  When a game is played in the slot machine 1 of the present embodiment, first, medals are inserted from the medal insertion unit 4 or a bet number is set using credits. To use the credit, the MAXBET switch 6 may be operated. When a predetermined number of bets determined according to the gaming state are set, the winning line LN (see FIG. 1) becomes valid, and the operation of the start switch 7 is valid, that is, the state where the game can be started. Become. In the present embodiment, when the prescribed number of bets is set to three regardless of the gaming state and the prescribed number of bets is set, the pay line LN becomes valid. In addition, when a medal is inserted exceeding the maximum number out of the prescribed number corresponding to the gaming state, the amount is added to the credit.

  The winning line is a line that is set to determine whether a combination of symbols displayed on the perspective windows 3 of the reels 2L, 2C, and 2R is a winning symbol combination. In this embodiment, as shown in FIG. 1, only the winning line LN set across the symbols arranged in the horizontal direction in the middle stage of the reel 2L, the middle stage of the reel 2C, the middle stage of the reel 2R, that is, the middle stage, is used as the winning line. It has been established. In this embodiment, only one winning line is applied, but a plurality of winning lines may be applied.

  In the present embodiment, invalid lines LM1 to LM1-4 are set apart from the winning line LN in order to make it easy to recognize that the winning line LN has a combination of symbols constituting the winning line. The invalid lines LM1 to LM4 are not determined based on the combination of symbols aligned with the invalid lines LM1 to LM4. When the combination of symbols constituting a specific prize is arranged on the winning line LN, the invalid line LM1 to LM4. When a combination of symbols (for example, bell-bell-bell) is awarded when the winning line LN is aligned with any of the LM1 to LM4, the symbols constituting the particular winning line LN It is easy to recognize that the combination is complete. In this embodiment, as shown in FIG. 1, an invalid line LM1 and a lower stage of the reel 2L, which are set across the symbols arranged horizontally in the upper stage of the reel 2L, the upper stage of the reel 2C, the upper stage of the reel 2R, that is, the upper stage. , The lower stage of the reel 2C, the lower stage of the reel 2R, that is, the invalid line LM2 set across the symbols arranged horizontally in the lower stage, the upper stage of the reel 2L, the middle stage of the reel 2C, the lower stage of the reel 2R, that is, the lower side There are four types of invalid lines LM3 set across straddling symbols LM3, lower stage of reel 2L, middle stage of reel 2C, upper stage of reel 2R, that is, invalid line LM4 set straddling to the right. It is defined as.

  When the start switch 7 is operated in a state where the game can be started, the reels 2L, 2C, and 2R rotate, and the symbols of the reels 2L, 2C, and 2R continuously vary. When any one of the stop switches 8L, 8C, 8R is operated in this state, the rotation of the corresponding reels 2L, 2C, 2R is stopped, and the display result is derived and displayed on the fluoroscopic window 3.

  Then, when all the reels 2L, 2C and 2R are stopped, one game is finished, and a combination of symbols (hereinafter also referred to as a combination) predetermined on the winning line LN is a display result of each reel 2L, 2C and 2R. In the case of a stop, a winning occurs, and a predetermined number of medals are awarded to the player and added to the credit. Further, when the credit reaches the upper limit number (50 in this embodiment), medals are paid out directly from the medal payout opening 9 (see FIG. 1). In addition, when the combination of symbols accompanying the transition of the gaming state is stopped as a display result of each reel 2L, 2C, 2R on the winning line LN, the gaming state is shifted according to the combination of symbols.

  In the slot machine 1 according to the present embodiment, after the game is started and the reels 2L, 2C, and 2R are rotated and the symbols start to change, any one of the stop switches 8L, 8C, and 8R is operated. When this is done, the rotation of the reels corresponding to the stop switches 8L, 8C, 8R is stopped, and the symbols are stopped and displayed. The maximum stop delay time from the operation of the stop switches 8L, 8C, 8R to the stop of the rotation of the corresponding reels 2L, 2C, 2R is 190 ms (milliseconds).

  The reels 2L, 2C and 2R rotate 80 times per minute, and 80 × 21 (the number of symbols per reel) = 1680 frames, so the maximum of 4 symbols is drawn in 190 ms. Will be able to. In other words, the symbols that can be selected as the stop symbols are the symbols that are displayed when the stop switches 8L, 8C, and 8R are operated, and the symbols that are four frames ahead of them, for a total of five symbols.

  For this reason, for example, when any one of the stop switches 8L, 8C, 8R is operated and the symbol displayed on the lower stage of the reel corresponding to the stop switch is used as a reference, the symbol from the symbol to four frames ahead is used. Since the symbols can be displayed in the lower row, in each of the reels 2L, 2C, 2R, when any one of the stop switches 8L, 8R is operated, the symbol displayed in the middle row of the reel corresponding to the stop switch. Can be displayed on the winning line LN.

  FIG. 4 is a block diagram showing a configuration of the slot machine 1. As shown in FIG. 4, the slot machine 1 is provided with a game control board 40, an effect control board 90, and a power supply board 101. The game state is controlled by the game control board 40, and the game state is controlled by the effect control board 90. The production according to the control is controlled, and the power supply board 101 generates the drive power for the electrical components constituting the slot machine 1 and supplies them to each part.

  The power supply board 101 is supplied with AC100V power from the outside, and from this AC100V power supply, a DC voltage necessary for driving electrical components constituting the slot machine 1 is generated, and the game control board 40 and the game control board 40 are generated. It is supplied to the production control board 90 connected through the. Further, a command transmission line from the game control microcomputer 100 to the sub-control unit 91, which will be described later, and a power supply line for supplying power from the game control board 40 to the effect control board 90 are a single cable and connector. Are connected to each other, and all the connectors that connect these cables and the respective boards are connected to each other so that the respective parts on the side of the effect control board 90 can operate and receive commands from the game control microcomputer 100. It becomes possible. For this reason, unless the command transmission line for transmitting commands from the game control microcomputer 100 is connected to the effect control board 90, power is not supplied to the effect control board 90 side, and only the effect control board 90 side. Will not work.

  Further, the above-described hopper motor 34b, payout sensor 34c, full sensor 35a, setting key switch 37, reset / setting switch 38, and power switch 39 are connected to the power supply board 101.

  For example, in the power supply board 101, as shown in FIG. 5, AC24V, VLP (DC + 24V), VSL (DC + 30V), VDD (DC + 12V), VCC (DC + 5V) and VBB (DC + 5V) are generated. For example, as shown in FIG. 5, the power supply substrate 101 includes a transformer circuit 301, a DC voltage generation circuit 302, a power supply monitoring circuit 303, and a clear switch 304. In addition, a power switch 39 is provided outside the power supply board 101 for executing or cutting off power supply to each control board and mechanism components in the slot machine 1. Alternatively, in the slot machine 1, the power switch 39 may be provided on the power supply substrate 101. In addition, the power supply substrate 101 may be provided with a capacitor serving as a backup power supply. For example, this capacitor may be charged from a power supply line of VBB (DC + 5V).

  For example, the transformer circuit 301 may be configured to include a transformer to which commercial power is applied to the input side (primary side), a varistor as an overvoltage protection circuit provided on the input side of the transformer, and the like. Here, the transformer included in the transformer circuit 301 may be any one that electrically insulates the commercial power supply from the power supply substrate 101. The transformer circuit 301 generates AC 24V as its output voltage. The DC voltage generation circuit 302 includes, for example, a rectifying / smoothing circuit that generates VSL by rectifying and boosting AC 24V with a rectifying element. VSL is used as a power supply voltage for driving the solenoid. Further, the DC voltage generation circuit 302 includes a rectifier circuit that generates VLP by rectifying AC24V with a rectifier, for example. VLP includes credit indicator 11, game auxiliary indicator 12, payout indicator 13, 1-3 BETLEDs 14-16, insertion request LED17, start valid LED18, waiting LED19, replaying LED20, BET switch valid LED21, left, middle, It is used as a power supply voltage for lighting light emitters such as the right stop valid LEDs 22L, 22C, 22R and the set value display 24. In addition, the DC voltage generation circuit 302 includes a DC-DC converter that generates VDD and VCC based on, for example, VSL. The DC-DC converter includes, for example, one or more switching regulators and a relatively large capacitor connected to the input side of the switching regulator, and when power supply from the outside to the slot machine 1 is stopped In addition, any configuration may be used as long as the direct-current voltage such as VSL, VDD, VBB, etc. decreases relatively slowly. The VDD is, for example, the MAXBET switch 6, the start switch 7, the stop switches 8L, 8C, and 8R, the settlement switch 10, the reset switch 23, the stop switch 36a, the automatic settlement switch 36b, the insertion medal sensor 31, and the door opening detection shown in FIG. It is supplied to various switches such as the switch 25, reel sensors 33L, 33C, 33R, payout sensor 34c, full sensor 35a, setting key switch 37, reset / setting switch 38, and used to operate these switches.

  As shown in FIG. 5, VLP, VSL, VDD, VCC, and VBB are transmitted to the game control board 40 via, for example, a predetermined connector and a power supply line. Note that each voltage may be supplied to the effect control board 90 via the game control board 40. Alternatively, each voltage may be directly supplied to the effect control board 90 from the power supply board 10 without going through the game control board 40.

  The power monitoring circuit 303 is configured by using, for example, a power failure monitoring reset module IC, and is a circuit that realizes power monitoring means for outputting a power interruption signal. For example, when a predetermined power supply voltage (VSL as an example) used in the slot machine 1 exceeds a predetermined value (+22 V as an example), the power monitoring circuit 303 outputs a power-off signal in an off state (high level). On the other hand, when the period during which the predetermined power supply voltage is equal to or lower than the predetermined value continues for a predetermined time (for example, 56 milliseconds), an on-state (low level) power-off signal is output. Alternatively, the power supply monitoring circuit 303 may output a power-off signal in an on state immediately when a predetermined power supply voltage used in the slot machine 1 becomes a predetermined value or less. For example, the power-off signal may be a negative logic electric signal that is turned on when it is low and turned off when it is high. The power-off signal output from the power supply monitoring circuit 303 is amplified by, for example, an output driver circuit mounted on the power supply board 101 and then transmitted to the game control board 40 via a predetermined connector or signal line.

  The predetermined power supply voltage to be monitored for outputting the power-off signal is preferably a voltage higher than a specified value (for example, +12 V) in the power supply voltage VDD for operating the switch, such as the power supply voltage VSL. As a result, the power supply voltage VDD for operating the switch is lowered, and various switches (for example, MAXBET switch 6, start switch 7, stop switches 8L, 8C, 8R, settlement switch 10, reset switch 23, stop switch 36a, automatic settlement switch) 36b, insertion medal sensor 31, door open detection switch 25, reel sensors 33L, 33C, 33R, payout sensor 34c, full sensor 35a, setting key switch 37, reset / setting switch 38, etc.) In addition, by outputting a power-off signal (turning on), it is possible to prevent progress of game control based on erroneous detection by various switches. That is, when the power supply voltage VDD for operating the switch is lowered, the switch output of the negative logic (turned on at a low level) is turned on, but the power supply voltage VSL that drops earlier than the power supply voltage VDD is monitored to supply power By recognizing the stop, it becomes possible to enter a state of waiting for power supply recovery and not detecting the switch output before the switch output is turned on.

  A large-capacitance capacitor may be connected to the power supply line for transmitting the power supply voltage VSL and the like to the game control board 40. On the other hand, such a capacitor may not be connected to the input line that transmits to the power supply monitoring circuit 303 in order to monitor the power supply voltage VSL. In this case, the power supply voltage VSL in the input line to the power supply monitoring circuit 303 to be monitored drops earlier than the power supply voltage VSL in the power supply line to which the capacitor is connected. That is, even after the monitored power supply voltage VSL starts to decrease, the supply state of the power supply voltage VSL in the power supply line supplied to the solenoid, the motor, or the like is maintained for a predetermined period. Therefore, even when the power supply voltage VSL to be monitored starts to decrease, the solenoid, the motor, and the like can be driven for a predetermined period. Further, it is possible to recognize the stop of the power supply before the power supply voltage VSL in the power supply line starts to decrease.

  In place of the solenoid drive power supply voltage VSL, for example, a power cut-off signal is generated by monitoring an arbitrary power supply voltage higher than a specified value in the switch operation power supply voltage VDD, for example, the power supply voltage VLP for lighting the light emitter. You may make it output. The condition for detecting the stop of the supply of power supplied to the slot machine 1 from the outside is not limited to the fact that the predetermined power supply voltage used in the slot machine 1 has become a predetermined value or less. Any condition may be used as long as it can be detected that the interruption has occurred. For example, the AC wave such as AC 24V may be monitored to detect that the AC wave has stopped, or the signal obtained by digitizing the AC wave may be monitored and the AC signal may be generated when the digital signal becomes flat. It may be a detection condition for the interruption.

  For example, the power supply monitoring circuit 303 may output a reset signal when a predetermined power supply voltage (VCC as an example) becomes equal to or lower than a predetermined value (+4.5 V as an example). The reset signal may be an electric signal that is turned on when the reset signal becomes low level, for example. The reset signal output from the power supply monitoring circuit 303 is amplified by, for example, an output driver circuit mounted on the power supply board 101 and then transmitted to the game control board 40 via a predetermined connector or signal line. A reset signal may be transmitted to the effect control board 90 via the game control board 40. Alternatively, the reset signal may be transmitted directly to the effect control board 90 without going through the game control board 40. Furthermore, the circuit that outputs the reset signal may be configured by using a watchdog timer built-in IC provided separately from the power supply monitoring circuit 303, a system reset IC, or the like.

  When power supply to the slot machine 1 stops, the power monitoring circuit 303 outputs a reset signal (sets to a low level) when a predetermined period elapses after the power-off signal is output (set to a low level). To do. The predetermined period here may be a period sufficient for the game control microcomputer 100 mounted on the game control board 40 shown in FIG. 4 to execute a predetermined power-off process, for example. In other words, the power monitoring circuit 303 outputs a reset signal as an operation stop signal after the gaming control microcomputer 100 completes a predetermined power-off process after outputting a power-off signal as a power feeding signal ( Set to low level). The game control microcomputer 100 that has received the reset signal output from the power monitoring circuit 303 enters an operation stop state, and execution of various control processes is stopped. Further, when power supply to the slot machine 1 is started, for example, when a predetermined power supply voltage (VCC as an example) exceeds a predetermined value (+4.5 V as an example), the power supply monitoring circuit 303 stops outputting a reset signal ( Set to high level).

  FIG. 6 is a timing chart schematically showing the states of AC 24 V, VSL, VCC, reset signal, and power-off signal when power supply to the slot machine 1 is started and when power supply is stopped. . As shown in FIG. 6, when power supply to the slot machine 1 is started, VSL and VCC gradually reach specified values (DC + 30V and DC + 5V). At this time, when VCC exceeds a first predetermined value (for example, +4.5 V), the power supply monitoring circuit 303 stops outputting the reset signal (sets it to a high level) and turns it off. When VSL exceeds a second predetermined value (for example, +22 V), the power supply monitoring circuit 303 stops outputting the power-off signal (sets it to a high level) and turns it off. On the other hand, when the power supply to the slot machine 1 stops, VSL and VCC gradually decrease. At this time, when VSL decreases to the second predetermined value (+22 V), the power supply monitoring circuit 303 outputs the power-off signal as an ON state (sets it to a low level). Further, when VCC decreases to the first predetermined value (+4.5 V), the power monitoring circuit 303 outputs the reset signal as an ON state (sets it to a low level).

  The clear switch 304 included in the power supply substrate 10 illustrated in FIG. 5 has a push button structure, for example, and outputs a clear signal in response to an operation such as pressing. The clear signal may be an electrical signal that is turned on when it becomes low level in response to an operation such as pressing. Alternatively, the clear signal may be an electrical signal that is turned on when it becomes high level in response to an operation such as pressing. The clear signal output from the clear switch 304 is transmitted to the game control board 40 via, for example, a predetermined connector or signal line. When the clear switch 304 is not operated, the output of the clear signal is stopped (set to high level or low level). Note that the clear switch 304 may have a configuration other than a push button structure (for example, a slide switch structure, a toggle switch structure, a dial switch structure, or the like).

  On the game control board 40, the above-described MAXBET switch 6, start switch 7, stop switches 8L, 8C, 8R, settlement switch 10, reset switch 23, stop switch 36a, automatic settlement switch 36b, insertion medal sensor 31, door open The detection switch 25 and reel sensors 33L, 33C, and 33R are connected, and the above-described payout sensor 34c, full sensor 35a, setting key switch 37, and reset / setting switch 38 are connected via the power supply board 101. Detection signals from these connected switches are input.

  Further, the game control board 40 includes the credit display 11, the game auxiliary display 12, the payout display 13, 1 to 3 BET LEDs 14 to 16, the insertion request LED 17, the start valid LED 18, the waiting LED 19, the replaying LED 20, and the BET. The switch effective LED 21, left, middle, and right stop effective LEDs 22L, 22C, and 22R, the set value display 24, the flow path switching solenoid 30, and the reel motors 32L, 32C, and 32R are connected to each other, and are described above via the power supply board 101. The hopper motor 34b is connected, and these electric components are driven based on the control of a game control microcomputer 100 described later mounted on the game control board 40.

  The game control board 40 includes a game control microcomputer 100, an external memory (SRAM) 50, a control clock generation circuit 42, a random number clock generation circuit 43, a switch circuit 44, a motor drive circuit 45, a solenoid drive circuit 46, and an LED. A drive circuit 47 is mounted.

  The game control microcomputer 100 is a one-chip microcomputer, and includes a CPU 505, a ROM 506, a RAM 507, and an I / O port 41d. The game control microcomputer 100 executes a control program stored in the ROM 506 to perform processing related to the progress of the game, and controls each part of the control circuit mounted on the game control board 40 directly or indirectly. To do. In this embodiment, the game control microcomputer 100 can only perform 16-bit or 32-bit bus access to an external device such as the SRAM 50.

  Here, the control clock generation circuit 42 generates a control clock CCLK that becomes an oscillation signal having a predetermined frequency outside the game control microcomputer 100. The control clock CCLK generated by the control clock generation circuit 42 is supplied to the clock circuit 502 via a control external clock terminal EXC of the game control microcomputer 100 as shown in FIG. 5, for example. The random number clock generation circuit 43 generates a random number clock RCK that is an oscillation signal having a predetermined frequency different from the oscillation frequency of the control clock CCLK, outside the game control microcomputer 100. The random number clock RCK generated by the random number clock generation circuit 43 is supplied to the random number circuits 509A and 509B (see FIG. 7), for example, via the random number external clock terminal ERC of the game control microcomputer 100. As an example, the oscillation frequency of the random number clock RCK generated by the random number clock generation circuit 43 may be set to be equal to or lower than the oscillation frequency of the control clock CCLK generated by the control clock generation circuit 42. Alternatively, the oscillation frequency of the random number clock RCK generated by the random number clock generation circuit 43 may be higher than the oscillation frequency of the control clock CCLK generated by the control clock generation circuit 42.

  The switch detection circuit 44 takes in detection signals input from switches connected directly to the game control board 40 or via the power supply board 101 and transmits them to the game control microcomputer 100. The motor drive circuit 45 transmits the motor drive signal output from the game control microcomputer 100 to the reel motors 32L, 32C, 32R. The solenoid drive circuit 46 transmits the solenoid drive signal output from the game control microcomputer 100 to the flow path switching solenoid 30. The LED drive circuit transmits the LED drive signal output from the game control microcomputer 100 to various displays and LEDs connected to the game control board 40.

  FIG. 7 shows a configuration example of the game control microcomputer 100 mounted on the game control board 40. The game control microcomputer 100 shown in FIG. 7 is, for example, a one-chip microcomputer, and includes an external bus interface 501, a clock circuit 502, a specific information storage circuit 503, a reset controller 504A, an interrupt controller 504B, and a CPU ( Central Processing Unit (505), ROM (Read Only Memory) 506, RAM (Random Access Memory) 507, timer circuit 508, 16-bit random number circuit 509A, 8-bit random number circuit 509B, and free-run counter 509C And a PIP (Parallel Input Port) 510, a serial communication circuit 511, and an address decoding circuit 512.

  FIG. 8 shows an example of an address map in the game control microcomputer 100. As shown in FIG. 8, the area from address 0000H to address 2FFFH is allocated to the ROM 506 and includes a user program area and a program management area. The subscript H indicates a hexadecimal number, and the same applies to the following description. FIG. 9A shows an example of the usage and contents of the main part of the program management area in the ROM 506. The area from address F000H to address F3FFH is a work area assigned to the RAM 507, and can be assigned to an I / O map or a memory map. The area from address FE00H to address FEBFH is a built-in register area assigned to the built-in registers of the game control microcomputer 100. FIG. 9B shows an example of the usage and contents of the main part of the built-in register area.

  The program management area is a storage area for storing information necessary for the CPU 505 to execute the user program. As shown in FIG. 9A, the program management area includes a header KHDR, a reset setting KRES, an interrupt initial setting KIIS, a 16-bit random number initial setting 1st KRL1, a 16-bit random number initial setting 3rd KRL3, and an 8-bit random number initial setting 1st. 1KRS1, 8-bit random number initial setting second KRS2, security time setting KSES, and the like are included.

  The header KHDR stored in the program management area indicates the internal data read setting in the game control microcomputer 100. FIG. 10A illustrates the correspondence between setting data and operation in the header KHDR. Here, in the game control microcomputer 100, the ROM read prevention function and the bus output mask function can be set. The ROM read prevention function is a function for permitting or prohibiting the read operation for the data stored in the ROM 506 provided in the game control microcomputer 100. When the read prohibition is set, the data stored in the ROM 506 cannot be read. The bus output mask function is an address bus output, data bus output, and control signal in the external bus interface 501 when an external device connected to the external bus interface 501 makes a read request for internal data of the game control microcomputer 100. This function makes it impossible to read internal data from an external device by masking the output. As shown in FIG. 10A, the operation combination of the ROM read prevention function and the bus output mask function is set differently in accordance with the setting data of the header KHDR. Of the setting data shown in FIG. 10A, the setting data for which ROM reading is permitted and the bus output mask is valid is also referred to as bus output mask valid data. Further, the setting data (all “00H”) in which ROM reading is prohibited and the bus output mask is valid is also referred to as ROM reading prohibiting data. The setting data for which ROM reading is permitted and the bus output mask becomes invalid is also referred to as bus output mask invalid data.

  The reset setting KRES stored in the program management area indicates the setting of the reset operation in the game control microcomputer 100. FIG. 10B shows an example of setting contents in the reset setting KRES. The bit number [7] of the reset setting KRES is setting data for setting an operation when an internal reset occurs in the game control microcomputer 100. The internal reset in the game control microcomputer 100 is caused by a predetermined factor such as a time-out signal output from the watchdog timer 520 provided in the reset controller 504A, or the prohibition of running outside the designated area (IAT). Is a reset generated by.

  In the example shown in FIG. 10B, when the bit value in the bit number [7] of the reset setting KRES is “0”, the reset operation when the internal reset occurs is set to the user reset. When a user reset is executed, for example, the interrupt controller 504B, the CPU 505, the timer circuit 508, the free-run counter 509C, the PIP 510, and the serial communication circuit 511 are initialized, and the user program is reset from the user program reset address (ROM 506 address 0000H). Run the program again. On the other hand, when the bit value in the bit number [7] of the reset setting KRES is “1”, the reset operation when the internal reset occurs is set to the system reset. When the system reset is executed, all internal circuits in the game control microcomputer 100 including, for example, the 16-bit random number circuit 509A and the 8-bit random number circuit 509B are initialized, and the reset address of the user program Re-execute the user program.

  The bit number [6] of the reset setting KRES is setting data for setting the activation method of the watchdog timer 520 provided in the reset controller 504A. In the example shown in FIG. 10B, when the bit value in the bit number [6] of the reset setting KRES is “0”, the operation state of the gaming control microcomputer 100 shifts from the security mode to the user mode. As a result, the watchdog timer 520 is automatically started. On the other hand, when the bit value is “1”, a user program (an initial setting program for game control and a game control processing program) based on the control code read from the ROM 506 by the CPU 505 of the game control microcomputer 100. ) To start the watchdog timer 520 by software. In this way, by storing in advance the setting data in which the bit value in the bit number [6] of the reset setting KRES stored in the program management area of the ROM 506 is “1”, the software by executing the user program The watchdog timer 520 can be activated by a predetermined WDT activation control code to validate the reset operation, or the watchdog timer 520 can be deactivated by the predetermined WDT stop control code to invalidate the reset operation.

  The bit number [5-4] of the reset setting KRES is setting data for setting a reference clock used for setting the timeout time of the watchdog timer 520. In the example shown in FIG. 10B, depending on whether the bit value in the bit number [5-4] of the reset setting KRES is “00”, “01”, “10”, or “11”. A reference clock with a different period is set. The bit number [3-0] of the reset setting KRES is setting data for setting a timeout time of the watchdog timer 520 by being used for multiplication with a setting period corresponding to the bit value in the bit number [5-4]. is there. In the example shown in FIG. 10B, when the bit value in the bit number [3-0] of the reset setting KRES is “0000”, the monitoring time measurement by the watchdog timer 520 is prohibited and the watchdog is disabled. Use it. On the other hand, when those bit values are “1000”, the timeout period of the watchdog timer 520 is set by multiplying the set period by “8”. When those bit values are “1111”, the time-out time of the watchdog timer 520 is set by multiplying the set period by “15”.

  As described above, by setting the bit values in the bit number [5-4] and the bit number [3-0] of the reset setting KRES, the monitoring time measured by the watchdog timer 520 has a plurality of predetermined types. Can be set from In the example shown in FIG. 10B, when the bit value in the bit number [5-4] of the reset setting KRES is “11” and the bit value in the bit number [3-0] is “1111”, the monitoring time The maximum time that can be set as is set. As an example, when the frequency of the internal system clock SCLK is 10.0 MHz, the longest monitoring time is about 50.33 seconds. As another example, when the frequency of the internal system clock SCLK is 12.0 MHz, the longest monitoring time is about 41.94 seconds.

  Interrupt initial settings KIIS stored in the program management area indicate initial settings related to handling of maskable interrupts generated in the game control microcomputer 100. FIG. 11A shows an example of setting contents in the interrupt initial setting KIIS.

  In the bit number [7-4] of the interrupt initial setting KIIS, the upper 4 bits of the interrupt vector are set. In the bit number [3-0] of the interrupt initial setting KIIS, a combination of maskable interrupt factor priorities is set. In the example shown in FIG. 11A, if any of “00H” to “02H” is specified by the bit number [3-0] of the interrupt initial setting KIIS, the maskable interrupt factor from the timer circuit 508 is given the highest priority. A combination of priorities is set. On the other hand, if either “03H” or “04H” is specified, a combination of priorities that gives the highest priority to the maskable interrupt factor from the serial communication circuit 511 is set. If either “05H” or “06H” is designated, a combination of priorities that gives the highest priority to maskable interrupt factors from the random number circuits 509A and 509B is set. Note that even if the priority combination has the highest priority for maskable interrupt factors from the same circuit, if the specified value is different, the type of maskable interrupt factor that has the highest priority, the priority combination in the second or lower order, etc. will differ. ing.

  16-bit random number initial setting 1st KRL1 to 16-bit random number initial setting 3rd KRL3 stored in the program management area indicate initial settings for the 16-bit random number circuit 509A. FIG. 11B shows an example of setting contents in the 16-bit random number initial setting first KRL1. FIG. 11C shows an example of setting contents in the 16-bit random number initial setting third KRL3. In this embodiment, the 16-bit random number circuit 509A can independently generate 16-bit pseudo random numbers of the four channels ch0 to ch3.

  Bit number [7] of the 16-bit random number initial setting first KRL1 sets the method of starting the 16-bit random number circuit 509A in order to generate the 16-bit random number of the channel ch1 The random number circuit start for the 16-bit random number channel ch1 Setting data. In the example shown in FIG. 11B, when the bit value in the bit number [7] of the 16-bit random number initial setting first KRL1 is “0”, the maximum value in the 16-bit random number of the channel ch1 is set as the user program (software ) Is activated, a circuit for generating a 16-bit random number of channel ch1 is activated. On the other hand, when the bit value is “1”, the operation state of the gaming control microcomputer 100 shifts from the security mode to the user mode, thereby generating a 16-bit random number of the channel ch1. The circuit is automatically activated.

  The bit number [6] of the 16-bit random number initialization first KRL1 is a random number update clock RGK (see FIG. 17) used for updating numerical data to be a random value when generating a 16-bit random number of the channel ch1. This is random number update clock setting data for the 16-bit random number channel ch1 for setting whether to use the internal system clock SCLK or to divide the random number clock RCK by two (RCK / 2). In the example shown in FIG. 11B, when the bit value in the bit number [6] of the 16-bit random number initial setting first KRL1 is “0”, the internal system clock SCLK is set to be used as the random number update clock RGK. On the other hand, in the case of “1”, the setting is made such that the random number clock RCK divided by two (RCK / 2) is used as the random number update clock RGK.

  The 16-bit random number initial setting 1st KRL1 bit number [5-4] sets whether or not to change the random number update rule when generating the 16-bit random number of channel ch1, and the change method in the case of changing 16 This is random number update rule setting data for the bit random number channel ch1. In the example shown in FIG. 11B, when the bit value in the bit number [5-4] of the 16-bit random number initial setting first KRL1 is “00”, the random number update rule is not changed, and “01” is set. Is set to change the random number update rule by software. When it is “10”, the random number update rule is automatically changed from the second round. When it is “11”, The random number update rule is automatically changed from the first round.

  In the example shown in FIG. 11B, the bit numbers [3], [2], and [1-0] of the 16-bit random number initial setting first KRL1 are the random number circuit start setting data and the random number for the 16-bit random number channel ch0, respectively. This is update clock setting data and random number update rule setting data. That is, the bit number [3-0] of the 16-bit random number initial setting first KRL is the same as the case of initializing the 16-bit random number of the channel ch1 by the bit number [7-4]. Is the setting data for performing the initial setting.

  Note that the bit numbers [7], [6], and [5-4] of the 16-bit random number initial setting second KRL2 are the random number circuit start setting data, random number update clock setting data, and random number update rule for the 16-bit random number channel ch3, respectively. Setting data. Bit numbers [3], [2], and [1-0] of the 16-bit random number initial setting second KRL2 are the random number circuit start setting data, random number update clock setting data, and random number update rule setting data for the 16-bit random number channel ch2, respectively. It has become.

  Bit number [7] and bit number [6] of 16-bit random number initial setting 3rd KRL3 set a start value in numerical data to be a 16-bit random number of channel ch3. Random number start value setting data for 16-bit random number channel ch3 It is. In the example shown in FIG. 11C, when the bit value in the bit number [7] of the 16-bit random number initial setting third KRL3 is “0”, the start value is set to “0000H” which is a predetermined default value. On the other hand, in the case of “1”, a value based on the ID number, which is unique identification information given to each game control microcomputer 100, is set as the start value. In the example shown in FIG. 11C, when the bit value [6] of the 16-bit random number initial setting third KRL3 is “0”, the start value is not changed at every system reset. On the other hand, when “1” is set, the start value is changed every time the system is reset.

  When the start value is set to a value based on the ID number, a part or all of the calculation for performing a predetermined scramble process on the ID number and the calculation such as addition / subtraction / multiplication / division using the ID number are performed. It is only necessary to execute and use the calculated value as the start value. Further, when the bit value in the bit number [6] of the 16-bit random number initial setting third KRL3 is “1”, the count in a predetermined free-run counter (for example, the free-run counter 509C shown in FIG. 7) is performed every system reset. A value set based on the value may be used as the start value. Further, when the bit values [7] and [6] of the 16-bit random number initial setting third KRL3 are both “1”, the bit number is set based on the ID number and the count value in the free-run counter. Can be used as the start value.

  Bit number [5] and bit number [4] of the 16-bit random number initial setting third KRL3 set the start value in the numerical data that becomes the 16-bit random number of the channel ch2 The random number start value setting data for the 16-bit random number channel ch2 It is. That is, the bit number [5] and the bit number [4] of the 16-bit random number initial setting third KRL3 are the same as the case where the 16-bit random number of the channel ch3 is initialized by the bit number [7] and the bit number [6]. And setting data for initial setting of a 16-bit random number of channel ch2. Bit number [3] and bit number [2] of the 16-bit random number initial setting third KRL3 are random number start value setting data for the 16-bit random number channel ch1. Bit number [1] and bit number [0] of 16-bit random number initial setting third KRL3 are random number start value setting data for 16-bit random number channel ch0.

  The 8-bit random number initial setting 1st KRS1 and the 8-bit random number initial setting 2nd KRS2 stored in the program management area indicate the initial setting for the 8-bit random number circuit 509B. In this embodiment, the 8-bit random number circuit 509B can independently generate 8-bit pseudo random numbers of the four channels ch0 to ch3. The 8-bit random number initial setting first KRS1 is a random number circuit start setting data, a random number update clock setting data, a random number update rule setting data for the 8-bit random number channel ch1, a random number circuit start setting data for the 8-bit random number channel ch0, and a random number update. Clock setting data and random number update rule setting data are included. The 8-bit random number initial setting second KRS2 is a random number circuit start setting data, a random number update clock setting data, a random number update rule setting data for the 8-bit random number channel ch3, a random number circuit start setting data for the 8-bit random number channel ch2, and a random number update. Clock setting data and random number update rule setting data are included. That is, the 8-bit random number initial setting 1st KRS1 and the 8-bit random number initial setting 1st KRS2 perform the initial setting for the 16-bit random numbers of the channel ch0 to the channel ch3 by the 16-bit random number initial setting 1st KRL1 and the 16-bit random number initial setting 2nd KRL2. Similarly, the setting data for performing the initial setting for the 8-bit random numbers of channel ch0 to channel ch3.

  The security time setting KSES stored in the program management area indicates a setting for extending the security mode time (security mode time) that is the operation state of the game control microcomputer 100 when the power is turned on. Here, when the operation state of the game control microcomputer 100 is the security mode, a predetermined security check process is executed to check whether or not the content stored in the ROM 506 has been changed. FIG. 12 shows an example of setting contents in the security time setting KSES.

  Bit number [7-6] of security time setting KSES indicates a time setting when the security mode time is extended by a random time every system reset. In the example shown in FIG. 12, if the bit value in the bit number [7-6] of the security time setting KSES is “00”, the random time extension is not performed. On the other hand, if the bit value is “01”, the short mode is set, if “10”, the middle mode is set, and if “11”, the long mode is set. Here, when the short mode, the middle mode, or the long mode is designated, for example, the count value of the free-run counter built in the game control microcomputer 100 is used as the game control microcomputer 100 when a system reset occurs. Is stored in a predetermined built-in register (variable security mode time register). Then, by using the stored value of the variable security time register as it is at the time of initialization, or by using the value obtained by substituting the stored value into a predetermined arithmetic function (for example, a hash function), the security mode time The extension time at the time of extending may be determined at random.

  As an example, when the frequency of the internal system clock SCLK is 10.0 MHz, the extension time is randomly determined in the range of 0 to 816 μs (microseconds) in the short mode, and 0 to 26.112 ms (milliseconds) in the middle mode. In the long mode, and the extension time is randomly determined in the range of 0 to 8355.584 ms. As another example, when the frequency of the internal system clock SCLK is 12.0 MHz, the extension time is randomly determined in the range of 0 to 510 μs in the short mode and in the range of 0 to 16.32 ms in the middle mode. In the long mode, the extension time is randomly determined in a range of 0 to 522.24 ms.

  The variable security mode time register only needs to be backed up using a backup power source common to the backup location on the main board 11, such as a backup area in the RAM 507 of the game control microcomputer 100. Alternatively, the variable security mode time register may be backed up by a power source provided separately from a backup power source used for a backup area in the RAM 507 or the like. In this way, the variable security mode time register is backed up by the backup power supply, so that the stored value of the variable security mode time register is saved for a predetermined period even when the power supply is stopped. Note that the timing at which the count value in the free-run counter is read and stored in the variable security mode time register is not limited to when a system reset occurs, and may be any predetermined timing. Alternatively, the free run counter may be backed up by a backup power source, and the extension time for extending the security mode time may be determined at random using the stored value read from the free run counter at the initial setting.

  Also, the short time, middle mode, and long mode are set by the bit value [7-6] of the security time setting KSES, and the bit value [4-0] of the security time setting KSES is set to By setting a value other than “0001”, the extension time added to the fixed time can be set. In this case, both the extension time corresponding to the bit value in the bit number [4-0] and the extension time randomly determined based on the bit value in the bit number [7-6] are fixed times. In addition, the security mode time during which the game control microcomputer 100 is in the security mode is determined.

  The external bus interface 501 provided in the game control microcomputer 100 shown in FIG. 7 includes an interface function between the external bus and the internal bus of the chip constituting the game control microcomputer 100, an address bus, a data bus, and each control signal. A bus interface having a direction control function and the like. For example, the external bus interface 501 is connected to an external memory, an external input / output device or the like externally attached to the game control microcomputer 100, and address signals, data signals, various control signals, etc. with these external devices As long as it transmits and receives. In this embodiment, the external bus interface 501 includes an internal resource access control circuit 501A.

  The internal resource access control circuit 501A controls access to the internal data of the game control microcomputer 100 from an external device via the external bus interface 501, and for example, a game control program (game control processing program) stored in the ROM 506 And a circuit for limiting inappropriate external reading of internal data such as fixed data. Here, a circuit analysis device such as an in-circuit emulator (ICE; InCircuit Emulator) may be connected to the external bus interface 501 as an external device.

  As an example, according to the contents of the header KHDR stored in the program management area of the ROM 506, it is possible to switch between prohibiting or permitting reading of stored data in the ROM 506. For example, when the header KHDR is bus output mask invalid data, the ROM 506 can be read by an external device, and external reading of internal data is permitted. On the other hand, if the header KHDR is bus output mask valid data, the ROM 506 can be read from the external device by masking the address bus output, data bus output and control signal output in the external bus interface 501, for example. Is disabled, and external reading of internal data is prohibited. In this case, when reading of internal data is requested from an external device connected to the external bus interface 501, a predetermined fixed value is output so that internal data cannot be read from the external device. . Further, when the header KHDR is ROM read prohibition data, the ROM 506 itself may not be read, and reading of stored data in the ROM 506 may be prevented. For example, in a ROM at the manufacturing stage, by making the header KHDR ROM read prohibition data, the ROM itself is made unreadable, and if it is a development ROM, bus output mask invalid data is written in the header KHDR, Allows verification of internal data by an external device. On the other hand, if the ROM for mass production is used, the bus output mask valid data is written in the header KHDR, so that the ROM 506 can be read by the CPU 505 and the like inside the game control microcomputer 100, while the external device It is only necessary to prevent the ROM 506 from being read.

  As another example, the internal resource access control circuit 501A is requested by an external device connected to the external bus interface 501 to read out internal data of the game control microcomputer 100 such as part or all of the stored data in the ROM 506. Detect that. When this read request is detected, the internal resource access control circuit 501A determines whether or not reading of internal data of the game control microcomputer 100 is permitted. For example, it is assumed that encryption processing is performed on part or all of the storage data in the ROM 506. In this case, if the read request from the external device is a read request for the encryption processing program or key data stored in the ROM 506, the internal resource access control circuit 501A rejects the read request, and the game control micro Reading of the internal data of the computer 100 is prohibited. In the external bus interface 501, a switch element is provided between the output port from which data stored in the ROM 506 is output and the internal bus. When the internal resource access control circuit 501 A prohibits reading of the internal data, the switch element May be controlled to be turned off. As described above, the internal resource access control circuit 501A reads the internal data depending on whether or not the read request from the external device requests reading of predetermined internal data (for example, a predetermined area of the ROM 506). You may make it determine whether it prohibits or permits.

  Alternatively, the internal resource access control circuit 501A may determine whether or not a predetermined authentication code has been input from an external device when detecting a read request for internal data. In this case, for example, a predetermined code pattern serving as an authentication code may be stored in advance in the internal resource access control circuit 501A or in a predetermined area of the ROM 506. When an authentication code is input from the external device, the authentication code is compared with the authentication code stored in the internal device. If they match, a read request is accepted and the internal data of the game control microcomputer 100 is read. To give permission. On the other hand, if the authentication code input from the external device does not match the authentication code stored internally, the read request is rejected and reading of the internal data of the game control microcomputer 100 is prohibited. As described above, the internal resource access control circuit 501A determines whether to prohibit or permit reading of the internal data depending on whether or not the authentication code input from the external device matches the authentication code stored internally. You may make it do. Thereby, it is possible to read out the internal data of the game control microcomputer 100 using a correct authentication code known in advance by an inspection organization or the like, and to properly inspect the validity of the internal data. become.

  As yet another example, a read prohibition flag is provided in the internal resource access control circuit 501A, and reading of the ROM 506 by an external device is prohibited if the read prohibition flag is on. On the other hand, when the reading prohibition flag is in the off state, reading of the ROM 506 by the external device is permitted. Here, the read prohibition flag is off in the initial state, but once the read prohibition flag is turned on, the read prohibition flag cannot be cleared and returned to the off state. That's fine. That is, the read prohibition flag can be irreversibly changed from the off state to the on state. For example, the internal resource access control circuit 501A does not have a function of clearing the read prohibition flag to turn it off, and is set so that the read prohibition flag cannot be cleared by any instruction. Just do it. Then, the internal resource access control circuit 501A determines whether or not the read prohibition flag is on when the external device requests to read internal data of the game control microcomputer 100 such as data stored in the ROM 506. At this time, if the reading prohibition flag is on, the reading request from the external device is rejected, and reading of the internal data of the gaming control microcomputer 100 is prohibited. On the other hand, if the read prohibition flag is OFF, a read request from an external device is accepted and reading of the internal data of the game control microcomputer 100 is permitted. With such a configuration, a provider who creates a game control processing program for game control and stores it in the ROM 506 can load a program that has been debugged from the ROM 506 with the read prohibition flag off. Can be read. Then, when shipping after the debugging work is completed, by setting the read prohibition flag to the on state, external reading of the ROM 506 can be restricted thereafter, and the ROM 506 by the user of the slot machine 1 or the like can be restricted. Can be prevented from being read. As described above, the internal resource access control circuit 501A may determine whether to prohibit or permit reading of internal data depending on whether an internal flag such as a read prohibition flag is off or on. .

  Note that the read prohibition flag is not set irreversibly but can be changed from the on state to the off state, while the read prohibition flag is changed from the on state to the off state to permit reading of internal data. In this case, external reading of the ROM 506 may be restricted by erasing the data stored in the ROM 506 (for example, flash erasure).

  The clock circuit 502 included in the game control microcomputer 100 is a circuit that generates the internal system clock SCLK by, for example, dividing the oscillation signal input to the control external clock terminal EXC by two. In this embodiment, the control clock CCLK generated by the control clock generation circuit 111 is input to the control external clock terminal EXC. The internal system clock SCLK generated by the clock circuit 502 is supplied to various circuits such as the CPU 505 that control the progress of the game in the game control microcomputer 100. The internal system clock SCLK is also supplied to random number circuits 509A and 509B. Furthermore, the internal system clock SCLK may be output from the system clock output terminal CLKO connected to the clock circuit 502 to the outside of the game control microcomputer 100. It is desirable that the internal system clock SCLK is not output to the outside of the game control microcomputer 100. As described above, by limiting the external output of the internal system clock SCLK, it becomes difficult to specify the operation cycle of the internal circuit (such as the CPU 505) of the game control microcomputer 100 from the outside, and numerical data that becomes a random value Can be prevented from being specified from the outside when the software is updated by software.

  The unique information storage circuit 503 included in the game control microcomputer 100 is a circuit that stores a plurality of types of unique information that is internal information of the game control microcomputer 100, for example. As an example, the unique information storage circuit 503 stores three types of unique information such as a ROM code, a chip individual number, and an ID number. The ROM 506 code is a 4-byte numerical value generated from stored data in a predetermined area of the ROM 506, and four numerical values with different generation methods may be prepared. The chip individual number is a 4-byte number assigned when the game control microcomputer 100 is manufactured, and represents a different numerical value for each chip constituting the game control microcomputer 100. The ID number is an 8-byte number assigned when the game control microcomputer 100 is manufactured, and indicates a different numerical value for each chip constituting the game control microcomputer 100. Here, the chip individual number may be read from the user program, while the ID number may be set so as not to be read from the user program. The unique information storage circuit 503 may be included in the ROM 506 by using a predetermined area of the ROM 506, for example. Alternatively, the unique information storage circuit 503 may be included in the CPU 505 by using a built-in register of the CPU 505, for example.

  The reset controller 504A included in the game control microcomputer 100 is for controlling various resets generated inside or outside the game control microcomputer 100. The reset controlled by the reset controller 504A includes a system reset and a user reset. The system reset is a reset that occurs when a low level signal is input to the external system reset terminal XSRST for a certain period. The user reset is a reset that occurs due to a predetermined factor, such as a watchdog timer (WDT) time-out signal is generated or an out-of-designated area travel prohibition (IAT) is generated.

  The reset controller 504A uses the internal information register CIF (address FE25H) among the built-in registers included in the game control microcomputer 100 as shown in FIG. It enables recording of abnormalities in the bit random number and random number clock RCK. FIG. 13A shows a configuration example of the internal information register CIF. FIG. 13B shows an example of setting contents in each bit of the internal information data stored in the internal information register CIF.

  The internal information data CIF7 to CIF4 stored in the bit number [7-4] of the internal information register CIF correspond to the 16-bit random numbers of the channels ch3 to ch0, and are random numbers indicating the presence or absence of abnormality in the random number value update operation. This is an update abnormality instruction. In the example shown in FIG. 13B, the bit value in each of the internal information data CIF7 to CIF4 is “0” when no abnormality in the update operation is detected for the 16-bit random numbers of channel ch3 to channel ch0. On the other hand, when an abnormality is detected in the 16-bit random number update operation, the bit value in any of the internal information data CIF7 to CIF4 becomes “1” corresponding to the channel in which the abnormality is detected. More specifically, if the channel in which an abnormality is detected in the 16-bit random number update operation is channel ch3, the internal information data CIF7 is “1”, and if the channel is channel 2, the internal information data CIF6 is “1”. If it is channel ch1, the internal information data CIF5 is “1”, and if it is channel ch0, the internal information data CIF4 is “1”.

  The internal information data CIF3 stored in the bit number [3] of the internal information register CIF is a random number clock abnormality instruction indicating the presence or absence of a frequency abnormality in the random number clock RCK. In the example shown in FIG. 13B, when the frequency abnormality of the random number clock RCK is not detected, the bit value of the internal information data CIF3 becomes “0”, whereas when the frequency abnormality is detected, the bit value is “1”. The internal information data CIF2 stored in the bit number [2] of the internal information register CIF is a system reset instruction indicating whether or not the reset factor generated immediately before is a system reset. In the example shown in FIG. 13B, when the immediately preceding reset factor is not a system reset (system reset has not occurred), the bit value of the internal information data CIF2 is “0”, whereas when the system reset is a system reset (system When the reset occurs), the bit value becomes “1”. As a first example of the operation using the internal information data CIF2, the CPU 505 of the game control microcomputer 100 checks the bit value of the internal information data CIF2 when the power is turned on, and the bit value is “1” (set). If not, it is determined that the power is not turned on normally. At this time, for example, by transmitting a predetermined effect control command to the effect control board 90, an illegal signal input action may be performed aiming at a big hit gaming state immediately after power-on in the slot machine 1 You may notify that there exists property by a production apparatus etc. Further, as a second example of the operation using the internal information data CIF2, when the slot machine 1 reports the probability variation state only when the power is turned on and does not inform the probability variation state normally, the gaming control microcomputer 100 is turned on when the power is turned on. The CPU 505 or the like may check the bit value of the internal information data CIF2, and if the bit value is not “1” (set), the gaming state may not be notified.

  Whether internal information data CIF1 stored in bit number [1] of internal information register CIF is a user reset due to a timeout of watchdog timer (WDT) 520 incorporated in reset controller 504A is the reset factor generated immediately before. This is a watchdog timeout instruction that indicates In the example shown in FIG. 13B, when the reset factor immediately before is not a user reset due to timeout of the watchdog timer 520 (no timeout occurs), the bit value of the internal information data CIF1 becomes “0”, while When a user reset is caused by a timeout of the dog timer 520 (timeout occurs), the bit value becomes “1”. The internal information data CIF0 stored in the bit number [0] of the internal information register CIF is an IAT generation instruction indicating whether or not the reset factor generated immediately before is a user reset due to prohibition of travel outside the designated area (IAT). . In the example shown in FIG. 13B, when the reset factor immediately before is not a user reset due to the occurrence of travel outside the designated area (no IAT occurrence), the bit value of the internal information data CIF0 becomes “0”, while When the user reset is caused by the occurrence of out-of-area travel (the occurrence of IAT), the bit value becomes “1”.

  A watchdog timer 520 is built in the reset controller 504A. The watchdog timer 520 is a time-out signal for restarting the game control microcomputer 100 in a reset state when the game control microcomputer 100 cannot execute the user program normally and a predetermined monitoring time has elapsed. Is output. Note that the watchdog timer 520 may be externally attached to the reset controller 504A while being incorporated in the game control microcomputer 100. Alternatively, the watch dog timer 520 may be externally attached to the game control microcomputer 100.

  FIG. 14 shows a configuration example of the watchdog timer 520. The activation method of the watchdog timer 520 is set by the bit value in the bit number [6] of the reset setting KRES stored in the program management area of the ROM 506. In this embodiment, the bit value in the bit number [6] of the reset setting KRES is set in advance in order to activate the watchdog timer 520 by software by executing the user program and enable the reset operation. Setting data “1” is stored. Further, the bit value in the bit number [5-4] of the reset setting KRES is set so that the time-out time as the monitoring time measured by the watchdog timer 520 becomes the longest time among a plurality of settable monitoring times. The setting data in which the bit value in the bit number [3-0] of the reset setting KRES is set to “1111” in advance is stored together with the setting data set to “11” in advance.

  The watchdog timer 520 shown in FIG. 14 includes a WDT control circuit 533, a count clock generation circuit 535, a 16-bit up counter 536, and an output control circuit 537. The WDT control circuit 533 is a circuit that controls the operation of the watchdog timer 520. The WDT control circuit 533 sets the reference clock generated by the count clock generation circuit 535 and the time-out in the 16-bit up counter 536 to operate the watchdog timer 520 based on the reset setting KRES of the program management area. Set the time.

  Further, the WDT control circuit 533 has a predetermined WDT activation control code set in the WDT start register WST (address FE23H) among the built-in registers provided in the game control microcomputer 100 as shown in FIG. 9B. Thus, the software by the execution of the user program can be switched so that the watchdog timer 520 is activated and the reset operation is validated, or the watchdog timer 520 is deactivated and the reset operation is invalidated. FIG. 15A shows a configuration example of the WDT start register WST. FIG. 15B shows an example of setting contents by WDT start data stored in the WDT start register WST.

  In the example shown in FIGS. 15A and 15B, when “CCH” is written to the WDT start register WST by the CPU 505, the watchdog timer 520 is activated to enable the reset operation due to the elapse of the timeout time. . On the other hand, when “33H” is written to the WDT start register WST by the CPU 505, the watchdog timer 520 is stopped and the reset operation due to the elapse of the timeout time is invalidated. As described above, the data indicating the value of “CCH” serving as the WDT activation control code is written to the WDT start register WST, whereby the watchdog timer 520 is activated. On the other hand, the data indicating the value of “33H” serving as the WDT stop control code is written into the WDT start register WST, whereby the watchdog timer 520 is stopped.

  Further, the WDT control circuit 533 is configured by setting predetermined WDT clear data in the WDT clear register WCL (address FE24H) among the built-in registers provided in the game control microcomputer 100 as shown in FIG. 9B. The watchdog timer 520 count is cleared and restarted. FIG. 16A shows a configuration example of the WDT clear register WCL. FIG. 16B shows an example of setting contents by WDT clear data stored in the WDT clear register WCL.

  In the example shown in FIGS. 16A and 16B, when “55H” is written to the WDT clear register WCL by the CPU 505 and then “AAH” is written by the CPU 505, the WDT control circuit 533 is increased by 16 bits. The count value of the counter 536 is cleared and the count operation is restarted. Thus, the measurement of the timeout time as the monitoring time in the watchdog timer 520 is initialized and restarted by sequentially writing WDT clear data having different values of “55H” and “AAH” in the WDT clear register WCL. Can do. Note that the WDT clear data consisting of “55H” and “AAH” does not need to be written continuously for 2 bytes, but it is necessary to write in this order.

  The count clock generation circuit 535 generates a reference clock for setting a timeout time using the internal system clock SCLK. The 16-bit up counter 536 counts the reference clock generated by the count clock generation circuit 535. When the count value reaches a predetermined value corresponding to the timeout time, the output control circuit 537 outputs a timeout signal. On the other hand, when the CPU 505 writes the WDT clear data to the WDT clear register WCL in a predetermined order before the timeout time elapses, the count value is cleared and restarted in the 16-bit up counter 535. For example, when the CPU 505 executes a process that becomes an infinite loop and the operation state of the game control microcomputer 100 shifts to the standby state, the watch dog timer 520 is activated to enable the reset operation due to the elapse of the timeout time. At this time, since WDT clear data is not written to the WDT clear register WCL, the count value of the 16-bit up counter 535 reaches a predetermined value and a timeout occurs. The output control circuit 537 outputs the timeout signal from the 16-bit up counter 535 to the reset circuit of the reset controller 504A.

  The interrupt controller 504B provided in the game control microcomputer 100 is for controlling various interrupt requests generated inside or outside the game control microcomputer 100. Interrupts controlled by the interrupt controller 504B include a non-maskable interrupt NMI and a maskable interrupt INT. The non-maskable interrupt NMI is an interrupt that is unconditionally accepted even when the CPU 505 is in an interrupt-disabled state. is there. The maskable interrupt INT is an interrupt that can permit / prohibit acceptance of an interrupt request by a setting instruction of the CPU 505, and multiple interrupts can be executed by setting priority. The maskable interrupt INT is caused by the fact that a low level signal is input to the external maskable interrupt terminal XINT (also used as the input port PI5) for a certain period of time, and that a timeout occurs in the timer circuit included in the timer 508. Multiple types of interrupt factors such as the occurrence of an interrupt factor due to data reception or data transmission in the serial communication circuit 511, or the occurrence of an interrupt factor due to the acquisition of numerical data as a random value in the random number circuits 509A and 509B May be determined in advance.

  The interrupt controller 504B includes an interrupt mask register IMR (address FE26H), an interrupt wait monitor register IRR (address FE27H), and an interrupt monitor monitor register among the built-in registers included in the game control microcomputer 100 as shown in FIG. 9B. Interrupt control and reset management are performed using ISR (address FE28H) or the like. The interrupt mask register IMR is a register that sets what is used and what is not used among maskable interrupts INT caused by a plurality of different factors. The interrupt wait monitor register IRR is a register for confirming the generation state of a maskable interrupt request signal for each maskable interrupt factor set by the interrupt initial setting KIIS. The in-interrupt monitor register ISR is a register for confirming the processing state of the maskable interrupt request signal for each maskable interrupt factor set by the interrupt initial setting KIIS.

  A CPU 505 provided in the game control microcomputer 100 executes a user program (game control processing program for game control) based on a control code read from the ROM 506, thereby executing a game control in the slot machine 1. It is. When such game control is executed, a fixed data reading operation in which the CPU 505 reads fixed data from the ROM 506, a variable data writing operation in which the CPU 505 writes various variable data to the RAM 507 and temporarily stores the data, and the CPU 505 is temporarily stored in the RAM 507. The CPU 505 receives the various data from the outside of the game control microcomputer 100 via the external bus interface 501, the PIP 510, the serial communication circuit 511, and the like. A transmission operation for outputting various signals to the outside of the game control microcomputer 100 via the external bus interface 501 and the serial communication circuit 511 is also performed.

  As described above, in the game control microcomputer 100, the CPU 505 executes control in accordance with the program stored in the ROM 506. Therefore, the game control microcomputer 100 (or CPU 505) executes (or performs processing) hereinafter. Specifically, the CPU 505 executes control according to a program. The same applies to microcomputers mounted on boards other than the game control board 40.

  The ROM 506 provided in the game control microcomputer 100 stores a control code indicating a user program (game control processing program for game control), fixed data, and the like. The ROM 506 stores a security check program 506A. The CPU 505 reads the security check program 506A stored in the ROM 506 when the gaming control microcomputer 100 shifts to the security mode in response to the power-on of the slot machine 1 or the occurrence of a system reset, and the stored contents of the ROM 506 are changed. A security check process is executed to check whether or not it has been done. Note that the security check program 506A may be stored in a built-in memory different from the ROM 506. Further, the security check program 506A may correspond to a security check process for inspecting the storage content of an external memory externally attached to the game control microcomputer 100 via the external bus interface 501, for example.

  A RAM 507 provided in the game control microcomputer 100 provides a work area for game control. Here, at least a part of the RAM 507 may be a backup RAM that is backed up by a backup power source created in the power supply substrate 101. That is, even if the power supply to the slot machine 1 is stopped, at least a part of the contents of the RAM 507 is stored for a predetermined period.

  The timer circuit 508 provided in the game control microcomputer 100 is configured, for example, by incorporating an 8-bit programmable timer with three channels (PTC0 to PTC2), and enables real-time interrupt generation and time measurement. Each programmable timer PTC0-PTC2 has a timer value that is updated in response to a change in the count clock signal generated based on the internal system clock SCLK (for example, a falling timing that changes from a high level to a low level). If it is.

  The game control microcomputer 100 includes, as random number circuits, for example, a random number circuit 509A that generates numerical data that is a 16-bit random number, and a random number circuit 509B that generates numerical data that is an 8-bit random number. In this embodiment, on the game control board 40 side, numerical data indicating a random number value for internal lottery may be controlled so that it can be counted (updated). In addition, in order to improve a game effect, random numbers other than these may be used. Such random numbers used to control the progress of the game are also referred to as game random numbers.

  Based on the numerical data extracted from the random number circuits 509A and 509B, the CPU 505 uses a random counter different from the random number circuits 509A and 509B, for example, a random counter provided in a predetermined area (game control counter setting unit or the like) of the RAM 507. The numerical data indicating a part or all of the random number value may be counted by processing or updating various numerical data by software. Alternatively, the CPU 505 counts (updates) a part of numerical data indicating a random number value by software, for example, using only a random counter provided in the game control counter setting unit without using the random number circuits 509A and 509B. It may be. As an example, the numerical data extracted by the CPU 505 from the 16-bit random number circuit 509A serving as hardware is processed by software to update the numerical data indicating the random value for internal lottery, and other random values MR2 Numerical data indicating .about.MR5 may be updated by software by the CPU 505 using a random counter or the like.

  Alternatively, the CPU 505 counts numerical data indicating a random value for internal lottery by using a random counter or without using a random counter based on the numerical data extracted from the 16-bit random number circuit 509A. The random value for internal lottery is a random value for determining whether or not a winning for each combination is permitted. For example, the random number value for internal lottery takes a value in the range of “0” to “65535”.

  FIG. 17 is a block diagram illustrating an example of a circuit configuration corresponding to the channel ch0 in the 16-bit random number circuit 509A. As shown in FIG. 17, a circuit for generating a 16-bit random number corresponding to channel ch0 includes a random number update clock selection circuit 551, a random number generation circuit 553A, a random number activation setting circuit 553B, a start value setting circuit 553C, and a random number sequence. The circuit includes a change circuit 554A, a random number sequence change setting circuit 554B, a maximum value comparison circuit 555, a hard latch selector 558A, a hard latch random number value register 559A, and a soft latch random number value register 559S.

  For example, the random number update clock selection circuit 551 determines whether the bit value in the bit number [2] (in the case of channel ch0) of the 16-bit random number initial setting first KRL1 is “0” or “1”. The clock SCLK or the random number clock RCK divided by two (RCK / 2) is selected and output as the random number update clock RGK. The random number update clock RGK output from the random number update clock selection circuit 551 is input to the clock terminal of the random number generation circuit 553A and is used for incrementing the count value in the random number generation circuit 553A.

  The internal system clock SCLK or the random number clock RCK divided by two (RCK / 2) selected by the random number update clock selection circuit 551 may be input to the clock terminal of a predetermined clock flip-flop. In the clock flip-flop, the reverse phase output terminal (inverted output terminal) is connected to the data input terminal. The random number update clock RGK is output from the positive phase output terminal (non-inverted output terminal), while the latch clock is output from the negative phase output terminal (inverted output terminal). In this case, when the signal state of the clock signal input to the clock terminal changes in a predetermined manner, the clock flip-flop is connected from the positive phase output terminal (non-inverted output terminal) and the negative phase output terminal (inverted output terminal). The signal state in the output signal is changed. For example, the clock flip-flop has a rising timing at which the signal state of the clock signal changes from low level to high level, or a falling timing at which the signal state of the clock signal changes from high level to low level. At either timing, the input signal at the data input terminal is captured. At this time, from the positive phase output terminal (non-inverted output terminal), the input signal captured at the data input terminal is output without being inverted, while from the negative phase output terminal (inverted output terminal), The input signal captured at the data input terminal is inverted and output. Thus, the random-phase update clock RGK having an oscillation frequency that is ½ of the oscillation frequency of the clock signal is output from the positive phase output terminal (non-inverted output terminal) of the clock flip-flop, while the negative phase output terminal (inverted) From the output terminal, a latch phase clock (inverted signal) of the random number update clock RGK, that is, a latching clock having the same frequency as the random number update clock RGK and a phase different from the random number update clock RGK by π (= 180 °) is output. .

  The oscillation frequency of the random number clock RCK and the oscillation frequency of the control clock CCLK generated by the control clock generation circuit 111 are different from each other, and one of the oscillation frequencies is the other oscillation frequency. It is never an integer multiple of. As an example, while the oscillation frequency of the control clock CCLK is 11.0 MHz, the oscillation frequency of the random number clock RCK may be 9.7 MHz. Therefore, both the random number update clock RGK and the latch clock are oscillation signals whose signal states change at a different period from the control clock CCLK supplied to the CPU 505. That is, the clock flip-flop serves as a random number update clock RGK for updating the count value or a latch clock serving as a plurality of random number acquisition clocks based on the random number clock RCK generated by the random number clock generation circuit 112. Then, an oscillation signal whose signal state changes with a period different from the control clock CCLK and the internal system clock SCLK (the control clock CCLK divided by two) is generated.

  The random number generation circuit 553A is composed of a 16-bit counter, for example, and based on an input such as a random number update clock RGK output from the random number update clock selection circuit 551, a predetermined initial value within a predetermined range in which numerical data can be updated. Is a circuit that cyclically updates from a predetermined value to a predetermined final value. For example, the random number generation circuit 553A responds to the falling edge of the random number update clock RGK, which is an input signal to a predetermined clock terminal, from the initial value set within the range from “0” to “65535” to “65535”. The numerical data is counted up so that “1” is added to “1”. Then, after counting up to “65535”, the numerical data is updated cyclically by counting up from “0” to a numerical value that becomes a final value that is 1 smaller than the initial value.

  The random number activation setting circuit 553B starts random number generation that differs depending on whether the bit value in the bit number [3] (for channel ch0) of the 16-bit random number initial setting first KRL1 is “0” or “1”, for example. When the condition is satisfied, a setting is made to start a 16-bit random number generation operation. More specifically, when the corresponding bit value is “0”, when the maximum value in the 16-bit random number is designated by the user program (software), the random number generation circuit 553A is activated and the 16-bit random number Start the generation operation. On the other hand, if the corresponding bit value is “1”, the random number generation circuit 553A is activated to generate a 16-bit random number when the operation state of the gaming control microcomputer 100 shifts from the security mode to the user mode. Start operation.

  The start value setting circuit 553C sets the start value in the count value generated by the random number generation circuit 553A in accordance with the bit value in the bit number [1-0] (for channel ch0) of the 16-bit random number initial setting third KRL3, for example. Set. For example, the start value setting circuit 553C sets the start value to the default value “0000H” if the corresponding bit value is “00” or “01”, and the system reset if the bit value is “00”. While the start value is not changed every time, if the bit value is “01”, the start value is changed every time the system is reset. If the corresponding bit value is “10” or “11”, the start value is set to a value based on the ID number. If the bit value is “10”, the start value is not changed every time the system is reset. On the other hand, if the bit value is “11”, the start value is changed at every system reset.

  When the start value is changed at each system reset, the count value of the free-run counter 509C is used as it is at the time of initial setting, or the count value is obtained by substituting it into a predetermined arithmetic function (for example, a hash function). The start value may be determined at random by using the measured value. The free-run counter 509C only needs to be backed up using a backup power source common to the backup location on the game control board 40, such as a backup area in the RAM 507 of the game control microcomputer 100. Alternatively, the free-run counter 509C may be backed up by a power source provided separately from a backup power source used for a backup area or the like in the RAM 507. In this way, the free-run counter 509C is backed up by the backup power source, so that the count value in the free-run counter 509C is stored for a predetermined period even when the power supply is stopped.

  The free-run counter 509C is not limited to the one backed up by the backup power source. For example, when a system reset occurs, the count value of the free-run counter 509C is stored in a predetermined built-in register (for example, a random number start value register). May be backed up by a backup power source. Then, the initial value is randomly determined by using the stored value of the random number start value register as it is or by using the value obtained by substituting the stored value into a predetermined arithmetic function. Also good. In this case, the timing at which the count value in the free-run counter 509C is read and stored in the random number start value register is not limited to when a system reset occurs, and may be any predetermined timing. The free-run counter 509C may be a dedicated free-run counter that is built in the random number circuits 509A and 509B and is used to randomly determine the start value of the numerical data. That is, the free-run counter 509C may be provided as a separate configuration from the free-run counter used for randomly determining the extension time when extending the security time. Alternatively, a free-run counter 509C, which is built in the game control microcomputer 100 but is provided outside the random number circuits 509A and 509B, is used for random determination of the extension time when extending the security time. A common counter may be used. In this case, in the process of determining the start value of the numerical data and the process of randomly determining the extension time in the security time, for example, the calculation function for substituting the count value is different from each other, or one of the determinations is made In the process, the count value is used as it is, while in the other determination process, the value obtained by substituting the count value into a predetermined arithmetic function is used. It may be different.

  The free-run counter 509C may incorporate, for example, four channels (PCC0 to PCC3) of 8-bit programmable counters. Each of the programmable counters PCC0 to PCC3 only needs to have its count value updated in response to a signal change of the internal system clock SCLK or occurrence of a timeout in any of the programmable counters PCC0 to PCC3.

  The free-run counter 509C may be included in the random number circuits 509A and 509B, or may be included in the internal circuit of the game control microcomputer 100 although it is not included in the random number circuits 509A and 509B. In addition, the free-run counter 509C may be the same counter as the free-run counter used for randomly determining the extended time for extending the security time for each system reset, or provided separately. It may be a counter.

  The random number sequence change circuit 554A is a circuit that allows the permutation of numerical data generated by the random number generation circuit 553A to be changed to a permutation according to a predetermined random number update rule. For example, the random number sequence change circuit 554A executes bit scramble processing such as bit replacement or transposition in numerical data output from the random number generation circuit 553A. Further, the random number sequence changing circuit 554A can change the permutation of numerical data, for example, by changing a bit scramble key or a bit scramble table used for bit scramble processing.

  The random number sequence change setting circuit 554B changes the random number update rule in the random number sequence change circuit 554B in accordance with, for example, the bit value in the bit number [1-0] (in the case of channel ch0) of the 16-bit random number initial setting first KRL1. It is a circuit for setting. For example, the random number sequence change setting circuit 554B sets the random number update rule not to be changed if the corresponding bit value is “00”, and responds to a change request in software if the bit value is “01”. The random number update rule is changed. If the bit value is “10”, the random number update rule is automatically changed from the second round. If the bit value is “11”, the random number update rule is automatically changed from the first round.

  The random number sequence changing circuit 554B is for game control as shown in FIG. 9B when the corresponding bit value is “01” in the 16-bit random number initial setting first KRL1 and the random number update rule is changed by software. Among the built-in registers provided in the microcomputer 100, the random number update rule RDSC (address FE73H) is used to control the change of the random number update rule. FIG. 18A shows a configuration example of the random number sequence change register RDSC corresponding to the 16-bit random number of the channel ch0. FIG. 18B shows the setting contents of the random number sequence change request data stored in the random number sequence change register RDSC. The random number sequence change request data RDSC0 stored in the bit number [0] of the random number sequence change register RDSC indicates the presence / absence of a random number sequence change request when the random number update rule is changed by software. In the example shown in FIG. 18B, when there is no request for changing the random number sequence by software, the bit value of the random number sequence change request data RDSC0 is “0”. The bit value is “1”.

  FIG. 19 shows an operation example when the random number update rule is changed by software. In this case, when the count value permutation RCN output from the random number generation circuit 553A is cyclically updated from a predetermined initial value to a predetermined final value, the response is that the random number sequence change request data RDSC0 is “1”. Then, change the random number update rule. In the operation example shown in FIG. 19, the random number sequence RSN output from the random number sequence changing circuit 554A is “0 → 1 →... → 65535”. Thereafter, it is assumed that “1” is written to the bit number [0] of the random number sequence change register RDSC at a predetermined timing by the CPU 505 executing the user program stored in the ROM 506.

  Then, in response to the bit number [1-0] of the 16-bit random number initial setting first KRL1 being “01”, the random number sequence change setting circuit 554B reads the random number sequence change request data RDSC0, and the bit value is “ In response to 1 ″, a setting for changing the random number update rule is made. At this time, the random number sequence change setting circuit 554B selects one of a plurality of types of random number update rules prepared in advance, for example, in response to the count value permutation RCN output from the random number generation circuit 553A reaching a predetermined final value. The random number update rule is changed, for example, by selecting. In the operation example shown in FIG. 19, the random number sequence change circuit 554A outputs numerical data “65535” corresponding to the final value in the count value permutation RCN output from the random number generation circuit 553A, and then responds to the random number sequence change request data RDSC0. Change the random number update rule. Thereafter, the random number sequence changing circuit 554A outputs “65535 → 65534 →... → 0” as the random number sequence RSN according to the changed random number update rule. The random number sequence change register RDSC is initialized when the random number sequence change setting circuit 554B reads the random number sequence change request data RDSC0. Therefore, until the bit value “1” is written to the bit number [0] of the random number sequence change register RDSC again, the random number sequence RSN output from the random number sequence change circuit 554A is “65535 → 65534 →. Become.

  When the CPU 505 executes the user program stored in the ROM 506 and the bit value “1” is written again to the bit number [0] of the random number sequence change register RDSC, the random number update rule is changed again. In the operation example shown in FIG. 19, when the random number sequence change circuit 554A outputs the numerical data “0” corresponding to the final value in the random number sequence RSN, the bit value “1” is written as the random number sequence change request data RDSC0. Change the random number update rule accordingly. Thereafter, the random number sequence changing circuit 554A outputs “0 → 2 →... → 65534 → 1 →... → 65535” as the random number sequence RSN according to the changed random number update rule.

  FIG. 20 shows an operation example when the random number update rule is automatically changed. In this case, in response to the count value permutation RCN output from the random number generation circuit 553A being cyclically updated from a predetermined initial value to a predetermined final value, the random number sequence change setting circuit 554B automatically generates a random number update rule. To change. In the operation example shown in FIG. 20, the random number sequence RSN output from the random number sequence changing circuit 554A is “0 → 1 →... → 65535”.

  When the random number sequence RSN output from the random number sequence change circuit 554A reaches a predetermined final value, the random number sequence change setting circuit 554B determines a predetermined order from among a plurality of types of update rules prepared in advance. The update rule may be changed by selecting the update rule according to the above. Alternatively, the random number sequence change setting circuit 554B may change the update rule by selecting an arbitrary update rule from among a plurality of types of update rules. In the operation example shown in FIG. 20, the random number sequence RSN output from the random number sequence change circuit 554A becomes “65535 → 65534 →... → 0” due to the first change of the random number update rule. Thereafter, due to the second change in the random number update rule, the random number sequence RSN output from the random number sequence change circuit 554A becomes “0 → 2 →... → 65534 → 1 →. In the operation example shown in FIG. 20, the random number sequence RSN output from the random number sequence change circuit 554A is “65534 → 0 →... → 32768” due to the third change in the random number update rule. When the fourth random number update rule change is performed, the random number sequence RSN output from the random number sequence change circuit 554A becomes “16383 → 49151 →... → 49150”. When the fifth random number update rule change is performed, the random number sequence RSN output from the random number sequence change circuit 554A becomes “4 → 3 →... → 465553”.

  As described above, the random number sequence change circuit 554A changes the count value permutation RCN output from the random number generation circuit 553A based on a random number update rule predetermined by the setting of the random number sequence change setting circuit 554B. A random number sequence RSN in which data is updated by a predetermined procedure can be output.

  The maximum value comparison circuit 555 compares the maximum value of the random number preset by the user with the random number sequence RSN output from the random number sequence change circuit 554A, and if there is an output value greater than the maximum value, the random number generation circuit 553A Is instructed to reset and restart. The maximum value comparison circuit 555 sets a random number maximum value using a random number maximum value setting register RMX (addresses FE67 to FE72H) among the built-in registers included in the game control microcomputer 100 as shown in FIG. 9B. To do. FIGS. 21A and 21B show a configuration example of the random number maximum value setting register RL0MX corresponding to the 16-bit random number of the channel ch0 in the random number maximum value setting register RMX. The CPU 505 writes, for example, random number maximum value setting data indicating the maximum value of the random number specified in advance by the user program in the random number maximum value setting register RL0MX. When random number maximum value setting data is written in the random number maximum value setting register RL0MX, the maximum value is set for the 16-bit random number of the channel ch0. The maximum value of the 16-bit random number may be set to any value in the range of “256” to “65535”, for example. For example, if the bit value in the bit number [3] (in the case of channel ch0) of the 16-bit random number initial setting first KRL1 is “0”, the maximum value can be set for the 16-bit random number. By setting, a 16-bit random number generation operation can be started by a user program (software).

  Hard latch selector 558A selects a signal to be output as random number latch signal LL1 from input signals at input port PI0 to input port PI5 of PIP510. The hard latch selector 558A uses a hard latch selection register RL0LS0 included in the hard latch selection register RLS (address FE5B-FE61H) among the built-in registers included in the game control microcomputer 100 as shown in FIG. 9B. The signal to be output as the random number latch signal LL1 is selected. FIG. 22A shows a configuration example of the hard latch selection register RL0LS used as the hard latch selection register RL0LS0. FIG. 22B shows an example of setting contents in each bit of the hard latch selection data stored in the hard latch selection register RL0LS.

  The hard latch selection data RL03LS stored in the bit number [3] of the hard latch selection register RL0LS indicates a condition for fetching a random value by hardware. In the example shown in FIG. 22B, when the bit value of the hard latch selection data RL03LS is “0”, the stored value of the corresponding hard latch random value register (for example, the hard latch random value register 559A) is read. The next value is set to be latchable. On the other hand, when the bit value of the latch selection data RL03LS is “1”, the next value is set to be latchable without reading the stored value of the corresponding hard latch random value register.

  The hard latch selection data RL02LS to RL00LS stored in the bit numbers [2-0] of the hard latch selection register RL0LS are external terminals of signals output as corresponding random number latch signals (for example, one of the random number latch signals LL1 and LL2). Setting data for selecting an input. In the example shown in FIG. 22B, an input at any of the input ports PI0 to PI5 can be selected as an external terminal input in accordance with the values of the latch selection data RL02LS to RL00LS.

  In this embodiment, the detection signal SS1 from the start switch 7 is input to the input port PI0. The hard latch selector 558A selects the detection signal SS1 from the start switch 7 input to the input port PI0 based on the stored value of the hard latch selection register RL0LS0, and outputs it as a random number latch signal LL1. The random number latch signal LL1 may be output in synchronization with the first latching clock.

  The detection signal SS1 from the start switch 7 is not limited to that directly transmitted from the start switch 7. As an example, the time during which the output signal from the start switch 7 is on is measured, and when the measured time reaches a predetermined time (for example, 3 milliseconds), the detection signal SS1 from the start switch 7 is A timer circuit for outputting may be provided.

  Each of the hard latch random value registers 559A is a register that stores numerical data in the random number sequence RSN output from the maximum value comparison circuit 555 as a random value. Each of the hard latch random number registers 559A is a 16-bit (2-byte) register, and can store a 16-bit random value corresponding to the channel ch0, for example.

  In response to the fact that the random number latch signal LL1 supplied from the hard latch selector 558A is turned on, the hard latch random number value register 559A converts the numerical data in the random number sequence RSN output from the maximum value comparison circuit 555 into a random value. And store as The hard latch random value register 559A may be in a readable (enable) state when the register read signal supplied from the CPU 505 is turned on, and may output the stored numerical data to an internal bus or the like. On the other hand, when the register read signal is in the OFF state, the same value (for example, “65535H” or the like) may always be output to make the reading impossible (disabled) state. Further, the hard latch random value register 559A may be in a state in which it cannot receive the register read signal when the random number latch signal LL1 is in the ON state. Further, the hard latch random value register 559A is set so that it cannot receive the random number latch signal LL1 when the register read signal is turned on before the random number latch signal LL1 is turned on. Also good.

  The hard latch random number value register 559A includes a random number hard latch flag register RHF (addresses FE82 to FE84H) and a random number interrupt control register RIC (of the built-in registers included in the game control microcomputer 100 as shown in FIG. Addresses FE64-FE66H), enabling operation management and interrupt control at the time of random number latching. The random number hard latch flag register RHF is a register that stores a random number latch flag indicating whether or not numerical data serving as a random number value is latched corresponding to the hard latch random number value register 559A. For example, the random number hard latch flag register RHF stores data indicating the state (on or off) of the random number latch flag corresponding to the hard latch random number value register 559A. When numerical data is fetched and stored in the hard latch random value register 559A, the storage of new numerical data may be restricted by turning on the corresponding random number latch flag. In this case, when the numerical data stored in the hard latch random number value register 559A is read, the corresponding random number latch flag is turned off so that storage of new numerical data is permitted. The random number interrupt control register RIC is a register that sets permission / prohibition of an interrupt that occurs when numerical data that becomes a random number value is latched in the hard latch random number value register 559A.

  FIG. 23A shows a configuration example of the random number hard latch flag register RHF. FIG. 23B shows an example of setting contents in each bit that becomes the hard latch flag RLHF0 stored in the random number hard latch flag register RHF. The hard latch flag data RL01HF and RL00HF stored in the bit number [1-0] of the random number hard latch flag register RHF is whether or not the numerical data is taken into the hard latch random number value register 559A that becomes the hard latch random number value register RL0HV0. Is a random number latch flag indicating. In the example shown in FIG. 23B, when the numerical data is not captured in the hard latch random value register RL0HV0 (559A) (no random number is captured), the bit values of the hard latch flag data RL01HF and RL00HF are both "0" is cleared and the random number latch flag is cleared to the OFF state. On the other hand, when numeric data is fetched (with random number fetching), those bit values are set to "1" and the random number latch flag is set to the ON state. Is done.

  When the bit value in the bit number [3] of the hard latch selection register RL0LS shown in FIGS. 22A and 22B is “0”, when each random number latch flag is on, Storage of new numerical data in the associated hard latch random value register RL0HV0 (559A) is restricted (prohibited). That is, when the bit values of the hard latch flag data RL01HF and RL00HF indicating whether numerical data has been taken into the hard latch random value register RL0HV0 (559A) are both “1” and the random number latch flag is in the ON state, The numerical data stored in the hard latch random number value register RL0HV0 (559A) cannot be changed, and storage (capture) of new numerical data is restricted (prohibited). On the other hand, when each random number latch flag is OFF, storage of new numerical data in the hard latch random number value register RL0HV0 (559A) associated with the random number latch flag is permitted. That is, when the bit values of the hard latch flag data RL01HF and RL00HF are both “0” and the random number latch flag is in the OFF state, the numerical data stored in the hard latch random number value register RL0HV0 (559A) can be changed. Storage of new numerical data is permitted.

  Note that the bit values of the hard latch flag data RL03HF to RL00HF are “0”, the corresponding random number latch flag is cleared to the off state, while being “1”, the positive logic is set to the on state. The present invention is not limited to this, and it may be a negative logic that turns on when the corresponding random number latch flag is turned off when it is “1” and turned on when it is “0”. That is, each random number latch flag is turned on when numerical data is stored in the corresponding hard latch random value register RL0HV0 (559A), and storage of new numerical data is restricted (prohibited), while corresponding hard latch. Any random number register RL0HV0 (559A) may be used as long as it is turned off when new numerical data storage is permitted.

  FIG. 24A shows a configuration example of the hard latch interrupt control register RLIC0 corresponding to the 16-bit random number of the channel ch0 included in the random number interrupt control register RIC. FIG. 24B shows an example of setting contents in each bit of the hard latch interrupt control data stored in the hard latch interrupt control register RLIC0. The hard latch interrupt control data RL01IE and RL00IE stored in the bit number [1-0] of the hard latch interrupt control register RLIC0 are obtained when the numerical data is taken into the hard latch random value register 559A that becomes the hard latch random value register RL0HV0. This shows the interrupt control setting for enabling or disabling the interrupts that occur. In the example shown in FIG. 24 (B), when interrupts at the time of fetching into the hard latch random number value register RL0HV0 (559A) are prohibited (interrupt prohibited), the bit values of the hard latch interrupt control data RL01IE and RL00IE are both set. On the other hand, when this interrupt is permitted (interrupt permitted), the bit value thereof is set to “1”.

  The soft latch random value register 559S is a register that stores numerical data in the random number sequence RSN output from the maximum value comparison circuit 555 as a random value by a user program (software). The soft latch random value register 559S is a 16-bit (2-byte) register, and may store a 16-bit random value corresponding to the channel ch0, for example.

  The random number soft latch signal is input to the soft latch random value register 559S using the random number soft latch register RDSL (address FE74H) among the built-in registers included in the game control microcomputer 100 as shown in FIG. 9B. Is done. FIG. 25A shows a configuration example of the random number soft latch register RDSL corresponding to the channel ch0. FIG. 25B shows the setting contents of random number soft latch data stored in the random number soft latch register RDSL. The random number soft latch data RDSL0 stored in the bit number [0] of the random number soft latch register RDSL indicates the presence / absence of a random value latch request when the 16-bit random number of the channel ch0 is latched by software. In the example shown in FIG. 25B, when there is no random number latch request by software, the bit value of the random number soft latch data RDSL0 is “0”, while when there is a random number latch request by software, The bit value is “1”.

  The soft latch random value register 559S responds to the bit value of the random number soft latch data RDSL0 stored in the random number soft latch register RDSL being “1”, and the random number sequence RSN output from the maximum value comparison circuit 555. The numerical data at is taken in as a random value and stored. The soft latch random value register 559S uses the random number soft latch flag register RDSF (address FE75H) among the built-in registers included in the game control microcomputer 100 as shown in FIG. Enable. The random number soft latch flag register RDSF is a register that stores a random number soft latch flag indicating whether or not numerical data serving as a random number value is latched in the soft latch random number value register 559S. FIG. 26A shows a configuration example of the random number soft latch flag register RDSF. FIG. 26B shows the setting contents of the soft latch flag data stored in the random number soft latch flag register RDSF. As for the soft latch flag data RDSF0 stored in the bit number [0] of the random number soft latch flag register RDSF, whether or not the 16-bit random number of the channel ch0 is taken into the soft latch random value register 559S that becomes the soft latch random value register RL0SV. It becomes a random number soft latch flag indicating.

  In the example shown in FIG. 26B, when the numerical data is not captured in the soft latch random value register RL0SV (no random number is captured), the bit value of the soft latch flag data RDSF0 becomes “0” and the random number is stored. On the other hand, when the soft latch flag is cleared to the off state, when numerical data is fetched (with random number fetching), the bit value becomes “1” and the random soft latch flag is set to the on state. When the random number soft latch flag is on, storage of new numerical data in the soft latch random number register RL0SV is restricted (prohibited). That is, when the bit value of the soft latch flag data RDSF0 indicating whether numerical data has been taken into the soft latch random value register RL0SV is “1” and the random soft latch flag is in the ON state, the soft latch random value register The numerical data stored in RL0SV cannot be changed, and storage (capture) of new numerical data is restricted (prohibited). On the other hand, when the random number soft latch flag is off, storage of new numerical data in the soft latch random number value register RL0SV is permitted. That is, when the bit value of the soft latch flag data RDSF0 is “0” and the random number soft latch flag is in the OFF state, the numerical data stored in the soft latch random number register RL0SV can be changed, and a new numerical value can be changed. Data storage (capture) is permitted.

  In the 16-bit random number circuit 509A, a channel for independently generating a 16-bit random number may be provided for the channels ch1 to ch3 as well as the channel ch0. Two 16-bit (2-byte) hard latch random number value registers 559A are provided corresponding to channel ch0, while a 16-bit (2-byte) hard-latch random value register corresponding to each of channels ch1 to ch3 is provided. Only one may be provided.

  The 8-bit random number circuit 509B may be provided with a circuit for independently generating an 8-bit random number corresponding to each of the channels ch0 to ch3. For example, the circuit for generating an 8-bit random number corresponding to the channel ch0 may be any circuit as long as the circuit shown in FIG. 17 is configured to be suitable for generating an 8-bit random number. A random number generation circuit, a random number activation setting circuit, a random number sequence change circuit, a random number sequence change setting circuit, a maximum value comparison circuit, a hard latch selector, a hard latch random number value register, and a soft latch random number value register.

  In the configuration example shown in FIG. 7, random number circuits 509 </ b> A and 509 </ b> B are built in the game control microcomputer 100. On the other hand, the random number circuits 509A and 509B may be externally attached to the game control microcomputer 100 as random number circuit chips different from the game control microcomputer 100. In this case, the detection signal SS1 from the start switch 7 is branched inside the switch circuit 114, one is input to the input port PI0 of the PIP 510 provided in the game control microcomputer 100, and the other is provided in the random number circuit 509A. What is necessary is just to input to the input terminal of the hard latch selector 558A. For example, the random number update clock selection circuit provided in the random number circuit 509A includes the internal system clock SCLK output from the clock circuit 502 provided in the game control microcomputer 100 via the system clock output terminal CLKO. The hard latch random number register RL0HV0 and the hardware are input via an address bus, a data bus, a control signal line, and the like connected to the external bus interface 501 included in the game control microcomputer 100. It suffices to read out the numerical data stored in the latch random value register RL0HV1.

  Even when the random number circuits 509A and 509B are externally attached to the game control microcomputer 100, the hard latch random value register RL0HV0 or the hard latch random number value register RL0HV1 depends on the state (on / off) of each random number latch flag. It is only necessary to limit (prohibit) or permit storage of new numerical data in the. Among the built-in registers shown in FIG. 9B, for example, hard latch selection register RLS, random number interrupt control register RIC, random number maximum value setting register RMX, random number sequence change register RDSC, random number soft latch register RDSL, random number soft latch flag register RDSF The various registers used by the random number circuits 509A and 509B, such as the soft latch random value register RSV, the random number hard latch flag register RHF, and the hard latch random value register RHV, are not built in the game control microcomputer 100, and are used for game control. The random number circuits 509A and 509B externally attached to the microcomputer 100 may be incorporated. In this case, the CPU 505 of the game control microcomputer 100 may write and read various registers incorporated in the random number circuits 509A and 509B via the external bus interface 501 and the like, for example.

  The PIP 510 provided in the game control microcomputer 100 shown in FIG. 7 is, for example, an 8-bit wide input-only port. PI7 is included. The input port PI5 is also used as an external maskable interrupt terminal XINT connected to the interrupt controller 504B. The input port PI6 is also used as an external non-maskable interrupt terminal XNMI connected to the interrupt controller 504B. The input port PI7 is also used as the reception terminal RX0 used by the serial communication circuit 511. Use settings of the input port PI5 to the input port PI7 are instructed by function settings stored in the program management area.

  The PIP 510 performs state management of the input ports PI0 to PI7 using an input port register among the built-in registers provided in the game control microcomputer 100. The input port register is a register that stores a bit value indicating the input state of the external signal corresponding to each of the input port PI0 to the input port PI7.

  The serial communication circuit 511 provided in the game control microcomputer 100 is a circuit that handles communication data in, for example, full duplex, asynchronous, standard NRZ (Non Return to Zero) format. As an example, the serial communication circuit 511 can only transmit serial data in a single direction between the external communication circuit and the first channel transmission / reception circuit capable of transmitting and receiving serial data bidirectionally with the external circuit. And a second channel transmission circuit. The second channel transmission circuit included in the serial communication circuit 511 may be used for serial communication in a single direction (only transmission) with the sub-control unit 91 mounted on the effect control board 90. Thereby, the signal input with respect to the main board | substrate 11 from the production control board | substrate 12 side can be prohibited, and an improper act can be prevented.

  In the serial communication circuit 511, for example, four types of errors such as an overrun error, break code error, framing error, and parity error may occur when communication data is received. As long as it can be generated. The overrun error is an error that occurs when the next communication data is received before the received communication data is read by the user program. A break code error is an error that occurs when a predetermined break code is detected during reception of communication data. The framing error is an error that occurs when the stop bit in the received communication data is “0”. The parity error is an error that occurs when the parity of the received communication data does not match a predetermined parity when the parity function is set to be used.

  The serial communication circuit 511 may include a first interrupt control circuit and a second interrupt control circuit. The first interrupt control circuit is a circuit for managing an interrupt generation factor in the first channel transmission / reception circuit included in the serial communication circuit 511 and controlling a communication interrupt request. Interrupts controlled by the first interrupt control circuit include a first channel transmission interrupt and a first channel reception interrupt. The first channel transmission interrupt includes an interruption due to transmission completion and an interruption due to transmission data empty. The first channel reception interrupt includes an interruption due to reception data full and an interruption due to the occurrence of a reception error such as a break code error, an overrun error, a framing error, and a parity error. The second interrupt control circuit is a circuit for managing an interrupt generation factor in the second channel receiving circuit included in the serial communication circuit 511 and controlling a communication interrupt request. The interrupt controlled by the second interrupt control circuit is a second channel transmission interrupt. The second channel transmission interrupt includes an interruption due to transmission completion and an interruption due to transmission data empty.

  The address decoding circuit 512 provided in the game control microcomputer 100 is a circuit for decoding each functional block in the game control microcomputer 100 and decoding a chip select signal that is a decode signal for an external device. . By the chip select signal, an internal circuit of the game control microcomputer 100 or an external device serving as a peripheral device is selectively activated to enable access from the CPU 505.

  A ROM 506 provided in the game control microcomputer 100 stores various selection data and table data used for controlling the progress of the game. For example, the ROM 506 stores data constituting a plurality of determination tables, determination tables, setting tables, and the like prepared for the CPU 505 to perform various determinations, determinations, and settings. The ROM 506 stores table data constituting a plurality of command tables used for the CPU 505 to transmit control signals serving as various control commands from the game control board 40.

  In the RAM 507 provided in the game control microcomputer 100, for example, a game control data holding area is provided as an area for holding various data used for controlling the progress of the game in the slot machine 1 and the like. For example, a DRAM is used as the RAM 507, and a refresh operation is required to maintain the stored data contents. The CPU 505 has a built-in refresh register for performing this refresh operation. For example, the refresh register consists of 8 bits, and the lower 7 bits are automatically incremented every time the CPU 505 fetches an instruction from the ROM 506. Therefore, the stored value in the refresh register is updated every execution time of one instruction in the CPU 505.

  In this embodiment, as will be described later, an SRAM 50 is connected as an external memory to the game control microcomputer 100, and this SRAM 50 is a backup RAM that is at least partially backed up by a backup power source. is there. That is, even if the power supply to the slot machine is stopped, at least a part of the contents of the SRAM 50 is stored for a predetermined period. In this embodiment, all areas of the SRAM 50 are backup RAMs, and all contents of the SRAM 50 are stored for a predetermined period even when power supply to the slot machine is stopped. In this embodiment, the SRAM 50 serving as the backup RAM includes, for example, data used for control related to internal lottery, which will be described later, data used for control related to medal payout, and reel rotation and stop when power is cut off. Data used for control related to the command, data used for control related to command input / output, and the like are stored.

  The game control microcomputer 100 transmits various commands to the sub-control unit 91. A command transmitted from the game control microcomputer 100 to the sub-control unit 91 is sent only in one direction, and no command is sent from the sub-control unit 91 to the game control microcomputer 100.

  In the game control microcomputer 100, detection states of various switches connected to the game control board 40 are input from an input port. The game control microcomputer 100 executes a basic process that shifts in stages according to the detection states of the various switches input from these input ports.

  In addition, the game control microcomputer 100 can execute an interrupt process by interrupting the basic process when an interrupt occurs. In the present embodiment, a timer interrupt process (main) described later is executed at regular time intervals (in the present embodiment, about 0.56 ms). In addition, the execution interval of the timer interrupt process (main) is set to a time longer than the sum of the time required to complete the repeated process according to the control state in the basic process and the execution time of the timer interrupt process (main) Therefore, the process that is repeated according to the control state between the current and next timer interrupt processes (main) is completed at least once.

  Further, the game control microcomputer 100 is set to prohibit other interrupts during execution of the interrupt process, and when a plurality of interrupts occur at the same time, the game control microcomputer 100 has a predetermined order. A priority interrupt is set. If another interrupt factor occurs during the execution of the interrupt process and the interrupt factor continues even after the interrupt process is completed, a new interrupt will occur at that point. It will be.

  An effect switch 56 is connected to the effect control board 90, and a detection signal of the effect switch 56 is input.

  The effect control board 90 is connected to effect devices such as a liquid crystal display 51 (see FIG. 1), an effect LED 52, speakers 53 and 54, and the reel LED 55 described above, which are arranged on the front door 1b of the slot machine 1. These effect devices are driven based on control by a later-described sub-control unit 91 mounted on the effect control board 90.

  In this embodiment, the sub-control unit 91 mounted on the effect control board 90 controls the output of the effect devices such as the liquid crystal display 51, effect effect LED 52, speakers 53 and 54, and reel LED 55. However, in addition to the sub-control unit 91, an output control unit that directly controls output of the effect device is mounted on the effect control board 90 or another board, and the sub-control unit 91 receives a command from the game control microcomputer 100. Based on the output pattern determined by the sub control unit 91 based on the output pattern determined by the sub control unit 91, the output control unit may control the output of the rendering device. In such a configuration, the sub control unit 91 and The output control of the effect device is performed by both of the output control units.

  Further, in the present embodiment, the liquid crystal display 51, the effect effect LED 52, the speakers 53 and 54, and the reel LED 55 are exemplified as the effect device, but the effect device is not limited to these, for example, a mechanically driven display. A device or a mechanically driven item may be applied as the effect device.

  Like the game control microcomputer 100, the effect control board 90 includes a sub CPU 91a, a ROM 91b, a RAM 91c, and a microcomputer provided with an I / O port 91d. A display control circuit 92 that performs display control of the liquid crystal display 51 connected to the substrate 90, an LED drive circuit 93 that performs drive control of the effect LED 52 and the reel LED 55, and an audio output circuit that performs audio output control from the speakers 53 and 54. 94, connected to the effect control board 90, a reset circuit 95 that gives a reset signal to the sub CPU 91a when the power source is unstable, such as when the power is turned on or off, or when the initialization command from the sub CPU 91a is not input for a certain period of time. Switch for detecting the detection signal input from the production switch 56 The output circuit 96, the clock device 97 for outputting time information including date information and time information, and the power supply voltage supplied to the slot machine 1 are monitored, and when a voltage drop is detected, a voltage drop signal indicating that is sub The power interruption detection circuit 98 that outputs to the CPU 91a, other circuits, and the like are mounted. The sub CPU 91a receives various commands transmitted from the game control board 40 and performs various controls for performing effects. At the same time, each part of the control circuit mounted on the effect control board 90 is controlled directly or indirectly.

  Similar to the game control microcomputer 100, the sub-control unit 91 has an interrupt function, generates an interrupt when receiving a command from the game control microcomputer 100, and transmits it from the game control microcomputer 100. The received command is acquired and stored in the buffer to execute the command reception interrupt process. The sub-control unit 91 executes a predetermined timer interrupt process (sub) by generating an interrupt every time the number of input system clocks reaches a certain number, that is, every certain interval.

  Further, unlike the game control microcomputer 100, the sub-control unit 91, when an interrupt is generated based on the reception of the command, performs the process even if the timer interrupt process (sub) is being executed. The command reception interrupt process is executed by interrupting the command reception interrupt process, and the command reception interrupt process is executed with the highest priority even if interrupts that trigger the timer interrupt process (sub) occur at the same time.

  The RAM 91c included in the sub control unit 91 provides a work area for various effects control such as liquid crystal display, lamp display, and sound output, and is used as a work RAM.

  As shown in FIG. 27 (a), the game control microcomputer 100 and the SRAM 50 include a 16-bit address bus, a 32-bit data bus, a CS (chip select) signal line, an RD (read) signal line, and a WR ( Connected via a signal line.

  Here, the input / output situation of signals when the game control microcomputer 100 reads data from the SRAM 50 and writes data from the game control microcomputer 100 to the SRAM 50 will be described.

  When the game control microcomputer 100 reads data from the SRAM 50, as shown in FIG. 27 (b), the game control microcomputer 100 designates the address where the data to be read from the SRAM 50 is stored on the address bus. Thereafter, the CS signal corresponding to the SRAM is turned ON, and the RD signal for instructing data reading is turned ON.

  The SRAM 50 that has detected the CS signal and the RD signal, until the data stored in the address area designated by the address bus is turned OFF, that is, until the data is captured by the game control microcomputer 100. Output to the data bus. On the other hand, the game control microcomputer 100 turns off the RD signal upon completion of taking in data from the data bus, and then turns off the CS signal and completes reading of data from the SRAM 50.

  When the game control microcomputer 100 writes data to the SRAM 50, as shown in FIG. 27 (c), the address where the data is stored is specified by the address bus, and the data to be written to the SRAM 50 is input to the data bus. After the output, the CS signal corresponding to the SRAM is turned ON, and the WR signal for instructing data writing is turned ON.

  The SRAM 50 that has detected the CS signal and the WR signal fetches data from the data bus and writes the fetched data in the address area designated by the address bus. Thereafter, the game control microcomputer 100 turns off the WR signal and turns off the CS signal corresponding to the SRAM after a sufficient time has elapsed for the SRAM 50 to take in the data from the data bus. Complete writing.

  In the slot machine 1 of the present embodiment, the medal payout rate changes according to the set value. Specifically, the medal payout rate is changed by using a winning probability corresponding to a set value in an internal lottery described later. The set value is composed of 6 levels of 1 to 6, with 6 being the highest payout rate and the payout rate being lower as the value is decreased in the order of 5, 4, 3, 2, 1. That is, when 6 is set as the set value, the advantage is highest for the player, and as the value decreases in order of 5, 4, 3, 2, 1, the advantage decreases stepwise.

  In order to change the setting value, it is necessary to turn on the power of the slot machine 1 after the setting key switch 37 is turned on. When the setting key switch 37 is turned on and the power is turned on, the setting value read from the RAM 507 is displayed on the setting value display 24 as a display value, and the setting value can be changed by operating the reset / setting switch 38. Transition to the setting change state. When the reset / setting switch 38 is operated in the setting change state, the display value displayed on the setting value display 24 is updated one by one (when further operation is performed from the setting 6, the display returns to the setting 1). . When the start switch 7 is operated, the display value is determined as the set value. When the setting key switch 37 is turned off, the determined display value (setting value) is stored in the RAM 507 of the game control microcomputer 100, and the state shifts to a state in which the game can proceed.

  In order to check the set value, after the game is over, the setting key switch 37 may be turned on in a state where the bet amount is not set. When the setting key switch 37 is turned on in such a situation, the setting value read out from the RAM 507 is displayed on the setting value display 24, thereby shifting to a setting confirmation state in which the setting value can be confirmed. In the setting confirmation state, the game cannot be progressed, and by setting the setting key switch 37 to the off state, the setting confirmation state is ended and the state in which the game can proceed is returned.

  In the slot machine 1 of the present embodiment, the game control microcomputer 100 detects the power-off signal from the power-off monitoring circuit 303 every time the timer interrupt process (main) shown in FIG. 34 is executed. If a power failure determination process (Sk2 in FIG. 34) for determining whether or not a power failure signal is detected in the power failure determination process, the power interruption process (main) shown in FIG. 36 is executed. In the power interruption process (main), as will be described later, a backup flag is set in the SRAM 50 for each program module, data used in the program module is calculated to generate a checksum, and the generated checksum is stored in the SRAM 50. Process to store in. Note that the checksum is the exclusion of the value stored in each bit of the corresponding area of the RAM 507 (in this embodiment, all areas in the work RAM in which data used by the program module is stored). It is a value calculated as a logical OR. For this reason, if the value obtained by calculating the exclusive OR based on the data stored in all areas in the work RAM in which the data used by the program module is stored is 0, the checksum is 0. If the value obtained by calculating the exclusive OR based on the data stored in all the areas in the work RAM in which the data used in the program module is stored is 1, the checksum is 1.

  The game control microcomputer 100 stores all the data used in the program module in the external memory (backup RAM) for each module at the time of activation, regardless of whether it is a system reset or a user reset. The checksum is calculated based on the area data, the backup flag is checked, and the calculated checksum matches the checksum value being backed up and the backup flag is also set. Based on the data stored in the SRAM 50, the processing state of the game control microcomputer 100 and the sub-control unit 91 is restored to the state before the power interruption. If not, Determines that the AM abnormal. At this time, if the gaming control microcomputer 100 determines that the RAM is abnormal, the RAM abnormal error code is set in the register to control the RAM abnormal error state, thereby disabling the progress of the game. Unlike the normal error state, the RAM abnormal error state is not canceled even if the reset switch 23 or the reset / setting switch 38 is operated, and a new set value is set in the above-described setting change state. It will not be released until

  In this embodiment, all the data stored in the RAM 507 is stored in the SRAM 50 even when a power failure occurs and is held by the backup power source. The game control microcomputer 100 stores the data in the SRAM 50 when the power is turned on. When it is determined to be normal, the configuration is such that the control state before power interruption is restored based on the data stored in the SRAM 50. Of the data stored in the RAM 507, the data necessary for restoration of the control state in the event of a power failure Only the SRAM 50 may be backed up in the SRAM 50, and the control state before power interruption may be restored based on the data backed up when the power is turned on.

  In addition, when returning to the control state before the power interruption when the power is turned on, it is not necessary to return all the control states to the control state before the power interruption, and the minimum control state that does not disadvantage the player For example, it is not necessary to restore the state of all input ports to the state before power interruption.

  In the slot machine 1 of this embodiment, as described above, the prescribed number of bets that can be set according to the gaming state (usually inside, BB (RB)) is determined, and is determined according to the gaming state. The game can be started on the condition that the specified number of bets has been set. In the present embodiment, the winning line LN is activated when a specified number of bets according to the gaming state are set.

  In the slot machine 1 of this embodiment, when all the reels 2L, 2C, and 2R are stopped, the activated winning line LN (hereinafter, the activated winning line LN is simply referred to as the winning line LN). A winning combination will be awarded when a combination of symbols called roles is complete. The combination may be a combination of the same symbols or a combination including different symbols. The type of winning combination is determined according to the game state, but it can be roughly divided into a small role with payout of medals and a replay that can start the next game without the need to set the number of bets. There are a game combination and a special combination with a transition to a game state advantageous to the player. Below, a small role and a re-playing role are collectively called a general role. In order to win each winning combination determined according to the game state, it is necessary to win an internal lottery described later and set a winning flag for the winning combination in the RAM 507.

  Of the winning flags for each of these combinations, the winning flag for the small role and the re-playing role is valid only in the game in which the flag is set, and is invalid in the next game. It is valid until the combination of combinations permitted by the flag is complete, and is invalid in a game having the combination of combinations permitted. In other words, once the winning flag for a special role is won, even if the combination of characters allowed by the flag cannot be aligned, the winning flag is not invalidated and is carried over to the next game. It becomes.

  In the internal lottery, it is determined whether or not the above winning combination is permitted before the display results of all reels 2L, 2C, and 2R are derived and displayed (actually, when the start switch 7 is detected). To do. In the internal lottery, first, a random value for internal lottery (an integer from 0 to 65535) is acquired when the start switch 7 is detected. Specifically, the value of the random number storage work assigned to the RAM 507 is set to the lottery work assigned to the RAM 507. Then, for each combination determined according to the gaming state and whether or not the special combination is carried over, the numerical data stored in the lottery work, the value of the gaming state flag for specifying the gaming state, and the RT described later are specified. The determination is made according to the number of determination values of each combination determined according to the value of the RT flag, the number of bets, and the set value.

  In the internal lottery, an internal lottery target, a current gaming state flag value, an RT flag value, and the number of determination values determined corresponding to the set value are stored in a random number for internal lottery (a lottery work). When the result of addition overflows, it is determined that the winning combination is won. For this reason, a winning combination will be won with a probability (number of determination values / 65536) according to the number of determination values.

  If a winning combination of any combination is determined, a winning flag corresponding to the winning combination is set in the internal winning flag storage work assigned to the RAM 507. The internal winning flag storage work consists of a 2-byte storage area, of which the upper byte is assigned as the special role storing work in which the winning flag for the special role is set, and the lower byte is the winning of the general role It is assigned as a general role storage work for which a flag is set. Specifically, when a special combination is won, a special combination winning flag indicating that the special combination is won is set in the special combination storing work, and the winning flag set in the general combination storing work is cleared. When a general combination is won, a winning flag for the general combination indicating that the general combination is won is set in the general combination storing work. If no winning combination is selected, only the general winning combination work is cleared.

  Next, stop control of the reels 2L, 2C, 2R will be described.

  The game control microcomputer 100 refers to the table index and table creation data stored in the ROM 506 when the reel starts rotating and when the reel stops and the reel that is still rotating still remains. Then, a stop control table is created for each rotating reel. When any of the stop switches 8L, 8C, and 8R corresponding to the rotating reel is effectively detected, the stop control table of the corresponding reel is referred to and the slip of the referred stop control table is referred to. Based on the number of frames, control is performed to stop the rotation of the reels 2L, 2C, 2R corresponding to the operated stop switches 8L, 8C, 8R.

  In the table index, an index that indicates the start address of the area in which the data for table creation is stored, from the reference address when referring to the table index, according to the setting state of the winning flag by internal lottery (hereinafter referred to as the internal winning state) Differences up to the address where the data is stored are registered. As a result, a difference corresponding to the internal winning state is acquired, and the corresponding index data can be acquired by adding the difference to the reference address. Even when the winning combinations are different, when the same control is applied, the same address is stored as the index data. In such a case, the same table creation data is referred to. Thus, a stop control table is created.

  The table creation data includes a stop control table indicating the number of sliding frames according to the stop operation position, and an address of the stop control table to be referred to according to the reel stop status.

  The stop control table referred to according to the reel stop status is whether all reels are rotating, only the left reel is stopped, only the middle reel is stopped, only the right reel is stopped, It may vary depending on whether the middle reel is stopped, the left and right reels are stopped, the middle and right reels are stopped, and if any reel is stopped, stop Since there may be differences depending on the stop position of the reels already completed, the address of the stop control table to be referenced for each situation is registered for each rotating reel, and based on the top address of the table creation data, It is possible to specify the address of the stop control table that should be referred to according to the status of each, and it is necessary according to each status from this specified address. And to be able to identify the stop control table. Even when the reel stop status and the stopped position of the stopped reel are different, when the same stop control table is applied, the same address may be registered as the address of the stop control table. In such a case, the same stop control table is referred to.

  The stop control table is data that can specify the number of sliding frames for each timing when the stop operation is performed. In this embodiment, stepping motors that make one turn at a cycle of 168 steps (0 to 167) are used for the reel motors 32L, 32C, and 32R. That is, when the reel motors 32L, 32C, and 32R are driven for 168 steps, the reels 2L, 2C, and 2R make one round. 21 areas (frames) divided every 8 steps (the number of steps in which one symbol moves) per reel are defined, and these areas are areas 0 to 20 from the reel reference position. A number is assigned. On the other hand, the number of symbols arranged on one reel is 21, and symbol numbers 0 to 20 from the reel reference position are assigned to symbols on each reel, so symbols 0 to 20 are assigned to each reel. , Area numbers 0 to 20 are assigned in order. In the stop control table, the number of sliding symbols for each area number is compressed and stored according to a predetermined rule, and the number of sliding symbols for each area number can be acquired by expanding the stop control table. Yes.

  As described above, the stop control table created by referring to the table index and the table creation data corresponds to the area number, and the area corresponding to each area number is the stop reference position (in this embodiment, the perspective window 3). Sliding frame when an operation of the stop switches 8L, 8C, 8R is detected at a timing (a timing in which the number of steps from the reel reference position is included in the range of the number of steps of each region number). It is a table with each number set.

  Next, the procedure for creating the stop control table will be described. First, at the start of reel rotation, the top address of the table creation data corresponding to the internal winning state of the game is acquired. Specifically, the table index is first referred to, index data corresponding to the internal winning state is obtained, table creation data is identified based on the obtained index data, and all reels are identified from the identified table creation data. The address of the stop control table for each reel corresponding to the state of rotation is acquired, and the stop control table for each reel stored at the acquired address is expanded to generate a stop control table for all reels.

  Further, when any one reel stops or any two reels stop, the index data acquired at the start of reel rotation, that is, the top address of the table creation data corresponding to the internal winning state of the game The table creation data is identified based on the table creation data, and the stop control table address of the unreacted reel corresponding to the stopped reel and the area number of the stop position of the reel is obtained from the identified table creation data. The stop control table for each stored reel is expanded to create a stop control table for the unstopped reels.

  Next, when the game control microcomputer 100 effectively detects any one of the stop switches 8L, 8C, and 8R corresponding to the rotating reel, the display result is output to the corresponding reel. Explaining the control, if any of the stop switches 8L, 8C, and 8R corresponding to the rotating reel is effectively detected, the operation is stopped based on the number of steps from the reel reference position at the time when the stop operation is detected. The area number of the operation position is specified, the stop control table of the reel where the stop operation is detected is referred to, and the number of sliding symbols corresponding to the specified area number of the stop operation position is acquired. Then, control is performed to rotate and stop the reel by the number of acquired sliding frames. Specifically, from the number of steps from the reel reference position at the time when the stop operation is detected, the number of steps from the acquired number of sliding frames to the stop is calculated, and the reel is rotated and stopped by the calculated number of steps. Take control. As a result, the area corresponding to the area number that is the stop position ahead of the number of sliding frames from the area corresponding to the area number of the stop operation position where the stop operation is detected is the stop reference position (in this embodiment, the perspective window 3 It will stop in the lower symbol area).

  In the table index of this embodiment, only one address is stored as index data corresponding to one internal winning state in one gaming state, and further, one table creation data includes one reel. Only one address is stored as the address of the storage area of the stop control table corresponding to the stop status (and the stop position of the stopped reel). In other words, table creation data corresponding to one internal winning state in one gaming state and stop control tables corresponding to reel stop states (and stopped positions of stopped reels) are uniquely determined. The stop control table created with reference to is unique for one internal winning state in one gaming state and the reel stop status (and the stop position of the stopped reel). Therefore, when all of the gaming state, the internal winning state, and the reel stop status (and the stop position of the stopped reel) are the same, the reel is based on the same stop control table, that is, the same control pattern. The stop control is performed.

  Further, in this embodiment, a value of 0 to 4 is determined as the number of sliding frames, and the reel can be stopped by drawing a maximum of 4 symbols after detecting the stop operation. In other words, the stop position of the symbol can be designated from a range of a maximum of 5 frames including the stop operation position where the stop operation is detected. In addition, since it is necessary to move one frame to move the reel for one symbol, it is possible to stop the reel by pulling in a maximum of four symbols after detecting the stop operation. The symbol stop position can be designated from a range of up to five symbols including the operation position.

  In the present embodiment, when any winning combination is won, the winning combination is drawn to the winning line LN to the maximum extent within a range of 4 frames, and the winning combination is drawn so that the winning combination is not aligned with the winning line LN. A stop control table with a defined number of frames is created and reel stop control is performed. If no winning combination is selected, a stop control table with a determined number of sliding symbols that do not have any combination And stop control of the reel. As a result, when a stop operation is performed, if the winning combination can be stopped in the winning line LN within the drawing range of a maximum of 4 frames, the control is performed so that the winning combination is stopped. The combination that has not been performed will be controlled to be stopped in a drawing range of up to 4 frames.

  If a special role and a small role are elected at the same time, such as when a special role is elected while the special role has been carried over from before the previous game, the elected small role will be placed in the winning line LN within 4 frames. The number of sliding symbols is set so as to be pulled in as much as possible, and for the stop operation position where the selected small role cannot be drawn into the winning line LN within the range of up to 4 frames, the winning special role is set to 4 in the winning line LN. A stop control table in which the number of sliding frames is determined so as to be pulled in as much as possible within the range of frames is created, and reel stop control is performed. As a result, when a stop operation is performed, if it is possible to stop all the small roles that have been selected in the winning line LN within a drawing range of a maximum of 4 frames, the control is performed so that the winning combination is stopped. If it is not possible to withdraw a small role that has been won in the draw range of up to 4 frames to the line LN, if the special role that has been won in the draw range of up to 4 frames can be aligned and stopped on the winning line LN, Control is performed to align and stop this, and the winning combination that has not been won is controlled to be stopped within the drawing range of 4 frames. That is, in such a case, priority is given to the control for aligning the small role with the winning line LN over the special role, and the special role can be won only when the small role cannot be drawn. When a special combination and a small combination can be withdrawn at the same time, only the small combination is drawn, and the small combination is not aligned with the winning line LN at the same time as the special combination.

  In this example, when a special role is elected while the special role has been carried over from before the previous game, or when a special role and a small role are simultaneously elected, the special role and the small role are won simultaneously. If the winning combination is prioritized over the selected winning combination, and only when the winning combination cannot be withdrawn, control is performed to align the winning combination with the winning line LN. When winning simultaneously, priority is given to the control for aligning the special combination with the winning line LN over the small combination, and the control for aligning the small combination with the winning line LN may be performed only when the special combination cannot be drawn.

  If a special player and a replaying player are elected at the same time, such as when a replaying player is elected while the special role has been carried over from before the previous game, the winning line LN will be displayed when the stop operation is performed. In addition, a control is performed in which the symbols of the re-gamer are aligned and stopped within a drawing range of up to 4 frames. In this case, the symbols constituting the re-gamer or the symbols constituting the re-gamer to be simultaneously elected are arranged at intervals of 5 symbols or less, that is, within 4 frames, for any of the reels 2L, 2C, and 2R. Since it can always be stopped at any position within the 4-frame pull-in range, if the special combination and the re-playing combination are elected at the same time, the timing of the operation of the stop switches 8L, 8C, 8R by the player Without fail, the re-playing role will always be won. That is, in such a case, the control for aligning the re-games with the winning line LN has priority over the special game, and the re-games will always win. In the case where the special combination and the re-playing combination can be withdrawn at the same time, only the re-playing combination is drawn in and the special combination is not aligned with the winning line LN at the same time as the re-playing combination.

  In the present embodiment, the game control microcomputer 100 detects the reels for which the stop operation has not been detected until the operation of the stop switches 8L, 8C, 8R is detected after the reels 2L, 2C, 2R start to rotate. The control is performed to continue the rotation and stop the display result on the corresponding reel on condition that the operation of the stop switches 8L, 8C, and 8R is detected. Even if the reel rotation temporarily stops due to the occurrence of a reel rotation error, the stop operation is still detected until the operation of the stop switches 8L, 8C, and 8R is detected after the reel rotation is restarted. Control is performed to stop the display result of the corresponding reels on the condition that the rotation of the reels that have not been continued is continued and the operation of the stop switches 8L, 8C, and 8R is detected.

  In this embodiment, control is performed to stop the display result on the corresponding reel on condition that the operation of the stop switches 8L, 8C, and 8R is detected. However, the rotation of the reel is started. When a predetermined automatic stop time has elapsed, even if the reel stop operation is not performed, it is assumed that the stop operation has been performed, and automatic stop control is performed to automatically stop each reel. May be. In this case, since the reels are stopped without the player's operation, for example, it is preferable to derive a display result that does not constitute any combination even if any combination is won.

  As shown in FIG. 28, a game control program is stored in the ROM 506 of the game control microcomputer 100. The game control program includes an internal lottery control module for performing control related to the internal lottery process executed in Sd2 in the game control process of FIG. 33, and an input / output process executed in Sd7 of the game control process of FIG. An input / output control module that performs control related to input / output processing at the I / O port), a reel rotation control module that performs control related to reel rotation processing executed in Sd3 in the game control processing of FIG. 33, and FIG. A payout control module for performing control related to the payout process executed in Sd5 in the game control process. Thus, the game control program includes a plurality of control modules corresponding to each control executed by the game control microcomputer 100. Therefore, only one type of control module (one or more) may be replaced with another type. In this case, only the control module needs to be replaced, and the game control program can be easily changed.

  Next, various control contents executed by the game control microcomputer 100 according to the present embodiment will be described with reference to FIGS.

  In the game control board 40, the game control microcomputer 100 is activated in response to the start of power supply from the power supply board 101 and the reset signal to the game control microcomputer 100 becoming high level (off state). Based on the security check program 506A read from the ROM 506 by the CPU 505, a security check process as shown in the flowchart of FIG. 29 is executed. At this time, the operation state of the game control microcomputer 100 is the security mode, and the game control user program stored in the ROM 506 is not yet executed.

  When the security check process shown in FIG. 29 is started, the CPU 505 first executes a process for determining a time (security time) when the game control microcomputer 100 is in the security mode by executing the security check process. . At this time, the CPU 505 reads the bit value in the bit number [5-0] of the security time setting KSES stored in the program management area of the ROM 506 (step S1). Then, a fixed extension time corresponding to the read value is set (step S2). In the process of step S2, for example, as shown in FIG. 12, a fixed security time that differs according to the bit value in the bit number [5-0] of the security time setting KSES may be set as the fixed extension time.

  After executing the process of step S2, the bit value in the bit number [7-6] of the security time setting KSES is read (step S3). Then, it is determined whether or not the read value is “00” (step S4). At this time, when it is determined that the read value is other than “00” (step S4; No), a variable extension time determined corresponding to the read value is set (step S5). In the process of step S5, for example, as shown in FIG. 12, the variable security time in any one of the short mode, middle mode, and long mode is set corresponding to the bit value in the bit number [7-6] of the security time setting KSES. What is necessary is just to set as variable extension extension time. The security time may be set by adding the fixed extension time set by the process of step S2 and the variable extension time set by the process of step S5. Here, the variable setting time is a time component that changes every time the security check process is executed in the security time, and the bit value in the bit number [7-6] of the security time setting KSES is “01” (short). Mode), “10” (middle mode), or “11” (long mode).

  For example, when the count value in the free-run counter 509C or the like is stored in the variable security time register built in the game control microcomputer 100 when the system reset occurs, in the process of step S5, the variable security time By using the stored value of the register as it is, or by using the value obtained by substituting the stored value for a predetermined arithmetic function (for example, a hash function), the variable setting time is within a predetermined time range for each system reset. It may be determined so as to change randomly. Thus, when the bit value in the bit number [7-6] of the security time setting KSES is a value other than “00”, the security time as the execution time of the security check process is set as the security based on the occurrence of the system reset or the like. Each time the check process is executed, it can be changed within a predetermined time range.

  On the other hand, when it is determined in step S4 that the read value is “00” (step S4; Yes), the process of step S5 is not executed. In this case, the fixed extension time set by the process of step S2 may be set as the security time.

  Thereafter, the security code stored in the predetermined area of the ROM 506 is read (step S6). Here, in a predetermined area of the ROM 506, a security code of a calculation result obtained by calculating the data of the stored content by a predetermined calculation formula is stored in advance. As a security code generation method, for example, a hash value is generated using a hash function, an error detection code (CRC code) is used, or an error correction code (ECC code) is used. A generation method may be used. In a predetermined area different from the security code storage area of the ROM 506, an arithmetic expression for specifying the security code by calculation is encrypted and stored in advance.

  Following the processing in step S6, the encrypted arithmetic expression is decrypted and restored (step S7). Thereafter, the storage code in the predetermined area of the ROM 506 is calculated by the arithmetic expression decrypted in step S7 to specify the security code (step S8). At this time, the storage data used for the calculation for specifying the security code is, for example, program data corresponding to a part or all of the user program different from the security check program 506A in the storage data of the ROM 506, or predetermined table data It is sufficient if it is a part or all of the fixed data that constitutes. Then, the security code read in step S6 is compared with the security code specified in step S8 (step S9). At this time, it is determined whether or not the security codes match in the comparison result (step S10).

  If the security codes do not match in step S10 (step S10; No), it is determined that an unauthorized change has been made to the ROM 506, and the operation of the CPU 505 is shifted to a halt state (HALT). On the other hand, if the security codes match in step S10 (step S10; Yes), it is determined whether the security time set based on the processing in step S2 or step S5 has elapsed (step S10). S11). If the security time has not elapsed (step S11; No), the process of step S11 is repeatedly executed and waits until the security time elapses. On the other hand, if it is determined in step S11 that the security time has elapsed (step S11; Yes), for example, the value of the program counter built in the CPU 505 is set to the start address (address 0000H) of the user program in the ROM 506. The start process (main) starts to be executed by setting or the like. At this time, the execution of the game control is started from the beginning of the control code constituting the user program stored in the ROM 506, so that the operation state of the game control microcomputer 100 shifts from the security mode to the user mode. Execution of the startup process (main) shown in the flowcharts of FIGS. 30 to 32 is started.

First, after the built-in device, peripheral IC, interrupt mode, stack pointer, etc. are initialized (Sa1), the values of the I register and IY register are initialized (Sa2). By initialization of the I register and the IY register, an interrupt table address to be referred to when an interrupt occurs is set in the I register, and a reference address for referring to the storage area of the RAM 507 is set in the IY register. . These values are fixed values and are always initialized at startup. Further, in the process of Sa2, the operation setting in the serial communication circuit 511 may be performed by initializing the setting in a predetermined communication setting register. Next, by setting the general-purpose port corresponding to the general-purpose terminal connected to the CS signal line connected to the SRAM 50 to the output port (Sa3), the output of the chip select signal of the SRAM 50 is validated. Following the processing of sa 3, setting of the timer circuit 508 and PIP510 may be performed.

Thereafter, it is determined such as by checking the pin states at a given input port included in the example PIP510, power-off signal whether the OFF state (Sa 3 5). In the slot machine 1, when power supply is started, output voltages of various power sources such as a VSL (+ 30V) power source gradually reach a specified value. In this case, by checking the off state of the power failure signal (high level) by treatment Sa 3 5, it is possible CPU505 confirms the stability of the power supply voltage. In order to prevent erroneous detection due to the influence of noise or the like, the confirmation of the power-off signal may be continuously executed a predetermined number of times (for example, 5 times).

If the power cut-off signal is in the on state (low level) at Sa 3 5, a setting for starting the watch dog timer 520 provided in the reset controller 504A is performed (Sa 3 6). In this embodiment, the bit value in the bit number [6] of the reset setting KRES shown in FIG. 10B is set to “0” in advance. Thus, the user program determines whether to activate the watchdog timer 520 and enable the reset operation according to the occurrence of timeout, or stop the watchdog timer 520 and invalidate the reset operation according to the occurrence of timeout. Set to switchable by (software). In addition, the bit value in the bit number [5-4] of the reset setting KRES is set to “11” in advance, and the bit value in the bit number [3-0] of the reset setting KRES is set to “1111” in advance. Set as follows. Thereby, the timeout time that is the monitoring time measured by the watchdog timer 520 is the longest time among a plurality of types that can be set as the monitoring time.

Based on such a setting, the processing of Sa 3 6 is a WDT start register WST which CPU505 is shown in FIG. 15 (A), writes "CCH" as WDT start data. Thus, when the power-off signal by the processing of Sa 3 5 is determined to be in the on state, to initiate a measurement of the monitoring time by the watchdog timer 520 to activate the reset operation due to the occurrence of a timeout.

Treatment of sa 3 6 after activating the watchdog timer 520, CPU 505 is a control state shifts to the waiting state by repeating the endless loop. Since the watchdog timer 520 is not cleared and restarted after shifting to the standby state in this way, a reset operation due to the occurrence of a timeout is performed when the elapsed monitoring time is measured. Therefore, even if a predetermined time has elapsed after power supply to the slot machine 1 is started, the stability of the power supply voltage cannot be confirmed, and if the power-off signal remains on, a time-out in the watchdog timer 520 occurs. The game control microcomputer 100 can be restarted by performing a reset operation upon occurrence.

  Here, the timeout time that is the monitoring time measured by the watchdog timer 520 is the longest time 225 × TSCLK × 15 (TSCLK is the cycle of the internal system clock SCLK) among a plurality of types that can be set as the monitoring time. Is set to Therefore, for example, when the power supply is completely stopped for a predetermined period due to, for example, disconnection of the power switch in the slot machine 1, the power supply to the CPU 505 of the game control microcomputer 100 is performed before the time-out occurs due to the elapse of the monitoring time. Since it stops, it can restrict | limit so that reset operation by generation | occurrence | production of timeout may not be performed. In this way, it can be prevented that the power switch is erroneously reset when the power switch is turned off.

When the power cut-off signal is in the off state (high level) at Sa 3 5, the clear switch is based on the signal state of the switch signal (clear signal) transmitted from the clear switch 304 installed on the power supply substrate 101. 304 determines whether the on operation (Sa 3 7). In the process of Sa 3 7 is a clear signal that is transmitted from the clear switch 304 is checked multiple times, when it is turned on in succession, it may be determined that the clear switch 304 is turned on. For example, once it is confirmed that the state of the clear signal is off, the state of the clear signal is confirmed once again after a predetermined time (for example, 0.1 second) has elapsed. At this time, if the clear signal is off, it is determined that the clear signal is off. On the other hand, if the state of the clear signal is on at this time, the state of the clear signal may be confirmed again after a predetermined time has elapsed. Note that the number of times of reconfirming the state of the clear signal may be one time or may be a plurality of times. Further, it is possible to check twice and check again when the check results do not match.

If clearing signal is turned on at sa 3 7, for example, it sets a clear flag also received was in a predetermined area (such as a gaming control flag setting section) of the RAM507 ON state (sa 3 8). On the other hand, when the clear signal is in the off state, it skips the process of Sa 3 8, and leaves the clear flag off.

Thereafter, the setting of delay processing for delaying the start timing of the game control process by executing software for controlling the progress of the game (Sa 3 9). As a specific example, an initialization weight count designation value is set in a wait counter provided in a predetermined area (such as a game control counter setting unit) of the RAM 507. Then, the start of the delay processing based on the setting in Sa 3 9, for example, subtracts 1 from the count value in the weight counters, and updates the settings related to the execution of the delay process (Sa 4 0). Then, for example, by the count value in the weight counter to determine whether it has reached a predetermined delay end determination value, it determines whether or not a predetermined delay time has elapsed (Sa 4 1). Here, the data indicating the delay end determination value may be stored in advance in the ROM 506 or the like.

When the delay time at the Sa 4 1 has not elapsed, it returns to the processing of Sa 4 0, when the delay time has elapsed, to allow access to the RAM507 (work RAM) (Sa4).

  After permitting access to the RAM 507 (work RAM), it is determined whether or not the backup flag for the internal lottery control module is set in the SRAM 50 (backup RAM) (Sa5). In this embodiment, in Sm5, Sm10, Sm15, and Sm20 in the power interruption process (main) of FIG. 36, when a power interruption occurs, a backup flag is set for each program module. That is, in this embodiment, regarding the processing performed by the game control microcomputer 100, the backup flag includes a backup flag corresponding to the internal lottery control module, a backup flag corresponding to the input / output control module, and a reach rotation control module. There are four types of backup flags, corresponding backup flags and backup flags corresponding to payout control modules. In Sa5, the game control microcomputer 100 first checks whether a backup flag corresponding to the internal lottery control module is set.

  When the backup flag corresponding to the internal lottery control module is set, the backup flag is cleared (Sa6). After clearing the backup flag, a checksum is calculated by obtaining an exclusive OR of data in an area where data used in the internal lottery control module of the SRAM 50 (backup RAM) is stored (Sa7). Thereafter, it is determined whether or not the calculated checksum matches the backed-up checksum (Sa8). In this embodiment, in Sm4, Sm9, Sm14, and Sm19 in the power interruption process (main) in FIG. Is generated by obtaining a logical OR, and stored in the SRAM 50 (backup RAM). That is, in this embodiment, regarding the processing performed by the game control microcomputer 100, the checksum is calculated using the data used in the internal lottery control module and used in the input / output control module. 4 types of checksum calculated using data, checksum calculated using data used in the reach rotation control module, and checksum calculated using data used in the payout control module There is. In Sa8, the game control microcomputer 100 first confirms whether or not the checksum calculated using the data used in the internal lottery control module matches that being backed up.

  If the checksums match, it is determined whether a backup flag corresponding to the input / output control module is set in the SRAM 50 (backup RAM) (Sa9). If the backup flag corresponding to the input / output control module is set, the backup flag is cleared (Sa10). After clearing the backup flag, a checksum is calculated by obtaining an exclusive OR of data in an area where data used by the input / output control module of the SRAM 50 (backup RAM) is stored (Sa11). Thereafter, it is determined whether or not the calculated checksum matches the backed-up checksum (Sa12).

  If the checksums match, it is determined whether a backup flag corresponding to the reel rotation control module is set in the SRAM 50 (backup RAM) (Sa14). If the backup flag corresponding to the reel rotation control module is set, the backup flag is cleared (Sa15). After clearing the backup flag, the exclusive sum of the data in the area where the data used in the reel rotation control module of the SRAM 50 (backup RAM) is stored is calculated to calculate the checksum (Sa16). Thereafter, it is determined whether or not the calculated checksum matches the backed-up checksum (Sa17).

  If the checksums match, it is determined whether a backup flag corresponding to the payout control module is set in the SRAM 50 (backup RAM) (Sa18). If the backup flag corresponding to the payout control module is set, the backup flag is cleared (Sa19). After clearing the backup flag, the checksum is calculated by obtaining the exclusive OR of the data in the area where the data used by the payout control module of the SRAM 50 (backup RAM) is stored (Sa20). Thereafter, it is determined whether or not the calculated checksum matches the backed-up checksum (Sa21).

  In Sa8, Sa12, Sa17, Sa21, when it is determined that even one checksum does not match, or in Sa5, Sa9, Sa14, Sa18, it is determined that no backup flag is set. In this case, after executing an initialization process for initializing all storage areas of the RAM 507 (work RAM) and the SRAM 50 (backup RAM) (Sa29), it is determined whether the setting key switch 37 is on (Sa30). . If the setting key switch 37 is on, a setting changing command indicating that the setting is being changed is generated, and the generated setting changing command is stored in the command buffer (Sa27). The setting changing command is immediately transmitted by executing the same process as the command transmission process of step Sk16 in the timer interrupt process described later after the process of step Sa27. Next, the game control microcomputer 100 described in FIG. 34 permits the interruption of the timer interruption process (main) executed at a constant interval (interval of 0.56 ms) (Sa28), and the winning probability of the winning combination is determined. The process shifts to a setting change process for changing, that is, a setting change state. When the setting change process is completed, the game control process shown in FIG. 33 is performed.

  In the processing of Sa28, for example, by setting the register of the timer circuit 508 provided in the game control microcomputer 100, the timer interrupt of the game control microcomputer 100 is generated every predetermined time (for example, 2 milliseconds). Configure internal settings. Thereafter, for example, the CPU 505 reads the bit value in the bit number [7], the bit number [3], etc. of the 16-bit random number initial setting first KRL1 stored in the program management area of the ROM 506. At this time, it is determined whether or not the read value is “0” for each bit value.

  If there is a bit value whose read value is “0”, the setting is made to activate the random number circuits 509A and 509B by setting the maximum value in the numerical data that becomes the random value. For example, the bit value in the bit number [3] of the 16-bit random number initial setting first KRL1 shown in FIG. 11B is set to be “0” in advance. In this case, a circuit that generates a 16-bit random number of channel ch0 in the 16-bit random number circuit 509A can be activated by setting a random number maximum value in a user program (software). Based on such setting, in the process of step S46, the CPU 505 stores predetermined numerical data in the random number maximum value setting register RL0MX corresponding to the 16-bit random number of the channel ch0 shown in FIGS. 21 (A) and (B). Write as a value. Thus, generation of a 16-bit random number corresponding to channel ch0 is started by setting the maximum random number in the user program (software).

  When the read value is “1” instead of “0”, or after setting to start the random number circuits 509A and 509B, the serial communication circuit is initialized.

  In the steps of Sa25 and Sa33, which will be described later, the same processing as that of the step of Sm25 described above is executed.

  If the setting key switch 37 is OFF in the step of Sa30, an error code indicating RAM abnormality is set in the register (Sa31), an error command indicating RAM abnormality is generated, and the generated error command is stored in the command buffer ( Sa32). The error command is transmitted immediately after the process of step Sa32 by executing the same process as the command transmission process of step Sk16 in the timer interrupt process described later. Next, the timer interrupt processing (main) interrupt that is executed by the game control microcomputer 100 described in FIG. 34 at regular intervals (0.56 ms interval) is permitted (Sa33), and error processing, that is, RAM abnormality Enter error state. Then, for example, when the RAM abnormality error state is canceled by operating the reset / setting switch 38 by a game clerk, the game control process shown in FIG. 33 is performed.

  If it is determined in Sa21 that the checksums match, it is determined whether or not the setting key switch 37 is on (Sa23). If the setting key switch 37 is on, the initialization process for initializing all the storage areas of the RAM 507 (work RAM) and the SRAM 50 (backup RAM) is executed (Sa26), and then the above-described processes of Sa27 to Sa28 are performed. , Transition to the setting change process, that is, the setting change state. When the setting change process is completed, the game control process shown in FIG. 33 is performed.

  If the setting key switch 37 is off in the step of Sa23, each register is returned to the state before power interruption, that is, the state stored in the stack (Sa24). Then, a return command is generated, the generated return command is stored in the command buffer (Sa24a), and a timer interrupt executed by the game control microcomputer 100 described in FIG. 34 at regular intervals (0.56 ms interval). The interruption of the process (main) is permitted (Sa25), and the process returns to the last executed before the power interruption. The return command is stored in a command transmission buffer assigned to a special work in the RAM 507 of the game control microcomputer 100, and a process similar to the command transmission process in step Sk16 in the timer interrupt process described later is executed. Therefore, it is sent immediately when the power failure is restored. If any of the processes in the game control process shown in FIG. 33 has been performed before the power interruption, based on the value of the program counter (PC) returned in Sa24, the game control process Sd1 to Sd7 Return to the processing that was performed before power interruption. Also, for example, if any of the timer interrupt processing shown in FIG. 34 has been performed before power interruption, the timer interrupt is based on the value of the program counter (PC) restored in Sa24. Of the processes Sk1 to Sk26, the process returns to the process performed before power interruption.

  After entering the interrupt enabled state by executing the processing of Sa25, Sa28, and Sa33, for example, a plurality of maskable interrupts at the same time in the timer circuit 508, the random number circuits 509A and 509B, or a part or all of the serial communication circuit 511, etc. When a factor occurs, the interrupt controller 504B accepts an interrupt factor with a high priority based on the designation by the bit value [2-0] of the interrupt initialization KIIS. When the interrupt controller 504B receives an interrupt factor, an interrupt request signal in an on state is output to, for example, an I class interrupt (IRQ) terminal provided in the CPU 505. When an on-state interrupt request signal is input to the IRQ terminal by the CPU 505, the generated interrupt factor is identified based on, for example, the result of checking the data stored in the internal register, and the vector address corresponding to the identified interrupt factor By executing the program having the first address as the interrupt address, interrupt processing based on each interrupt factor can be started.

  If any of the four types of errors such as an overrun error, break code error, framing error, and parity error occurs during reception of communication data by the first channel transmission / reception circuit included in the serial communication circuit 511, the first A channel receive interrupt occurs. At this time, the CPU 505 may execute a predetermined serial communication error interrupt process. In this serial communication error interrupt processing, for example, the bit values corresponding to the predetermined bit number in the predetermined first channel communication setting register and the predetermined bit number in the second channel communication setting register are both set to “0”. For example, the transmission function and the reception function in the serial communication circuit 511 may be set not to be used. Here, the first channel communication setting register and the second channel communication setting register may be included in the built-in registers of the game control microcomputer 100. Further, when an error occurs during reception of communication data by the first channel transmission / reception circuit, control may be performed to prohibit the payout of game balls by the payout device including the payout motor 51. Thereby, when an abnormality such as a reception error of communication data occurs, it is possible to prevent an excessive payout of game balls that are prize balls.

  As described above, in the start-up process (main), all the checksums of the program modules match each other and all the backup flags for the program modules are set. Since the previous state is restored, it is possible to prevent the backup data of some modules from being restored even though they are not accurate. Thereby, even if backup data is created for each module, it can be reliably restored.

  Commands transmitted from the game control microcomputer 100 to the sub-control unit 91 include a reel rotation start command, a reel stop command, a return command, a setting changing command, and an error command.

  The reel rotation start command is a command for notifying the start of reel rotation. The reel stop command is a command that can specify whether the reel to be stopped is the left reel, the middle reel, or the right reel, the area number of the corresponding reel stop operation position, and the area number of the corresponding reel stop position. It is. Since the reel stop command is transmitted when the stop switches 8L, 8C, and 8R are operated, it is possible to specify that the stop switches 8L, 8C, and 8R are operated by receiving the reel stop command. .

  The error command is a command indicating occurrence or cancellation of an error state and the type of error state.

  The return command is a command indicating that the game control microcomputer 100 has returned to the control state before power interruption.

  The setting changing command is a command indicating that the setting is being changed. Further, since the control state of the game control microcomputer 100 is initialized with the transition to the setting change state, the control state of the game control microcomputer 100 is changed by a setting change command indicating that the setting is being changed. It is possible to specify that it has been initialized.

  When the setting change command, the error command, and the return command are transmitted in the activation process shown in FIGS. 30 to 32 regarding the above-described plurality of types of commands, these commands are stored in the game control microcomputer 100. Is stored in the command transmission buffer assigned to the special work of the RAM 507, and is transmitted immediately in the startup process by executing the same process as the command transmission process in step Sk16 in the timer interrupt process described later.

  On the other hand, the reel rotation start command and the reel stop command are temporarily stored in a command transmission buffer provided in a special work in the RAM 507 of the game control microcomputer 100, and the timer interrupt process (main) shown in FIG. Is transmitted to the sub-control unit 91 in the command transmission process (Sk16) executed in step S1.

  FIG. 33 is a flowchart showing the control contents of the game control process executed by the game control microcomputer 100.

  In the game control process, a BET process (Sd1), an internal lottery process (Sd2), a reel rotation process (Sd3), a winning determination process (Sd4), a payout process (Sd5), a game end process (Sd6), an input / output process ( When the input / output process (Sd7) is completed, the process returns to the BET process (Sd1) again.

  In the BET process in the step of Sd1, the process waits in a state where a bet number can be set, and a process for starting a game when a specified number of bets is set according to the gaming state and the start switch 7 is operated is executed. .

  The internal lottery process in step Sd2 is a process executed by the game control microcomputer 100 according to the internal lottery module. In the internal lottery process in the step of Sd2, it is determined whether or not the above winning combination is allowed based on the internal lottery random value latched simultaneously with the start of the game by the detection of the start switch 7 in the step of Sd1. Process. In this internal lottery process, a winning flag is set in the RAM 507 based on each lottery result.

  The reel rotation process in step Sd3 is a process executed by the game control microcomputer 100 according to the reel rotation control module. In the reel rotation process in the step of Sd3, the process of rotating each reel 2L, 2C, 2R and the operation of the corresponding reel 2L, 2C, 2R in response to the operation of the stop switch 8L, 8C, 8R detected by the player are detected. A process for stopping the rotation is executed. A reel rotation command indicating that the reels 2L, 2C and 2R have started rotating, a reel stop command indicating the type of reel to be stopped, and a symbol to be stopped for the reel are generated in the reel rotation processing and stored in the command buffer. . Each command stored in the command buffer is transmitted to the sub-control unit 91 in the command transmission process (Sk16) executed in the timer interrupt process (main) shown in FIG. Then, it waits until the rotation of the reel (2L, 2C, 2R) corresponding to the operated stop button stops (Sf12).

  In the winning determination process in the step Sd4, when it is determined in the step Sd3 that the rotation of all the reels 2L, 2C, and 2R is stopped, the winning is determined according to the display result derived for each reel 2L, 2C, and 2R. A process of determining whether or not it has occurred is executed.

  The payout process in step Sd5 is a process executed by the game control microcomputer 100 according to the payout control module. In the payout process in step Sd5, when it is determined that a prize is generated in step Sd4, processing such as addition of credits and payout of medals is performed based on the number of payouts according to the win.

  In the game end process in the step of Sd6, a process of setting a gaming state in preparation for the next game is executed.

  The input / output process in step Sd7 is a process executed by the game control microcomputer 100 according to the input / output control module. In the input / output process in step Sd7, the input state of the input port is monitored, the presence / absence of input of various switches is detected, and the detection result is set in the input buffer. In this embodiment, for example, in the switch input determination process of Sk21 shown in FIG. 35 and the stop switch process of Sk23 shown in FIG. To check. In the input / output process in step Sd7, a process of outputting output signals to various solenoids and LEDs is performed based on the state of the output buffer. In this embodiment, for example, various output values such as LEDs are set in the output buffer in the LED dynamic display processing of Sk12 in FIG.

  34 and 35 are flowcharts showing the control contents of the timer interrupt process (main) executed by the game control microcomputer 100 interrupting and executing the start-up process and the game control process at regular intervals (0.56 ms interval). . Note that other interrupts are automatically prohibited during the execution period of the timer interrupt process (main).

  In the timer interrupt process (main), first, the register in use is saved in the stack area (Sk1).

  Next, a power failure determination process is performed (Sk2). In the power failure determination process, it is determined whether or not the power-off signal has been turned on (low level). If a power-off signal has been input, it is determined whether or not a power-off signal has been input in the previous power failure determination process. If a power-off signal has been input in the previous power failure determination process, a power failure is determined. Then, a power interruption flag indicating that is set.

  After the power failure determination process in the step of Sk2, it is determined whether or not the power interruption flag is set (Sk3). If the power interruption flag is not set, the process proceeds to Sk4 and the power interruption flag is set The process proceeds to a power interruption process (main) described later.

  In step Sk4, port input processing for inputting detection data of various switches from the input port is performed.

  Next, the branch counter for identifying the timer interrupt to be executed in the timer interrupt process (main) is advanced by 1 from the four types of timer interrupts 1 to 4 (Sk5). In this embodiment, the timer interrupt 1 is a branch process during a timer interrupt that controls the motor to control the start of the reel. Specifically, the processes from Sk9 to Sk11, such as a reel start process described later. Is done. Timer interrupt 2 is a branch process during timer interrupt that performs LED display control, time counter update, door open / close status monitoring, control signal output control, command and external output signal update, etc. Specifically, the processes of Sk12 to Sk17 such as the LED dynamic display process described later are performed. The timer interrupt 3 is a branching process during timer interrupt that detects the origin passage of the reel, monitors the switch input, and reads out the random number value. Processing of Sk20 to Sk22 such as time processing is performed. The timer interrupt 4 is a branching process during a timer interrupt that detects the input of a stop switch and performs reel stop control. Specifically, the processes of Sk23 to Sk25, such as a stop switch process described later. Is done. In the step of Sk5, 1 is added when the branch counter value is 0 to 2, and is updated to 0 when the counter value is 3. That is, the branch counter value loops in the order of 0 → 1 → 2 → 3 → 0... Each time the timer interrupt process (main) is executed.

  Next, the branch counter value is referenced to determine whether it is 2 or 3, that is, timer interrupt 3 or timer interrupt 4 (Sk6). If it is not timer interrupt 3 or timer interrupt 4, that is, timer interrupt In the case of 1 or timer interrupt 2, it is checked whether the reel motors 32L, 32C, 32R are started or whether they are rotating at a constant speed, and whether the reel motors 32L, 32C, 32R are started or are rotating at a constant speed. For example, the motor phase signal output process for outputting the phase signal data changed in the motor step process of Sk10 described later and the phase signal data changed in the final stop process of Sk24 described later is executed (Sk7).

  Next, referring to the counter value for branching, it is determined whether or not it is 1, that is, timer interrupt 2 (Sk8). If it is not timer interrupt 2, that is, timer interrupt 1, the reel motor Reel starting process (Sk9) for controlling the step time interval when starting 32L, 32C, 32R, motor step process (Sk10) for changing phase signal data of the reel motors 32L, 32C, 32R, reel motors 32L, 32C After the stop of 32R, motor phase signal standby processing (Sk11) for changing the phase signal to one-phase excitation after a predetermined time has been sequentially executed, and then the process proceeds to step Sk25.

  In the case of timer interrupt 2 in the step of Sk8, LED dynamic display processing (Sk12) for dynamically lighting various indicators, and output processing of control signals and the like for outputting data such as lighting signals of various LEDs to the output port (Sk13), a time counter update process (Sk14) for updating various time counters, a door monitoring process (Sk15) for monitoring the detection state of the door open detection switch 25, a door command transmission request, etc., set in the command buffer A command transmission process (Sk16) for transmitting various commands such as a setting change command, a return command, and an error command to the sub-control unit 91 and an external output signal update process (Sk17) for updating the external output signal are sequentially executed, and then Sk25. Go to step.

  If it is timer interrupt 3 or timer interrupt 4 in the step of Sk6, it is further determined by referring to the counter value for branching whether it is 3, that is, timer interrupt 4 (Sk18). If it is not interrupt 4, that is, if it is timer interrupt 3, the passing of the origin of the rotating reels 2L, 2C, 2R (pass of the reel reference position) is checked, and the occurrence of a reel rotation error is detected and stopped. Check if the preparation is complete (whether the stop preparation completion code is set). If the stop preparation is complete and the motor is rotating at a constant speed, operate the stop switch corresponding to the rotating reel. Processing to pass through origin (Sk20), switch input determination processing (Sk21) for determining whether or not the detection state of switches has changed, operation detection command transmission request, etc. After executing random number reading process to be stored in the random number storing work the (SK22) sequentially reads numeric data from Staphylococcus R1D, the process proceeds to step Sk26.

  If the timer interrupt is 4 in the step of Sk18, the stop stored in the work on the stop reel is stored when the stop operation position is stored in the work on the stop reel in accordance with the detection of the stop switches 8L, 8C, 8R. The stop position is determined from the operation position, the stop switch process (Sk23) for calculating the number of steps after which the stop should be performed, and the number of steps until the stop calculated in the stop switch process is counted. A stop process (Sk24) for starting braking by two-phase excitation and a final stop process (Sk25) for three-phase excitation after a certain time from the start of braking in the stop process are sequentially executed, and then the process proceeds to step Sk26.

  In the step of Sk26, the register saved in the stack area in Sk1 is restored, and the processing before the interruption is returned.

  As described above, in this embodiment, the timer interrupt process (main) is executed by interrupting the basic process at regular intervals, and the process counter is updated each time the timer interrupt process (main) is executed. In addition to distributing the load required for one timer interrupt process (main), the power interruption condition based on the voltage drop signal regardless of the process counter value. A power failure determination process is performed to determine whether or not the power failure is satisfied.If the power interruption condition is satisfied, the power interruption processing is performed. Disconnection processing can be performed.

  In the timer interrupt process (main), it is determined whether or not the power interruption condition is satisfied. If the power interruption condition is satisfied, the process proceeds to the power interruption process. Since interruptions due to power interruptions do not occur during execution of interrupt processing (main), interruption processing can be interrupted during execution of timer interruption processing (main), or timer interruption processing (main) Since it is not necessary to wait for the end of the interruption to perform an interruption process associated with power interruption, the process associated with establishment of the power interruption condition is not complicated.

  FIG. 36 is a flowchart showing the control contents of the power interruption process (main) executed when the game control microcomputer 100 determines that the power interruption signal is on in the timer interrupt process (main) described above. .

  In the power interruption process (main), first, the game control microcomputer 100 reads data used in the internal lottery control module from the work RAM (Sm1). Next, predetermined data conversion is performed on the data read from the work RAM to create backup data (Sm2). Then, the game control microcomputer 100 stores the created backup data in the SRAM 50 (backup RAM) (Sm3). Next, the game control microcomputer 100 calculates the exclusive OR of the backup data converted in Sm2, calculates the checksum of the backup data of the internal lottery control module, and sets this in the SRAM 50 (backup RAM) ( Sm4). After the checksum data is set, the game control microcomputer 100 sets a backup flag indicating that the backup has been executed in the SRAM 50 (backup RAM) (Sm5).

  Here, the data conversion process in step Sm2 will be described. In Sm1, the game control microcomputer 100 reads data of 2 bytes (16 bits) from a work RAM which is an internal memory. In this embodiment, an SRAM 50 capable of only 8-bit bus access is connected as an external memory and used as a backup RAM. As described above, in this embodiment, the game control microcomputer 100 can only perform 16-bit or 32-bit bus access to an external device such as an external memory. Then, even if the 16-bit data read from the work RAM is stored in the SRAM 50 (backup RAM) as it is, only the 8-bit data can be recognized on the SRAM 50 (backup RAM) side, so the upper 8 bits are lost, A situation occurs in which only lower 8-bit data can be stored in the SRAM 50 (backup RAM). Therefore, in the step Sm2, the 16-bit data read in Sm1 is converted into two data by performing the following data conversion process.

  First, for the first conversion data, the 16-bit data read in Sm1 is masked with the mask value “00FF (H)” as it is, and only the lower 8 bits of the original data read in Sm1 are used as the lower 8 bits. Generate data set to. For the second conversion data, the 16-bit data read in Sm1 is shifted by 8 bits (therefore, the value in the upper 8 bits of the original data is moved to the lower 8 bits). ), The data after the shift processing is masked with the mask value “00FF (H)”, and data in which the upper 8 bits of the original data read in Sm1 are set to the lower 8 bits is generated. Then, by storing these two pieces of conversion data in the SRAM 50 (backup RAM) in the step Sm3, the upper and lower values of the original data read in Sm1 are not lost, although they are divided into two data. Can backup power.

  In Sm7, Sm12, and Sm17, which will be described later, the same data conversion process as that in Sm2 described above is executed.

  Next, the game control microcomputer 100 reads data used in the input / output control module from the work RAM (Sm6). Next, predetermined data conversion is performed on the data read from the work RAM to create backup data (Sm7). Then, the game control microcomputer 100 stores the created backup data in the SRAM 50 (backup RAM) (Sm8). Next, the game control microcomputer 100 calculates the exclusive OR of the backup data converted in Sm2, calculates the checksum of the backup data of the input / output control module, and sets this in the SRAM 50 (backup RAM) ( Sm9). After the checksum data is set, the game control microcomputer 100 sets a backup flag indicating that the backup has been executed in the SRAM 50 (backup RAM) (Sm10).

  Next, the game control microcomputer 100 reads data used in the reel rotation control module from the work RAM (Sm11). Next, predetermined data conversion is performed on the data read from the work RAM to create backup data (Sm12). Then, the game control microcomputer 100 stores the created backup data in the SRAM 50 (backup RAM) (Sm13). Next, the game control microcomputer 100 calculates the exclusive OR of the backup data converted in Sm2, calculates the checksum of the backup data of the reel rotation control module, and sets it in the SRAM 50 (backup RAM) ( Sm14). After the checksum data is set, a backup flag indicating that the backup has been executed is set in the SRAM 50 (backup RAM) (Sm15).

  Next, the game control microcomputer 100 reads data used in the payout control module from the work RAM (Sm16). Next, predetermined data conversion is performed on the data read from the work RAM to create backup data (Sm17). Then, the game control microcomputer 100 stores the created backup data in the SRAM 50 (backup RAM) (Sm18). Next, the game control microcomputer 100 calculates an exclusive OR of the backup data converted in Sm2, calculates a checksum of the backup data of the payout control module, and sets it in the SRAM 50 (backup RAM) (Sm19). ). After the checksum data is set, the game control microcomputer 100 sets a backup flag indicating that the backup has been executed in the SRAM 50 (backup RAM) (Sm20).

After setting the backup flag in Sm20, access to the RAM 507 is prohibited (Sm21), and the setting of the general-purpose port corresponding to the general-purpose terminal to which the CS signal line connected to the SRAM 50 is connected is set to the input port. (Sm22), the function of outputting the chip select signal to the SRAM 50 is forcibly disabled. Thereafter, in the same manner as the processing of Sa 3 6 shown in FIG. 30, (SM23) set from performing for starting the watchdog timer 520 is provided to the reset controller 504A, by repeatedly executing an infinite loop The control state is shifted to the standby state. Since the watchdog timer 520 is not cleared and restarted after shifting to the standby state in this way, a reset operation due to the occurrence of a timeout is performed when the elapsed monitoring time is measured. Therefore, for example, after a control state in which a game control process for controlling the progress of a game in the slot machine 1 such as a timer interrupt process (main) (FIG. 34) can be executed, the power supply voltage in the slot machine 1 decreases (instantaneously). When the power-off signal is turned on due to the stop, the reset operation due to the occurrence of a timeout in the watchdog timer 520 can be performed to restart the game control microcomputer 100.

  Here, the timeout time that is the monitoring time measured by the watchdog timer 520 is set to be the longest time 225 × TSCLK × 15 among a plurality of types that can be set as the monitoring time. Therefore, for example, when the power supply is completely stopped for a predetermined period due to, for example, the power switch in the slot machine 1 being cut off, the CPU 505 or the reset controller 504A of the game control microcomputer 100 is set before the time-out occurs due to the elapse of the monitoring time. Since the power supply to is stopped, the reset operation due to the occurrence of timeout can be restricted. In this way, it can be prevented that the power switch is erroneously reset when the power switch is turned off.

In the start-up process (main) shown in FIG. 30 and the power-off process (main) shown in FIG. 36, the infinite loop process is repeatedly executed after setting the watchdog timer 520 to be started by the process of Sa 3 6 or Sm23. As a result, the control state is shifted to the standby state. After shifting to the standby state, even if the power-off signal is turned off, the game control microcomputer 100 is restarted by performing a reset operation due to occurrence of a timeout. On the other hand, even after the transition to the standby state, when the power-off signal is turned off, the standby state may be terminated and the game control process may be executed.

As an example, after executing the process of step Sa 3 shown in FIG. 30 may perform the processing as shown in FIG. 37 (A). In this case, after setting the CPU 505 to activate the watchdog timer 520 through the process of Sa 3 5A, the CPU 505 determines whether the power-off signal is in the on state through the process of Sa 3 5. At this time, if the power-off signal is in the ON state, the process waits until a predetermined time elapses due to the process of Sa 3 5B and then returns to the process of Sa 3 5. Therefore, the processes of Sa 3 5 and Sa 3 5B are repeatedly executed until the power- off signal is turned off . When the watchdog timer 520 measures that the time-out time that is the monitoring time has elapsed without the power- off signal being turned off, a reset operation due to the occurrence of time-out is performed.

On the other hand, when it is determined in the process of Sa 3 5 shown in FIG. 37 (A) that the power-off signal is in the OFF state, the setting for stopping the watchdog timer 520 is performed by the process of Sa 3 5C. , it advances to the processing of Sa 3 7 shown in FIG. 30. In the process of step S 3 5C, the WDT start register WST which CPU505 is shown in FIG. 15 (A), writes "33H" as the WDT stop data. Thus, before the occurrence of timeout, when the power-off signal by the processing of Sa 3 5 is determined to be off state, and stops the measurement of the monitoring time by the watchdog timer 520, a reset operation due to the occurrence of a timeout It may be invalidated.

Even when it is determined in the processing of Sk2 shown in FIG. 34 that the power-off signal is in the on state, after waiting for a predetermined time, it is checked again whether the power-off signal is in the on state. May be. In this case, the power-off process (main) shown in FIG. 36 is executed when it is first determined that the power-off signal is in the on state, while the power-off signal is in the on state even after waiting for a predetermined time. When it is determined, the watchdog timer 520 may be activated to enable the reset operation due to the occurrence of a timeout. When it is determined that the power-off signal is off after waiting for a predetermined time, an interrupt may be permitted after setting for stopping the watchdog timer 520 in the same manner as the processing of Sa 3 5C.

Also, processing of Sa 3 6 shown in FIG. 30, the processing of Sm23 shown in FIG. 36, or FIG. 37 in the process of step S25A shown in (A) is reset operation always starts a watchdog timer 520 due to the occurrence of a timeout It is not limited to what activates. For example, it is determined whether or not a predetermined WDT activation condition is satisfied. If the WDT activation condition is satisfied, the reset operation due to the occurrence of a timeout is validated. The reset operation due to the occurrence may be invalidated.

In this case, for example, a process as shown in FIG. 37B may be executed as the process of Sa 3 6, Sm23, and Sa 3 5A. In the process shown in FIG. 37B, the CPU 505 reads the bit value (stored value) in the bit number [1] of the internal information register CIF shown in FIG. 13A (step S71). Then, it is determined whether or not the read value is “1” (step S72). As shown in FIG. 13B, in the internal information data CIF1 stored in the bit number [1] of the internal information register CIF, whether or not the reset factor generated immediately before is due to the timeout of the watchdog timer 520. Is shown. Therefore, if the value of the internal information data CIF1 read in step S71 is “1”, it can be determined that the reset operation due to the occurrence of timeout has been performed.

  When it is determined in step S72 that the read value is not “1” but “0” (step S72; No), “CCH” is written as WDT start data in the WDT start register WST (step S73). The watchdog timer 520 is activated to enable the reset operation due to the occurrence of timeout. On the other hand, when it is determined in step S72 that the read value is “1” (step S72; Yes), the watchdog timer 520 is stopped by writing “33H” as WDT stop data in the WDT start register WST. Then, the reset operation due to the occurrence of timeout is invalidated (step S74).

  In this way, when the reset factor generated immediately before is due to the timeout of the watchdog timer 520, the reset operation due to the occurrence of the timeout is invalidated by executing the process of step S74. As a result, it is possible to prevent an inadvertent reset operation from being repeatedly performed because the stability of the power supply voltage cannot be confirmed. If it is determined in step S72 that the read value is “1”, the processing shown in FIG. 37B may be terminated without executing the processing in steps S73 and S74.

  In the startup process (main) shown in FIG. 30 to FIG. 32, the generation and storage of the return command by the process of Sa24, the generation and storage of the command being changed by the process of Sa27, and the generation and storage of the return command by the process of Sa32 are performed. By setting the maximum random number value in the random number circuits 509A and 509B at the timing after the execution and before permitting the interrupt of the timer interrupt processing (main), the random number is set by the user program (software). It is trying to start the occurrence of. Here, the timing for starting the generation of random numbers by the user program (software) may be arbitrarily set based on the specifications of the slot machine 1 and the like. For example, the random number circuits 509A and 509B may be activated and the generation of random numbers may be started at a timing prior to the determination of the power-off signal by the processing of Sa26. Alternatively, the random number circuits 509A and 509B are activated at a timing after the determination of the power-off signal by the processing of S26a and before the access permission to the RAM 507 by the processing of S4a is performed, thereby generating a random number. May be started. Alternatively, the random number circuits 509A and 509B are activated to start generation of random numbers at a timing after the access permission to the RAM 507 by the processing of S4a and before the recovery determination by the processing of Sa21 and Sa23. May be. Alternatively, the random number circuits 509 </ b> A and 509 </ b> B may be activated to start generation of random numbers at a timing after permitting the interrupt of the timer interrupt process (main).

  When such a power interruption process (main) is executed, a process for clearing the random number latch flag may be executed. For example, it is determined whether one of the bit values of the hard latch flag data RL00HF to RL01HF stored in the random number hard latch flag register RHF shown in FIG. If there is one that is “1”, the hard latch random number register 559A corresponding to the random number latch flag is read to clear all the bit values of the hard latch flag data RL00HF to RL01HF to “0”. Thus, the random number latch flag may be turned off. As a result, the bit value in the bit number [3] of the hard latch selection register RL0LS shown in FIGS. 21A and 21B is “0”, and reading of the stored value is a condition for taking in the hard latch random number value. Even in this case, the hard latch random number value register 559A can be set to a state in which storage of new numerical data is permitted. Note that the hard latch random number value register 559A may be read regardless of the bit values in the hard latch flag data RL00HF to RL01HF.

Such processing for clearing the random number latch flag is not limited to that executed when the power supply voltage is lowered due to the power-off signal being turned on. For example, in the start-up process (main) shown in FIGS. 30 to 32 that is executed in response to the start of power supply, the determination of the power-off signal by the process of Sa26 and the access permission to the RAM 507 by the process of Sa4 , Recovery determination by processing of Sa21 and Sa23, random number generation start setting by processing of Sa2 4 , Sa 27 , Sa3 2 , or initial setting of interrupt by processing of Sa2 5 , Sa 28 , Sa3 3 It may be executed at an arbitrary timing predetermined by the user program (software), such as a timing associated with.

  Here, a specific example of storing backup data of each program module in the game control board 40 in the SRAM 50 (backup RAM) will be described with reference to FIG.

  As described with reference to FIG. 36, among the four program modules of the internal lottery control module, the input / output control module, the reel rotation control module, and the payout control module, first, the backup data of the internal lottery control module is stored in the SRAM 50 (backup RAM). Store (Sm3). In the SRAM 50 (backup RAM), the start address designated when storing the backup data of the internal lottery control module is set to “0600”. Therefore, the game control microcomputer 100 starts storing backup data of the internal lottery module generated by designating “0600” as the start address in the step Sm3 and converting the data in the step Sm2. Then, until all the data for the internal lottery control module stored in the work RAM are backed up, the processes of Sm1 to Sm3 are repeatedly executed while incrementing the storage destination address of the SRAM 50 (backup RAM).

  Next, after storing the backup data of the internal lottery control module, the backup data of the input / output control module is stored in the SRAM 50 (backup RAM) (Sm8). In the backup RAM, the start address designated when storing the backup data of the input / output control module is set to “0700”. Therefore, the game control microcomputer 100 starts storing backup data of the input / output control module generated by performing data conversion in step Sm7, specifying “0700” as the start address in step Sm8. The processes of Sm6 to Sm8 are repeatedly executed while incrementing the storage destination address of the SRAM 50 (backup RAM) until backup of all data for the input / output control module stored in the work RAM is completed.

  Next, after storing the backup data of the input / output control module, the backup data of the reel rotation control module is stored in the SRAM 50 (backup RAM) (Sm13). In the backup RAM, the start address designated when storing the backup data of the reel rotation control module is set to “0800”. Therefore, the game control microcomputer 100 starts storing the backup data of the reel rotation control module generated by designating “0800” as the start address in step Sm13 and converting the data in step Sm12. Then, until all the data for the reel rotation control module stored in the work RAM is backed up, the processes of Sm11 to Sm13 are repeatedly executed while incrementing the storage destination address of the SRAM 50 (backup RAM).

  Next, after storing the backup data of the input / output control module, the backup data of the payout control module is stored in the SRAM 50 (backup RAM) (Sm18). In the backup RAM, the start address designated when storing the backup data of the payout control module is set to “0900”. Therefore, in step Sm18, the game control microcomputer 100 designates “0900” as the start address, and starts storing backup data of the payout control module generated by data conversion in step Sm17. The processes of Sm16 to Sm18 are repeatedly executed while incrementing the storage destination address of the SRAM 50 (backup RAM) until backup of all data for the payout control module stored in the work RAM is completed.

  Thus, since backup data is stored for each program module, when only one of the program modules needs to be changed in another model, only that program module needs to be replaced, and the game control program can be easily changed. . Since the start address for storing the backup data of each program module is set for each program module, it is not necessary to maintain consistency for storing the backup data even if the model is changed. The backup data may be stored at the start address set in. For this reason, it is possible to simplify the program at the time of storing the backup data, and it is possible to reduce the man-hour for developing the program. Similarly, checksum data is also created for each program module, so even if the model is changed, there is no need to maintain consistency for storing checksum data, and the program for storing checksum data is simplified. Can reduce the man-hours for program development.

  In the slot machine 1 of the present embodiment, the game control microcomputer 100 controls the progress of the game. A MAXBET switch 6, a start switch 7, and stop switches 8L, 8C, and 8R are provided as operation switches. Of these operation switches, the start switch 7 is also used for setting value setting in a setting change state.

  The game control microcomputer 100 detects these operation switches in a switch input determination process executed during a timer interrupt process (main) executed by interrupting at regular time intervals.

  The game control microcomputer 100 executes a start-up process when the power is turned on, permits an interrupt when the start-up process ends, and then executes a timer interrupt process (main) at regular intervals. If the game control microcomputer 100 can return to the state before the power interruption, a return command is transmitted to the sub-control unit 91 before interruption is permitted in the activation process. If the game control microcomputer 100 is unable to return to the state before the power interruption due to an abnormality in the data stored in the RAM 507, an error command indicating an abnormality in the RAM is issued as a sub-control before interruption is permitted in the startup process. Transmitted to the unit 91. Further, when the setting key switch 37 is in the on state and the RAM 507 is initialized and does not return to the state before the power interruption, it indicates that the setting is being changed before the interruption is permitted in the starting process. A setting change command is transmitted to the sub-control unit 91. Among the commands transmitted in the activation process, the return command specifies that the game control microcomputer 100 returns to the state before power interruption, indicates an error command indicating a RAM abnormality, and that the setting is being changed. From the setting change command, it is specified that the game control microcomputer 100 does not return to the state before power interruption.

  Next, a description will be given of the control of effects performed by the sub-control unit 91 based on a command transmitted from the game control microcomputer 100 to the effect control board 90.

  When the sub control unit 91 receives a command from the game control microcomputer 100, the sub control unit 91 executes a command reception interrupt process. In the command reception interrupt process, the command acquired from the command transmission line is stored in the reception buffer provided in the RAM 91c.

  The reception buffer is provided with an area capable of storing a maximum of 16 commands so that a plurality of commands can be accumulated.

  In the timer interrupt process (sub), the sub-control unit 91 determines whether or not an unprocessed command is stored in the reception buffer. If an unprocessed command is stored, the sub-control unit 91 is the earliest. The control pattern table stored in the ROM 91b is referred to based on the command received in the stage, and the liquid crystal display 51, effect effect LED 52, speakers 53, 54, reel LED 55, etc. are controlled based on the control contents registered in the control pattern table. Performs output control of various rendering devices.

  In the control pattern table, the display pattern of the liquid crystal display 51 corresponding to the type of command, the lighting mode of the lighting effect LED 52, the output mode of the speakers 53 and 54, the lighting mode of the reel LED, etc. Control patterns of these effect devices are registered, and when the sub-control unit 91 receives a command, the sub-control unit 91 stores the control patterns registered corresponding to the effect patterns set in the RAM 91c in the game of the control pattern table. Among these, the control pattern corresponding to the type of the received command is referred to, and the output control of the rendering device is performed based on the control pattern. Thereby, the production according to the production pattern and the progress of the game is executed.

  If the sub-control unit 91 receives a new command during execution of an effect triggered by the reception of a certain command, the sub-control unit 91 stops the effect based on the control pattern being executed, and changes to the newly received command. An effect based on the corresponding control pattern is executed. In other words, even if the production is not finished to the end, when a new command is received, the production that was being executed is canceled and a new command is received unless the received new command is not a command that triggers a new production. An effect based on the command is executed.

  When the internal winning command is received, the effect pattern is selected at a selection rate corresponding to the result of the internal lottery indicated by the internal winning command, and is set in the RAM 91c. The selection rate of the effect pattern is registered in the effect table stored in the ROM 91b, and when the sub control unit 91 receives the internal winning command, the sub control unit 91 stores the effect pattern in the effect table according to the result of the internal lottery indicated by the internal winning command. With reference to the registered selection rate, one of the effect patterns is selected from a plurality of types of effect patterns according to the selection rate, and the selected effect pattern is set in the RAM 91c as the effect pattern of the game. Even if the same command is received, a different control pattern is selected depending on the effect pattern selected when the internal winning command is received. As a result, different effects may be performed depending on the effect pattern.

  In the slot machine 1 of the present embodiment, when a predetermined symbol combination is aligned on the winning line LN, a winning is achieved. The types of winning combinations are determined according to the state of the game, but can be broadly divided into special roles with transition to big bonus and regular bonus, small roles with payout of medals, and setting of bet number. There is a re-player who can start the next game without needing.

  The big bonus may be indicated as BB and the regular bonus may be indicated as RB. In some cases, a big bonus or a regular bonus is simply referred to as a bonus. In order for each winning combination determined according to the gaming state to occur, it is necessary to set a winning flag in the RAM 507 to win the internal lottery and allow the winning of the winning combination.

  FIGS. 39 to 41 are diagrams for explaining the types of winning combinations, symbol combinations of winning combinations, and technical matters related to winning combinations. FIG. 42 is a diagram for explaining a gaming state and RT transition controlled by the gaming control microcomputer 100.

  As shown in FIG. 42, the slot machine according to the present embodiment is controlled as a normal gaming state, one in the inside, two in the inside, RB, and BB (RB) as shown in FIG. In addition, RT is a replay time in which the probability of a replay is increased. In a normal gaming state (hereinafter, the normal gaming state is referred to as normal), any type of RT (replay) from RT0 to RT4 is used. Time).

  Among the winning combinations, the special combination includes 6 types of bonuses such as big bonuses 1 to 4 and regular bonuses 1 and 2.

  BB1 is awarded when the combination of “Black 7-Black 7-Black 7” is aligned on the winning line LN. BB2 is awarded when the combination of “network 7-network 7-network 7” is aligned on the winning line LN. BB3 is awarded when the combination of “white 7-white 7-white 7” is aligned on the winning line LN. BB4 is awarded when the combination of “BAR-BAR-BAR” is aligned on the winning line LN. BB4 is awarded when the combination of “black 7-white 7-net 7” is aligned on the winning line LN.

  When winning one of BB1 to BB4, the game shifts to a big bonus that is controlled by the game every time during the BB regular bonus (hereinafter referred to as BBRB).

  The big bonus generated due to the winning of any one of BB1 to BB4 is terminated on condition that 316 or more medals have been paid out.

  RB1 wins when the winning line LN has a combination of “net 7-net 7-black 7”. RB2 is awarded when the combination of “white 7-white 7-black 7” is aligned on the winning line LN.

  When winning one of RB1 and RB2, a transition is made to a regular bonus (hereinafter referred to as RB).

  The regular bonus generated due to the winning of either RB1 or RB2 ends on the condition that any winning combination has won 6 times or 12 games have been consumed.

  As shown in FIG. 42, from the internal winning one of BB1, BB3, RB2 to winning a prize, it is controlled to 1.RT0 inside, and after winning an internal winning one of BB2, BB4, RB1 Until it is done, it is controlled to 2.RT0. Also, as shown in FIG. 18, after the big bonus or regular bonus (collectively referred to as a bonus) is completed, control is normally performed to .RT4.

  Even if one of BB1 to BB4, RB1, or RB2 is won in an internal lottery to be described later, if the stop switches 8L, 8C, and 8R are not operated at an appropriate timing to enable winning of these roles, these I won't win a role. The symbols composing BB1 to BB4, RB1, and RB2 ("black 7", "white 7", and "net 7") are arranged within 5 frames on each of the left reel 2L, middle reel 2C, and right reel 2R. This is because it has not been done.

  Next, with reference to FIG. 39, the small combination among the winning combinations will be described. Among the winning roles, there are middle bells, right-down bells, upper bells 1-8, middle watermelons, right-down watermelons, upper watermelons, lower cherries, middle cherries, one piece, right-up bells, right-up bevels, Includes a rising rivet.

  For example, the middle bell is awarded when the combination of “bell-bell-bell” is arranged on the winning line LN, and eight medals are paid out.

  Here, referring to FIG. 3, the bells are arranged within 5 frames in each of the left reel 2L, the middle reel 2C, and the right reel 2R. For this reason, it can be said that, in principle, when a middle bell is won in an internal lottery to be described later, it can be said that a winning can be made regardless of the operation timing of the stop switches 8L to 8R.

  Below, right down bell, upper bell 1-8, middle watermelon, right down watermelon, upper watermelon, lower cherry, middle cherry, one-piece, right up bell, right up bevel, right up rebebe are also shown in FIG. When the combinations of the symbols shown are complete, a prize is awarded, and the number of medals shown in FIG. 39 is paid out. As shown in FIG. 3, the right-down bell, the right-up bell, the right-up bevel, and the right-up bevel are arranged within 5 frames, so that a prize is won regardless of the operation timing of the stop switches 8L to 8R. Can be made, but the upper bell 1-8, middle watermelon, right-down watermelon, upper watermelon, lower cherry, middle cherry, 1 piece role, because there are places where the configuration symbol is not arranged within 5 frames, If a stop switch corresponding to a reel whose symbol is not arranged within 5 frames is not operated at an appropriate timing, no prize is won.

  Next, with reference to FIG. 40, the re-game combination among the winning combinations will be described. Among the winning combinations, the replaying role includes normal replay, lower stage replay, fall replay, promotion replays 1 and 2, special replay, and SP (special) replay.

  For example, the normal replay is performed when a combination of “Replay-Replay-Replay”, “Replay-Replay-Plum”, “Plum-Replay-Replay”, and “Plum-Replay-Plum” is arranged on the winning line LN. Become. Replays and plums are arranged within 5 frames in each of the left reel 2L, middle reel 2C, and right reel 2R. Therefore, as a general rule, it can be said that the normal replay is a role that can be won regardless of the operation timing of the stop switches 8L to 8R if the winning is made.

  Hereinafter, the lower replay, the fall replay, the promoted replays 1 and 2, the special replay, and the SP (special) replay are similarly awarded when the symbol combinations shown in FIG. Also, as shown in FIG. 3, each of these replays is arranged within 5 frames, so that if it is elected, it can be awarded regardless of the operation timing of the stop switches 8L to 8R. It can be said.

  As shown in FIG. 42, after winning the fall replay in normal .RT0, it is controlled to RT1.

  Also, after winning a promotion replay (promotion replay 1 or promotion replay 2) in normal .RT1, it is normally controlled to .RT0. As will be described later, the promotion replay is set so that it is not won by itself in the internal lottery in normal .RT2, normal .RT3, and normal .RT4. Also, when the special combination and the promotion replay are won at the same time in the internal lottery in normal .RT2, normal .RT3, and normal .RT4, it is controlled to 1.RT0 in the interior or 2.RT0 in the interior at that time. For this reason, in the normal .RT2, normal .RT3, and normal .RT4, no promotion replay is won. As a result, it is configured not to be controlled from normal .RT2, normal .RT3, normal .RT4 to normal .RT0, and only when it is normal .RT1, promoted replay win, and only normal .RT1 only from normal .RT0 It is comprised so that it may be controlled.

  Also, after winning a special replay in normal .RT1 and normal .RT3, it is controlled to normal .RT2. As will be described later, the special replay is set so as not to be won by itself in the internal lottery in normal .RT1 and normal.RT4. Also, when the special combination and special replay are won at the same time in the internal lottery in normal .RT1 and normal.RT4, it is controlled to 1.RT0 in the interior or 2.RT0 in the interior at that time. For this reason, special replays are not won in normal RT1 and normal RT4. As a result, it is configured not to be controlled from normal .RT1, normal .RT4 to normal .RT2, and only when it is normal .RT0 and normal .RT3, a special replay win is awarded. Only normally configured to be controlled by RT2. If the special replay is won in normal RT2, the normal RT2 is maintained.

  As shown in FIG. 42, after winning the SP replay in the normal .RT2, it is controlled to the normal .RT3. As will be described later, the SP replay is set so that it is not won independently in the internal lottery in the normal .RT0, the normal .RT1, and the normal .RT4. Also, when the special combination and SP replay are won at the same time in the internal lottery in normal .RT0, normal .RT1, and normal .RT4, it is controlled to 1.RT0 inside or 2.RT0 inside. For this reason, SP Replay is not won in normal .RT0, normal .RT1, and normal .RT4. As a result, the normal .RT0, normal .RT1, normal .RT4 to normal .RT3 are not controlled, and when the normal .RT2 is reached, the SP replay is won, and only the normal .RT2 is normal.RT3. It is comprised so that it may be controlled. When a special replay is won in normal RT3, the normal RT3 is maintained.

  Next, the transition outcome will be described with reference to FIG. As shown in FIG. 41, the transition items are composed of 20 types of combinations such as “Replay-Orange-Bell”. In this embodiment, left bells 1 to 4, middle bells 1 to 4 and right bells 1 to 4 which will be described later are elected, and the upper bells which are elected as the first stop other than the reels which become the winning conditions for the middle bells are elected. When the game is missed, the above-mentioned transition outcome is aligned with the winning line LN.

  As shown in FIG. 42, after the transition outcomes are aligned with the pay line LN in normal .RT0, normal .RT2, normal .RT3, and normal .RT4, the control is controlled to normal .RT1. Note that when the transition outcomes are aligned with the winning line LN at the normal .RT1, the normal .RT1 is maintained.

  Next, a combination of lottery target combinations that are read out as lottery target combinations for each gaming state will be described. In this embodiment, the gaming state is the normal gaming state, the inside one (BB1, BB3, RB2 is elected) or the inside 2 (BB2, BB4, RB1 is won) State), BB (RB), or RB, and the winning combination and the winning probability for the internal lottery are different. Furthermore, if the gaming state is the normal gaming state, at least one of the re-game player and the winning probability to be subject to the internal lottery differs depending on the types of RT0 to RT4. As will be described later as a lottery target combination, a plurality of winning combinations can be read out simultaneously and can be won in duplicate. In the following, “+” is indicated between winning combinations to indicate that the winning combination is simultaneously read out in the internal lottery.

  Normal. When RT0, BB1, BB1 + weak watermelon, BB1 + strong watermelon, BB1 + weak cherry, BB1 + strong cherry, BB1 + middle tier, BB1 + 1 double role, BB1 + normal replay, BB1 + fall replay, BB1 + promoted replay, BB1 + special replay, BB1 + SP Replay, BB2, BB2 + weak watermelon, BB2 + strong watermelon, BB2 + weak cherry, BB2 + strong cherry, BB2 + middle cherries, BB2 + one piece, BB2 + normal replay, BB2 + tumble replay, BB2 + promoted replay, BB2 + special replay, BB3, BB3 + weak watermelon, BB3 + strong watermelon, BB3 + weak cherry, BB3 + strong cherry, BB3 + middle cherries, BB3 + 1 sheet, BB3 + normal replay, BB3 + tumble replay, BB3 + promoted replay, BB3 + special Especially replay, BB4, BB4 + middle cherries, BB4 + 1 sheets, BB4 + special replay, RB1, RB1 + strong watermelon, RB1 + weak cherries, RB1 + strong cherry, RB1 + 1 sheets, RB2, RB2 + weak watermelon, RB2 + strong watermelon, RB2 + weak cherry, RB2 + Strong cherry, RB2 + 1 role, bell, left bell 1, left bell 2, left bell 3, left bell 4, middle bell 1, middle bell 2, middle bell 3, middle bell 4, right bell 1, right bell 2, right Bell 3, Right bell 4, Weak watermelon, Strong watermelon, Weak cherry, Strong cherry, Middle cherries, 1 part, Replay GR11, Replay GR12, Replay GR13, Replay GR14, Replay GR15, Replay GR16, Replay GR21, Replay GR22, Replay GR23, Replay GR24, and Replay GR25 are subject to internal lottery To become.

  In addition, a weak watermelon is an upper stage watermelon + right-down watermelon. That is, when the upper watermelon wins, it can be recognized that it is a weak watermelon. A strong watermelon is a middle-stage watermelon + right-down watermelon. That is, when the middle stage watermelon wins, it can be recognized that it is a strong watermelon. A weak cherry is a lower cherry alone, and a strong cherry is a lower cherry plus one piece. In the weak cherries, the combination of “BAR-BAR-BAR” in the middle stage can be recognized as weak cherries, whereas the cherry stops in the lower stage of the left reel 2L, and “BAR-BAR in the middle stage. It can be recognized that it is a strong cherry when the combination of “−BAR” is prepared.

  The promotion replay is promotion replay 1 + promotion replay 2. The bell is a middle bell + a downward-sloping bell. Left bell 1 is right falling bell 5 + upper bell 5 + upper bell 8, left bell 2 is right falling bell + upper bell 6 + upper bell 7, and left bell 3 is right falling bell + upper bell 2 + upper bell 3, left bell 4 is right falling bell + upper bell 2 + upper bell 4. The left bells 1 to 4 are also simply called left bells. The middle bell 1 is the middle bell + the upper bell 2 + the upper bell 5, the middle bell 2 is the middle bell + the upper bell 1 + the upper bell 6, and the middle bell 3 is the middle bell + the upper bell 4 + the upper bell. 7 and the middle bell 4 is the middle bell + the upper bell 3 + the upper bell 8. The middle bells 1 to 4 are also simply called middle bells. The right bell 1 is the middle bell + the upper bell 3 + the upper bell 5, the right bell 2 is the middle bell + the upper bell 1 + the upper bell 7, and the right bell 3 is the middle bell + the upper bell 4 + the upper bell. 6 and the right bell 4 is the middle bell + the upper bell 2 + the upper bell 8. The right bells 1 to 4 are also simply called right bells. The left bells 1 to 4, the middle bells 1 to 4, and the right bells 1 to 4 are also simply referred to as push order bells.

  Replay GR11 is a fall replay + promotion replay 2, replay GR12 is a fall replay + promotion replay 2 + normal replay, replay GR13 is a fall replay + promotion replay 1, and replay GR14 is a fall Replay + promotion replay 1 + normal replay, replay GR15 is fall replay + promotion replay 1 + promotion replay 2, and replay GR16 is fall replay + promotion replay 1 + promotion replay 2 + normal replay.

  Replay GR21 is tumble replay + special replay, replay GR22 is tumble replay + special replay + normal replay, replay GR23 is tumble replay + special replay + lower replay, and replay GR24 is Tumble replay + special replay + normal replay + lower replay. Replay GR25 is tumble replay + special replay + promotion replay 1.

  Normal. When RT1, BB1, BB1 + weak watermelon, BB1 + strong watermelon, BB1 + weak cherry, BB1 + strong cherry, BB1 + middle cherries, BB1 + 1 sheet, BB1 + normal replay, BB1 + fall replay, BB1 + promoted replay, BB1 + special replay, BB1 + SP Replay, BB2, BB2 + weak watermelon, BB2 + strong watermelon, BB2 + weak cherry, BB2 + strong cherry, BB2 + middle cherries, BB2 + one piece, BB2 + normal replay, BB2 + tumble replay, BB2 + promoted replay, BB2 + special replay, BB3, BB3 + weak watermelon, BB3 + strong watermelon, BB3 + weak cherry, BB3 + strong cherry, BB3 + middle cherries, BB3 + 1 sheet, BB3 + normal replay, BB3 + tumble replay, BB3 + promoted replay, BB3 + special Especially replay, BB4, BB4 + middle cherries, BB4 + 1 sheets, BB4 + special replay, RB1, RB1 + strong watermelon, RB1 + weak cherries, RB1 + strong cherry, RB1 + 1 sheets, RB2, RB2 + weak watermelon, RB2 + strong watermelon, RB2 + weak cherry, RB2 + Strong cherry, RB2 + 1 role, bell, left bell 1, left bell 2, left bell 3, left bell 4, middle bell 1, middle bell 2, middle bell 3, middle bell 4, right bell 1, right bell 2, right Bell 3, right bell 4, weak watermelon, strong watermelon, weak cherry, strong cherry, middle tier cherry, 1 part, normal replay, replay GR1, replay GR2, replay GR3, replay GR4, replay GR5, replay GR6 are internal lottery It becomes a target role.

  Replay GR1 is normal replay + promotion replay 1, replay GR2 is normal replay + promotion replay 1 + promotion replay 2, replay GR3 is normal replay + promotion replay 1 + lower replay, and replay GR4. Is normal replay + promotion replay 1 + promotion replay 2 + lower replay, replay GR5 is normal replay + promotion replay 2, and replay GR6 is normal replay + promotion replay 2 + lower replay.

  Normal. When RT2, BB1, BB1 + weak watermelon, BB1 + strong watermelon, BB1 + weak cherry, BB1 + strong cherry, BB1 + middle cherries, BB1 + 1 double role, BB1 + normal replay, BB1 + fall replay, BB1 + promoted replay, BB1 + special replay, BB1 + SP Replay, BB2, BB2 + weak watermelon, BB2 + strong watermelon, BB2 + weak cherry, BB2 + strong cherry, BB2 + middle cherries, BB2 + one piece, BB2 + normal replay, BB2 + tumble replay, BB2 + promoted replay, BB2 + special replay, BB3, BB3 + weak watermelon, BB3 + strong watermelon, BB3 + weak cherry, BB3 + strong cherry, BB3 + middle cherries, BB3 + 1 sheet, BB3 + normal replay, BB3 + tumble replay, BB3 + promoted replay, BB3 + special Especially replay, BB4, BB4 + middle cherries, BB4 + 1 sheets, BB4 + special replay, RB1, RB1 + strong watermelon, RB1 + weak cherries, RB1 + strong cherry, RB1 + 1 sheets, RB2, RB2 + weak watermelon, RB2 + strong watermelon, RB2 + weak cherry, RB2 + Strong cherry, RB2 + 1 role, bell, left bell 1, left bell 2, left bell 3, left bell 4, middle bell 1, middle bell 2, middle bell 3, middle bell 4, right bell 1, right bell 2, right Bell 3, right bell 4, weak watermelon, strong watermelon, weak cherry, strong cherry, middle tier cherry, single role, normal replay, replay GR31, replay GR32, replay GR33, replay GR34, replay GR35, replay GR36 are internal lottery It becomes a target role.

  Replay GR31 is special replay + SP replay + normal replay, replay GR32 is special replay + SP replay + normal replay + falling replay, and replay GR33 is special replay + SP replay + lower replay, and replay GR34. Is special replay + SP replay + lower replay + falling replay, replay GR35 is special replay + SP replay + normal replay + lower replay, and replay GR36 is special replay + SP replay + normal replay + lower replay + It is a fall replay.

  Normal. When RT3, BB1, BB1 + weak watermelon, BB1 + strong watermelon, BB1 + weak cherry, BB1 + strong cherry, BB1 + middle cherries, BB1 + 1 double play, BB1 + normal replay, BB1 + fall replay, BB1 + promoted replay, BB1 + special replay, BB1 + SP Replay, BB2, BB2 + weak watermelon, BB2 + strong watermelon, BB2 + weak cherry, BB2 + strong cherry, BB2 + middle cherries, BB2 + one piece, BB2 + normal replay, BB2 + tumble replay, BB2 + promoted replay, BB2 + special replay, BB3, BB3 + weak watermelon, BB3 + strong watermelon, BB3 + weak cherry, BB3 + strong cherry, BB3 + middle cherries, BB3 + 1 sheet, BB3 + normal replay, BB3 + tumble replay, BB3 + promoted replay, BB3 + special Especially replay, BB4, BB4 + middle cherries, BB4 + 1 sheets, BB4 + special replay, RB1, RB1 + strong watermelon, RB1 + weak cherries, RB1 + strong cherry, RB1 + 1 sheets, RB2, RB2 + weak watermelon, RB2 + strong watermelon, RB2 + weak cherry, RB2 + Strong cherry, RB2 + 1 role, bell, left bell 1, left bell 2, left bell 3, left bell 4, middle bell 1, middle bell 2, middle bell 3, middle bell 4, right bell 1, right bell 2, right Bell 3, right bell 4, weak watermelon, strong watermelon, weak cherry, strong cherry, middle tier cherry, 1 part, replay GR31, replay GR32, replay GR33, replay GR34, replay GR35, replay GR36, SP replay are internal lottery It becomes a target role.

  Normal. When RT4, BB1, BB1 + weak watermelon, BB1 + strong watermelon, BB1 + weak cherry, BB1 + strong cherry, BB1 + middle tier, BB1 + 1 double role, BB1 + normal replay, BB1 + fall replay, BB1 + promoted replay, BB1 + special replay, BB1 + SP Replay, BB2, BB2 + weak watermelon, BB2 + strong watermelon, BB2 + weak cherry, BB2 + strong cherry, BB2 + middle cherries, BB2 + one piece, BB2 + normal replay, BB2 + tumble replay, BB2 + promoted replay, BB2 + special replay, BB3, BB3 + weak watermelon, BB3 + strong watermelon, BB3 + weak cherry, BB3 + strong cherry, BB3 + middle cherries, BB3 + 1 sheet, BB3 + normal replay, BB3 + tumble replay, BB3 + promoted replay, BB3 + special Especially replay, BB4, BB4 + middle cherries, BB4 + 1 sheets, BB4 + special replay, RB1, RB1 + strong watermelon, RB1 + weak cherries, RB1 + strong cherry, RB1 + 1 sheets, RB2, RB2 + weak watermelon, RB2 + strong watermelon, RB2 + weak cherry, RB2 + Strong cherry, RB2 + 1 role, bell, left bell 1, left bell 2, left bell 3, left bell 4, middle bell 1, middle bell 2, middle bell 3, middle bell 4, right bell 1, right bell 2, right Bell 3, right bell 4, weak watermelon, strong watermelon, weak cherry, strong cherry, middle cherries, one-piece combination, and normal replay are targeted for internal lottery.

  When the inner center is 1.RT0 and the inner center is 2.RT0, the bell, the left bell 1, the left bell 2, the left bell 3, the left bell 4, the middle bell 1, the middle bell 2, the middle bell 3, the middle bell 4, the right Bell 1, Right bell 2, Right bell 3, Right bell 4, Weak watermelon, Strong watermelon, Weak cherry, Strong cherry, Middle cherry, Single role, Normal replay, Lower replay, SP replay, Tumble replay, Promotion replay, Special Replay is the target for internal lottery.

  When it is BBRB.RT0, the weak cherry and all roles are subject to internal lottery, and when it is RB.RT0, all roles, RB bell 1, RB bell 2, and RB bell 3 are subject to internal lottery.

  All roles are all small roles other than right-up bevel, ie middle bell + right-down bell + upper bell 1 + upper bell 2 + upper bell 3 + upper bell 4 + upper bell 5 + upper bell 6 + upper bell 7 + upper bell 8 + middle watermelon + Lower right watermelon + upper watermelon + lower cherry + middle cherries + 1 piece + right rising bell + right rising rivet.

  The RB bell 1 is a right-up bell + right-up bevel, the RB bell 2 is a right-up bell + right-up bevel + right-up beryl, and the RB bell 3 is all small roles, that is, the middle stage bell. + Downward bell + Upper bell 1 + Upper bell 2 + Upper bell 3 + Upper bell 4 + Upper bell 5 + Upper bell 6 + Upper bell 7 + Upper bell 8 + Middle watermelon + Lower watermelon + Upper watermelon + Lower cherry + Middle cherry + Single role + Upright Bell + bevel up to the right + bevel up to the right.

  Also, usually at RT0-4, etc., weak watermelon, strong watermelon, weak cherry, strong cherry, middle cherry, single tier, normal replay, fall replay, promotion that can be elected simultaneously with any of BB1-BB4, RB1, RB2 Replay and SP replay decision values are 1.RT0 for internal and 2.RT0 for internal, and are read separately from bonuses, strong watermelon, weak cherry, strong cherry, middle cherries, one-piece role, normal Since it is added to Replay, Tumble Replay, Promotion Replay, and SP Replay, the winning probability of each of Strong Watermelon, Weak Cherry, Strong Cherry, Middle Cherry, Single Role, Normal Replay, Tumble Replay, Promotion Replay, and SP Replay is constant. It is secured to be.

  In this way, the internal lottery role varies depending on whether the gaming state is the normal gaming state, 1 or 2 inside, BB (RB), or RB, and BB (RB) In RB, the internal lottery is performed using a lottery table in which the winning probability of the small role is set higher than that in the normal gaming state and inside.

  Also, when the game state is 1 or 2 in the inside, the subject of the internal lottery does not change depending on whether it is 1 in the inside or 2 in the inside, but it is 1 in the inside or inside The internal lottery is performed using a lottery table in which the winning probabilities of the target re-gamer are different.

  In addition, when the gaming state is the normal gaming state, the re-game player to be subject to the internal lottery differs depending on whether it is RT0-4, and depending on whether it is RT0-4 An internal lottery is performed using a lottery table with different re-game players and their winning probabilities.

  As will be described in detail later, in this embodiment, when a plurality of types of small roles (bells) and a plurality of types of replaying players are simultaneously elected, the type of the selected small role or replaying role and a stop switch Control is performed so that the symbol combination of the small combination and the combination of the re-playing combination determined according to the pressing order of 8L, 8C, and 8R are aligned and stopped on the winning line LN within the drawing range of up to four frames. Therefore, the types of small combination and re-playing combination to be won simultaneously will be described in detail with reference to FIGS. 43 to 45. FIG. 43 shows a list of small combinations and re-playing combination to be won simultaneously. FIG. 44 shows reel control when a plurality of replays are won simultaneously, and FIG. 45 shows reel control when a plurality of small roles are won simultaneously.

  As shown in FIG. 43 and FIG. 44, for example, when the replay GR1 (normal replay + promotion replay 1) is won and the stop operation is performed in the order of left middle right, the promotion replay among the replaying players who have won. Control is performed so that one combination is aligned with the winning line LN and stopped, and when a stop operation is performed in an order other than the left middle right, control is performed so that the combination of normal replays is aligned with the winning line LN and stopped.

  Similarly, when the replays GR2 to 6 are stopped in a predetermined order, the combination of the promoted replay 1 or the promoted replay 2 among the selected re-playing players is stopped in alignment with the winning line LN. If the stop operation is performed in an order other than the predetermined order, control is performed so that the combination of the normal replays is aligned with the winning line LN and stopped.

  As shown in FIG. 3, the symbols constituting the promoted replay 1, the promoted replay 2, and the normal replay are arranged at intervals of 5 frames or less on all of the left reel 2L, the middle reel 2C, and the right reel 2R, so that the stop The reel control is performed so that the promotion replay 1, the promotion replay 2 or the normal replay always wins regardless of the stop operation timing of the stop switches 8L to 8R according to the operation order.

  For this reason, replays GR1 to 6 are usually subject to internal lottery.In RT1, if any of replays GR1 to GR6 is elected, the promotion replay will be won with a probability of 1/6, and normally it will be RT0. Will be migrated.

  Similarly, when the replays GR11 to 16 are stopped in a predetermined order, the combination of the promoted replay 1 or the promoted replay 2 among the selected re-playing players is aligned with the winning line LN and stopped. If the stop operation is performed in an order other than the predetermined order, control is performed so that the combination of falling replays is aligned with the winning line LN and stopped.

  As shown in FIG. 3, the symbols constituting the promotion replay 1, the promotion replay 2, and the fall replay are arranged at intervals of 5 frames or less on all of the left reel 2L, the middle reel 2C, and the right reel 2R. The reel control is performed so that the promotion replay 1, the promotion replay 2 or the fall replay always wins regardless of the stop operation timing of the stop switches 8L to 8R according to the operation order.

  For this reason, the replay GRs 11-16 are usually subject to internal lottery.If any of the replays GR11-16 is elected in RT0, the promotion replay wins with a probability of 1/6, and normal RT0 is maintained. On the other hand, the fall replay wins with a probability of 5/6, and the game moves to normal RT1.

  In addition, in the replays GR21 to GR25, when a stop operation is performed in a predetermined order, the special replay combination among the selected replay players is controlled so as to be aligned with the winning line LN and stopped. When stop operations are performed in order, control is performed so that the combination of falling replays is aligned with the winning line LN and stopped.

  As shown in FIG. 3, since the symbols constituting the special replay and the fall replay are arranged at intervals of 5 frames or less in all of the left reel 2L, the middle reel 2C, and the right reel 2R, Regardless of the stop operation timing of the stop switches 8L to 8R, the reel control is performed so that the special replay or the fall replay is always won.

  Therefore, replay GR21-25 is subject to internal lottery. In RT0, if any of replay GR21-25 is selected, special replay wins with a probability of 1/5 and transitions to normal RT2. On the other hand, the fall replay wins with a probability of 4/5, and the game moves to normal RT1.

  Further, in the replay GR31 to 36, when the stop operation is performed in a predetermined order (left push), the control for stopping the combination of the SP replay or the normal replay among the selected replay players in the winning line LN is stopped. If the stop operation is performed in an order other than the predetermined order, the special replay combination is controlled to be aligned with the winning line LN and stopped.

  As shown in FIG. 3, the symbols constituting the SP replay, special replay, and normal replay are arranged at intervals of 5 frames or less on all of the left reel 2L, the middle reel 2C, and the right reel 2R. Accordingly, the reel control is performed so that the SP replay, special replay, or normal replay always wins regardless of the stop operation timing of the stop switches 8L to 8R.

  Also, replay GR31-36 is the target of internal lottery. In RT3, if any one of replay GR31-36 is won, SP replay wins with a probability of 1/6 and there is one Navistock which will be described later On the other hand, the normal replay wins with the probability of 1/6 and the normal .RT3 is maintained, and the special replay wins with the probability of 4/6 and shifts to the normal .RT2.

  As shown in FIGS. 43 and 45, when the left bells 1 to 5 are elected and the stop operation is performed by pressing the left button, the combination of the right falling bells of the elected small roles is aligned with the winning line LN and stopped. When the stop operation is performed by middle press or right press, the control is performed so that any combination of the upper bells 2 to 8 or the shift outcome is aligned with the pay line LN.

  As shown in FIG. 3, the configuration symbol of the right-down bell is arranged at intervals of 5 frames or less on all reels, and when the left bells 1 to 4 are elected, a stop operation is performed by pushing left. In this case, regardless of the timing of the stop operation, control is always performed so that the right lowering bell is aligned with the winning line LN, while the symbols constituting the upper bells 1 to 8 are at intervals of 5 frames or more on all reels. Even if the left bells 1 to 4 are elected because there are places that are arranged, if the stop operation is performed by pressing the middle or right, it becomes the drawing range of the constituent symbols of the elected upper bells 1 to 8 If the stop operation is not performed at an appropriate timing, the winning upper bell cannot be aligned with the winning line LN, and in this case, the control is performed so that the transition outcome is aligned with the winning line LN.

  In addition, when the middle bells 1 to 4 are elected and the stop operation is performed by pressing the middle bell, the combination of the middle bells among the selected small roles is controlled to be aligned with the winning line LN and stopped, and left or right pressed. When the stop operation is performed at, control is performed so that any combination of the upper bells 1 to 8 or the transition outcome is aligned with the winning line LN and stopped.

  As shown in FIG. 3, the configuration symbols of the middle bell are arranged at intervals of 5 frames or less on all reels, and when the middle bell 1 to 4 is elected, when the stop operation is performed by middle push Regardless of the timing of the stop operation, control is always performed so that the middle bell is aligned with the winning line LN, while the symbols constituting the upper bells 1 to 8 are arranged at intervals of 5 frames or more on all reels. Even if the middle bells 1 to 4 are elected, if the stop operation is performed by pressing left or right, an appropriate range that will be drawn in the constituent symbols of the elected upper bells 1 to 8 will be used. If the stop operation is not performed at the timing, the selected upper bell cannot be aligned with the winning line LN, and in this case, control is performed so that the shift outcome is aligned with the winning line LN.

  If right bells 1 to 4 are elected and stop operation is performed by pressing right, control is performed to stop the combination of middle bells in the selected small role in line with winning line LN, and stop by pressing left or middle. When an operation is performed, control is performed to stop any combination of the upper bells 1 to 8 or the transition outcome in line with the pay line LN.

  As shown in FIG. 3, the configuration symbols of the middle bell are arranged at intervals of 5 frames or less on all reels, and when the right bell 1 to 4 is elected, when the stop operation is performed by pushing right However, regardless of the timing of the stop operation, control is always performed so that the middle bell is aligned with the winning line LN, while the symbols constituting the upper bells 1 to 8 are arranged at intervals of 5 frames or more on all reels. Therefore, even if the right bells 1 to 4 are elected, if the stop operation is performed by left-pressing or middle-pressing, an appropriate drawing range of the constituent symbols of the elected upper bells 1 to 8 is appropriate. If the stop operation is not performed at the timing, the selected upper bell cannot be aligned with the winning line LN, and in this case, control is performed so that the shift outcome is aligned with the winning line LN.

  Thus, in this embodiment, when any of the left bell, middle bell, right bell, that is, the push order bell is won, by performing a stop operation in a specific operation mode according to the type of winning combination, While the right-down bell or middle bell always wins, if the stop operation is performed in an operation mode other than the specific operation mode according to the type of winning combination, the upper bell is aligned at 1/4, but at 3/4 In some cases, the upper bells are not aligned and the transition outcomes are aligned.

  For this reason, at the time of winning the push order bell, the expected value of the number of medals to be paid out can be changed depending on whether or not it is operated in a specific operation mode according to the type of winning combination. In other words, even if one of the push order bells is won, it is impossible to intentionally select a specific operation mode unless the type is known. Although a medal can be surely obtained by winning a prize, the upper bell can be won only by 1/4 at a ratio of 2/3, and a medal cannot be surely obtained.

  When RB bell 1 (Right-up bell + Right-up Rivebe) is elected and a stop operation is performed by left-pressing, control is performed so that the combination of right-up bells among the selected small roles is aligned with the winning line LN and stopped. If a stop operation is performed by middle pressing or right pressing, control is performed to align the combination of rising right ribs on the winning line LN and stop.

  If RB Bell 2 (Rising Right Bell + Right Rising Bevel + Right Rising Berri) is won and stopped by pressing the middle, the combination of the right rising bells of the selected small roles is aligned with the winning line LN and stopped. If the stop operation is performed by pressing the button to the left, the control is performed to stop the right-up bevel combination in alignment with the winning line LN. If the stop operation is performed by pressing the button to the right, Control is performed to stop the combination in line with the winning line LN.

  RB bell 3 (middle bell + lower right bell + upper bell 1 + upper bell 3 + upper bell 4 + upper bell 5 + upper bell 6 + upper bell 7 + upper bell 8 + middle watermelon + lower watermelon + upper watermelon + lower cherry + middle cherry +1 sheet role + right-up bell + right-up bevel + right-up bevel), and if the stop operation is performed by pressing right, the combination of right-up bells in the selected small role is aligned with the winning line LN Control to stop is performed, and when a stop operation is performed by left-pressing or middle-pressing, control is performed to stop the right-beveled bevel combination aligned with the winning line LN.

  As shown in FIG. 3, the configuration symbols of the right-up bell, the right-up bevel, and the right-up bevel are arranged at intervals of 5 frames or less on all reels, and when the RB bells 1 to 4 are won, Regardless of the timing of the stop operation, any combination of right-up bell, right-up ribebe and right-up bevel will be aligned on the winning line LN and 10 medals will be paid out, but at a rate of 1/3 Only "bell-bell-bell" combinations will be aligned to the right.

  Although not particularly shown, when a bell (middle bell + lower right bell) is won, a combination of “bell-bell-bell” is arranged on the winning line LN regardless of the stop order of the reels and the operation timing. To be controlled.

  Also, all roles (middle bell + lower right bell + upper bell 1 + upper bell 2 + upper bell 3 + upper bell 4 + upper bell 5 + upper bell 6 + upper bell 7 + upper bell 8 + middle watermelon + right lower watermelon + upper watermelon + lower cherry + middle (Cherry + 1 hand + right-up bell + right-up rivebe) is selected, the “bell-bell-bell” combination is controlled to rise to the right regardless of the reel stop order and operation timing. The

  In this embodiment, as shown in FIG. 42, the game is controlled to any one of the normal game state, internal 1, internal 2, RB, BB (RB), and in the normal game state, any of RT 0 to 4 is controlled. To be controlled.

  Normal.RT0 is a normal .RT1 when a promotion replay wins (when any of the replays GR1 to GR6 is elected and a stop operation is performed in the order in which the promotion replay wins). Shifts when the game is completed due to the consumption of the specified number of games. Regardless of the number of games since the transition to normal .RT0, the normal .RT0 transitions to normal .RT1 by winning a fall replay or stopping the transition, or to normal .RT2 by winning a special replay It ends when the special role is elected and moves to the inside 1 or inside 2 inside.

  The normal .RT1 shifts when the transition start stops at the normal .RT0, normal .RT2, normal .RT3, and normal .RT4, or when the fall replay wins at the normal .RT0. The normal RT1 is such that the number of remaining RT games is subtracted for each game, and the normal number of RT remaining games is reduced to 0 by digesting the specified number of games (1000G in this embodiment). It ends when it shifts to .RT0 or when the special role is elected and shifts to internal 1 or internal 2.

  The normal .RT2 shifts when the special replay wins in the normal .RT0 or the normal .RT3. The normal RT2 is such that the number of remaining RT games is subtracted for each game, and the normal number of RT remaining games is reduced to 0 by digesting the specified number of games (30G in this embodiment). Move to .RT0, SP Replay wins and move to normal .RT3, or the transfer roll stops and then shifts to normal .RT1 or the special role is elected and becomes 1 in internal or 2 in internal It ends by migrating.

  The normal RT3 shifts when the SP replay wins in the normal RT2. Regardless of the number of games since the transition to normal .RT3, whether or not the special replay wins the normal .RT3 and the transition to normal .RT2 or the transition outcome stops and the transition to normal .RT1 When the special role is elected and moves to the inside 1 or the inside 2, it ends.

  Normally, RT4 shifts at the end of BB (RB) and RB. Regardless of the number of games since transitioning to normal RT4, normal RT4 will either stop the transition and shift to RT1, or the special role will be elected to shift to internal 1 or internal 2 To finish.

  The inside 1 shifts when BB1, BB3, RB2 among the special roles are won in the normal gaming state. Then, regardless of the number of games since the transition to the inside, the inside 1 finishes when the special role that triggered the transition to the inside 1 wins and shifts to BB (RB) or RB. .

  The inside 2 shifts when BB2, BB4, RB1 among special roles are won in the normal gaming state. Then, inside 2 ends regardless of the number of games since the transition to the inside, when the special combination that triggered the transition to the inside 2 wins and shifts to BB (RB) or RB. .

  RB shifts when RB1 or RB2 wins in 1 and 2 inside. And RB is complete | finished by digesting 12 games or winning 6 times.

  BB (RB) shifts when BB wins inside. Then, BB (RB) ends when the total number of medals paid out to BB (RB) exceeds the prescribed number, regardless of the number of games since the transition to BB (RB).

  Further, in the slot machine according to the present embodiment, when the gaming state is RT0 to 3, the sub-control unit 91 provides an assist time (hereinafter referred to as AT) that is a notification period in which a navigation effect that notifies the internal lottery result can be executed. The production state can be controlled.

  Here, the gaming state and the transition state of RT will be described. As shown in FIG. 42, when RB or BB (RB) is completed, the state normally shifts to RT4.

  Normally, in RT4, when the transition outcome is stopped, the process proceeds to RT1, and when the special role is elected, it shifts to the internal 1 or the internal 2 depending on the type of the special role selected.

  Normally, at RT4, if any of the left bell 1-4, middle bell 1-4, right bell 1-4 is won and the small role cannot be won, the transitional outcome will stop. Therefore, after the end of RB or BB (RB), one of the left bells 1-4, middle bells 1-4, right bells 1-4 can be elected and the small role can be won in the normal .RT4 If not, it will normally shift to .RT1.

  Normally, in RT1, the special role is not won, the promotion replay is not won, and the specified number of games (1000G) is consumed, or the promotion replay wins. Depending on the type of the special role that has been won, the game moves to the inside 1 or 2 inside.

  Usually, since replays GR1 to 6 are elected in RT1 and the replay order is correct, the promoted replay will be awarded, so in normal RT1, replays GR1 to 6 are elected and usually answered in the order of stoppage. It will shift to RT0.

  Normally, at RT0, when the fall replay wins, or when the transition is stopped, it usually shifts to RT1, and when the special replay wins, it usually shifts to RT2, and the special role is won. Depending on the type of the special role, it shifts to 1 inside or 2 inside.

  Usually, the replays GR11 to 16 are elected at RT0, the promotion replay wins when the stop order is correct, and the fall replay wins when the answer is incorrect. Also, normally, the replays GR21 to 25 are won at RT0, and the special replay wins when the stop order is correct, and the fall replay wins when the answer is incorrect. In addition, when the left bell 1 to 4, the middle bell 1 to 4, or the right bell 1 to 4 are won in normal .RT0 and the small role cannot be won, the transitional outcome stops. For this reason, in normal .RT0, replay GRs 21 to 25 are elected and the stop order is correct, so normal.RT2 is entered, and replay GRs 11 to 16 are elected and the stop order is incorrect or left bell 1 -4, middle bell 1 to 4, right bell 1 to 4 are elected, and if it is not possible to win a small role, it will normally shift to RT1.

  Normally, in RT2, the special role is not won, SP replay is not won, and the regular game number (30G) is used to move to normal .RT0, and SP replay is won to move to normal .RT3, When the special role is elected, it shifts to 1 inside or 2 inside depending on the kind of the special role won.

  Normally, the replay GRs 31 to 36 are won at RT2, and the SP replay wins when the stop order is correct. In addition, when the left bell 1 to 4, the middle bell 1 to 4, or the right bell 1 to 4 are won in normal RT 2, and the small role cannot be won, the transitional outcome stops. For this reason, in normal .RT2, replay GR31-36 is elected, and when the stopping order is correct, it moves to normal .RT3, and any of left bell 1-4, middle bell 1-4, right bell 1-4 Will be transferred to .RT1 if the winning combination is not made and the small role cannot be won.

  Normally, in RT3, when the special replay wins, it moves to RT2, and when the transition roll stops, it shifts to RT1, and when the special role is elected, it is internal depending on the type of special role won. Transition to Medium 1 or Internal 2

  Normally, the replay GRs 31 to 36 are won at RT3, and the SP replay or the normal replay is won when the stop order is correct, and the special replay is won when the answer is incorrect. In addition, in the normal .RT3, when any one of the left bell 1 to 4, the middle bell 1 to 4 and the right bell 1 to 4 is won and the small role cannot be won, the transitional outcome is stopped. Therefore, in normal .RT3, the replay GRs 31 to 36 are elected and the stop order is incorrect, so the routine proceeds to .RT2 and the left bell 1 to 4, the middle bell 1 to 4, the right bell 1 to 4 If one of them wins and the small combination cannot be won, the routine will shift to .RT1.

  In the inside 1 and 2, the special role that triggers the transition to the inside wins a transition to RB or BB (RB).

  A specific operation example in the slot machine 1 will be described below.

  In the game control microcomputer 100, for example, the CPU 505 uses numerical data indicating a random number value for internal lottery based on numerical data read from the hard latch random value register 559A of the random number circuit 509A in step Sd2 of FIG. Decide whether to allow winnings in each role. In the random number circuit 509A, for example, the random number sequence change circuit 554A changes the count value permutation RCN output from the random number generation circuit 553A based on a random number update rule predetermined by the setting of the random number sequence change setting circuit 554B. Subsequently, after being compared with a random number maximum value set by a user program (software) or the like in the maximum value comparison circuit 555, a random number sequence RSN in which numerical data is updated by a predetermined procedure is output. Then, based on the detection signal SS1 from the start switch 7 input to the input port PI0 being turned on, the numerical data constituting the random number sequence RSN is taken into the hard latch random value register 559A as a random value and stored. Is done.

  FIG. 46 is a timing chart for explaining the operation of the random number circuit 509A. FIG. 46A shows a control clock CCLK generated by the control clock generation circuit 111 mounted on the game control board 40. FIG. 46B shows the random number clock RCK generated by the random number clock generation circuit 112. The various signals shown in FIG. 46 are assumed to be negative logic signals that are turned off at a high level and turned on at a low level. As shown in FIGS. 46A and 46B, the oscillation frequency of the control clock CCLK and the oscillation frequency of the random number clock RCK are different from each other. It does not become an integral multiple of the other oscillation frequency.

  As shown in FIG. 46B, the random number clock RCK falls from the high level to the low level at timings T10, T11, T12,. The random number clock RCK is divided by two and then input to the random number update clock selection circuit 551 of the random number circuit 509A. When such a random number clock RCK divided by two (RCK / 2) is selected by the random number update clock selection circuit 551, the random number update clock RGK has timings T10, T12 as shown in FIG. , T14,..., Fall from a high level to a low level, and become a signal having an oscillation frequency that is ½ of the oscillation frequency of the random number clock RCK. For example, if the oscillation frequency of the random number clock RCK is 20 MHz, the oscillation frequency of the random number update clock RGK is 10 MHz. Since the oscillation frequency of the random number clock RCK is neither an integral multiple nor a fraction of the oscillation frequency of the control clock CCLK, the oscillation frequency of the random number update clock RGK is the oscillation frequency of the control clock CCLK. Different frequency.

  The random number generation circuit 553A updates the numerical data in the count value permutation RCN in response to, for example, the falling edge of the random number update clock RGK. The random number sequence changing circuit 554A changes the numerical data update order in the count value permutation RCN output from the random number generation circuit 553A based on the setting of the random number update rule by the random number sequence change setting circuit 554B as a random number sequence RDN. Output. The random number sequence RDN is output as the random number sequence RSN after being compared with the maximum random number value by the maximum value comparison circuit 555. Thus, the numerical data in the random number sequence RSN is updated in response to the falling edge of the random number update clock RGK, for example, as shown in FIG.

  The oscillation frequency of the random number clock RCK generated by the random number clock generation circuit 112 and the oscillation frequency of the control clock CCLK generated by the control clock generation circuit 111 are different from each other. Does not become an integral multiple of the other oscillation frequency. Therefore, even when the oscillation frequency of the random number update clock RGN used in the random number circuit 509A is half the oscillation frequency of the random number clock RCK, the oscillation frequency of the control clock CCLK and the oscillation frequency of the control clock CCLK The oscillation frequency of the internal system clock SCLK that is ½ of this is different. In this way, synchronization between the control clock CCLK, the internal system clock SCLK, and the random number update clock RGK is prevented. From the operation timing of the CPU 505, the random number circuit 509A and the random number generation circuit 553A and the random number sequence change circuit 554B It becomes difficult to specify the update timing of the numerical data in the random number sequence RSN generated by the maximum value comparison circuit 555. Similarly, an 8-bit random number sequence is generated for the 8-bit random number circuit 509B. As a result, it is possible to reliably prevent aiming and the like based on the result of analyzing the update operation of numerical data serving as random number values in the random number circuits 509A and 509B from the operation timing of the CPU 505.

  Hard latch selector 558A takes in detection signal SS1 from start switch 7 and outputs random number latch signal LL1 if the fetching method is designated as signal input to input port PI0. For example, the detection signal SS1 from the start switch 7 whose signal state changes between an off state (high level) and an on state (low level) at the timing shown in FIG. 46F is a latch clock RC1 (clock flip-flop). Is taken into the hard latch selector 558A at the falling timings T11, T13, T15,..., And then the timings T11, T13 as shown in FIG. Thus, a random number latch signal LL1 whose signal state changes between an off state and an on state is output. Here, the detection signal SS1 from the start switch 7 changes from the off state to the on state when the operation of the start switch 7 is detected. The random number latch signal LL1 output from the hard latch selector 558A is supplied to the hard latch random number value register 559A and used to acquire numerical data in the random number sequence RSN output from the maximum value comparison circuit 555. In this way, the hard latch selector 558A generates a random number latch signal LL1 for acquiring numerical data serving as a random value based on the detection of the operation of the start switch 7.

  Using the latch clock RC0 generated by the clock flip-flop, a random number latch signal LL1 for acquiring numerical data to be a random value is generated. The hard latch random value register 559A takes in numerical data in the random number sequence RSN output from the maximum value comparison circuit 555 in response to the falling edge of the random number latch signal LL1 input from the hard latch selector 558A to the clock terminal. (Latch) and update the numerical data to be stored data.

  For example, as shown in FIG. 46 (G), when a falling edge is generated at which the random number latch signal LL1 changes from the off state to the on state at timing T11, the output from the maximum value comparison circuit 555 at this timing T11. As shown in FIG. 46 (H), the numerical data in the random number sequence RSN that has been read is taken into the hard latch random value register 559A and acquired as numerical data that becomes a random value. Accordingly, the hard latch random number value register 559A can acquire and store numerical data used as a random number value based on the detected operation of the start switch 7.

  Thus, the hard latch random number value register 559A stores numerical data in the random value RSN in response to the falling edge of the random number latch signal LL1 output from the hard latch selector 558A.

  In the random number hard latch flag register RHF shown in FIG. 23 (A), the corresponding bit values are changed to “0” and “1” in response to the numerical data fetching and reading operations in the hard latch random number register 559A. Change. FIG. 47 is a timing chart for explaining changes in the hard latch flag RLHF0 stored in the random number latch flag register RHF.

  As shown in FIG. 47A, at the timing T20 when the random number latch signal LL1 falls, the numerical data is captured and stored in the hard latch random number value register 559A as shown in FIG. 47B. Then, as shown in FIG. 47C, the corresponding bit value in the hard latch flag RLHF0 changes from “0” to “1”. For example, when numerical data is stored in the hard latch random value register 559A in response to the random number latch signal LL1 being turned on (low level) at timing T20, the bit values of the hard latch flag data RL01HF and RL00HF Change from “0” to “1”, the random number latch flag corresponding to the hard latch random number value register 559A is turned on.

  When the random number latch flag is turned on in this way, storage of new numerical data in the corresponding hard latch random number value register 559A can be restricted. For example, when the bit value [3] of the hard latch selection register RL0LS shown in FIGS. 22A and 22B is “0”, the bit values of the hard latch flag data RL01HF and RL00HF are both “ When the value changes from “0” to “1”, the random number latch flag corresponding to the hard latch random number register 559A is turned on, and storage of new numerical data in the hard latch random number register 559A is restricted. Therefore, even when the random number latch signal LL1 for capturing numerical data corresponding to the input of the detection signal SS1 from the start switch 7 is input to the hard latch random number value register 559A in which the corresponding random number latch flag is on. , New numerical data included in the random number sequence RSN cannot be stored.

  Thus, after the numerical data is temporarily stored in the hard latch random value register 559A, before the numerical data is read from the CPU 505 or the like, for example, the detection signal SS1 from the start switch 7 is erroneously turned on due to noise or the like. Even in such a case, the numerical data already stored is updated, and it is possible to prevent reading of an inaccurate random number value. Further, the numerical data already stored can be obtained by intentionally turning on the detection signal SS1 from the start switch 7 from the outside or by intentionally turning on the random number latch signal LL1 from the outside. It is also possible to prevent fraud such as alteration. On the other hand, when the numerical data once stored in the hard latch random value register 559A is not read from the CPU 505 or the like for a long time, the detection signal SS1 from the start switch 7 is normally turned on thereafter. Thus, accurate numerical data corresponding to the operation of the start switch 7 cannot be stored in the hard latch random number value register 559A.

  Therefore, for example, the CPU 505 of the game control microcomputer 100 executes a predetermined random value register reading process as shown in FIG. 47D when a predetermined random value reading condition is satisfied. Then, the hard latch random number register 559A is read to set the random number latch flag to the off state, thereby setting a state in which new numerical data storage is permitted. The random value read condition may be that the CPU 505 starts execution of game control in the slot machine 1. In the operation example shown in FIG. 47, in response to the completion of the random number value register reading process shown in FIG. 47D at timing T25, the hard latch flag RLHF0 is turned off as shown in FIG. Is set.

  As an example, the CPU 505 executes a predetermined security check process when the system reset of the game control microcomputer 100 is released based on the start of power supply in the slot machine 1, and then executes a user program ( The control code indicating the game control game control program) is read out and the execution of the game control is started. At this time, the CPU 505 may read the numerical data stored in the hard latch random number value register 559A by executing a random number value register read process, and set the corresponding random number latch flag to the OFF state. Note that the CPU 505 may read only the random number value register in which the random number latch flag is in an ON state based on the result of checking the bit values of the hard latch flag data RL00HF to RL01HF. Alternatively, each random number latch flag may be turned off by reading numerical data from the hard latch random value register 559A regardless of whether or not the random number latch flag is on.

  When the slot machine 1 is turned on, various power supply voltages gradually rise to specified values, for example, as shown in FIGS. 6B and 6C, such as the power supply voltage VSL and the power supply voltage VCC. During such an increase in the power supply voltage, some of the various circuits such as the built-in circuit of the game control microcomputer 100 may operate normally, while the other components may not operate normally. As an example, when the power supply voltage is unstable, the detection signal SS1 from the start switch 7 is erroneously turned on, so that numerical data is captured and stored in the hard latch random value register 559A in the random number circuit 509A. The corresponding random number latch flag may be turned on and storage of new numerical data may be restricted. Further, after the execution of game control by the CPU 505 or the like is started, the random number latch signal LL1 is input to the hard latch random number value register 559A at a predetermined timing before the switch input determination process of Sk21 in FIG. 35 is performed. Thus, there is a possibility that a fraudulent act of acquiring numerical data indicating a random number value for internal lottery that allows winning a special combination and shifting to a regular bonus or a big bonus may be performed. As described above, when the storage of new numerical data is restricted when the random number latch flag is turned on, erroneous numerical data due to noise or the like is taken into the hard latch random number value register 559A after the start switch 7 is operated. If numerical data is captured and stored in the hard latch random number value register 559A due to malfunction or fraud due to instability of the power supply voltage before the start winning occurs, Even if the start switch 7 is operated, the numerical data already stored before the operation timing of the start switch 7 is acquired as a random number value and used to determine whether or not a winning for each combination is permitted. there is a possibility.

  Therefore, when the system reset in the gaming control microcomputer 100 is released and the gaming control is started, the random number latch flag may be set to the off state to allow the storage of new numerical data. As a result, for example, the numerical data stored in the hard latch random number register 559A is erroneously acquired as a random value when the power supply voltage is unstable when the power is turned on in the slot machine 1, for example, and various decisions in game control are made. It can be prevented from being used. Further, after the execution of the game control is started, it is possible to prevent an illegal act in which a random number latch signal is input and a regular bonus or a big bonus is transferred before the state of the start switch 7 is checked.

  As another example, an on-state power-off signal is output from the power supply monitoring circuit 303 mounted on the power supply board 101 based on a decrease in a predetermined power supply voltage in the slot machine 1, such as the power supply voltage VSL. When the CPU 505 determines that the power interruption flag is set in the process of Sk3 shown in FIG. 34, the CPU 505 executes the main-side power interruption process in step S52 to cause unstable operation of the slot machine 1 due to a decrease in power supply voltage. Or in preparation for an operation stop. Along with the execution of the main-side power-off process, which is the power supply stop process, the watchdog timer 520 is activated in the process of Sm23 to enable the reset operation due to the occurrence of a timeout, and then the infinite loop process is repeatedly executed. Enter standby mode. Here, after it is determined that the power interruption flag is set by the processing of Sk3, before the time-out of the watchdog timer 520 occurs, the random value register read processing is executed, thereby executing the hard latch random number value register. The numerical data stored in 559A may be read and the corresponding random number latch flag may be turned off. Thus, it may be determined as one of the random value read conditions that it is determined that the power-off signal is in the ON state after the execution of the user program is started.

  FIG. 48 is a timing chart illustrating an operation example in the case where the power supply voltage VSL decreases during the execution of game control. First, based on the start of power supply to the slot machine 1, for example, at a timing T30 before the timing T31 when the power supply voltage VSL shown in FIG. 48A reaches a predetermined value VSL1 (+22 V as an example). Thus, power supply voltage VCC shown in FIG. 48B reaches predetermined value VCC1 (for example, +4.5 V). At this timing T30, the reset signal shown in FIG. 48E changes from the on state to the off state. Subsequently, when the power supply voltage VSL reaches the predetermined value VSL1 at timing T31, the power-off signal shown in FIG. 48C is changed from the on state to the off state. Thereafter, at timing T32, power supply voltage VSL shown in FIG. 48A is assumed to be lower than predetermined value VSL1. At this time, based on the determination that the power interruption flag shown in FIG. 48C is set (Sk3; Y in FIG. 34), the power interruption processing (main) shown in FIG. 36 is executed. Along with this, the watchdog timer 520 is activated by the processing of Sm23. Thus, the reset operation due to occurrence of timeout is validated.

  After the process of Sm23 shown in FIG. 36 is executed, the infinite loop process is repeatedly executed. Therefore, for example, at timing T33, even when the power supply voltage VSL shown in FIG. 48A returns to the predetermined value VSL1, the game control process (game control timer interrupt process, etc.) is not executed, and waits until a timeout occurs. It becomes a state. Thereafter, when a maximum time 225 × TSCLK × 15 that can be set as a time-out time that is a time to be monitored by the watchdog timer 520 has elapsed, the watchdog timer 520 outputs a time-out signal. As a result, a reset operation due to occurrence of a timeout is performed. At this time, the execution of the game control is started from the head of the control code indicating the user program (game control processing program for game control) stored in the ROM 506 based on, for example, the specified contents in the predetermined vector table. A game control process as shown in FIG. 33 is executed from the beginning. Thereby, when the power supply voltage supplied to the slot machine 1 decreases (instantaneous power interruption) in a short period of time, it is possible to appropriately recover from the instantaneous power supply interruption by performing a reset operation due to occurrence of timeout. . Also, until the process of Sm23 shown in FIG. 36 is executed or when the process of Sm23 shown in FIG. 36 is not executed, the watchdog timer 520 is stopped, so that the count value measured by the watchdog timer 520 is changed. There is no need to periodically clear (initialize) and restart, and the control burden for controlling the progress of the game can be reduced.

FIG. 49 is a timing chart showing an operation example when the stability of the power supply voltage cannot be confirmed when the slot machine 1 is powered on. In the operation example shown in FIG. 49, similarly to the operation example shown in FIG. 48, the power supply voltage VCC shown in FIG. 49B reaches the predetermined value VCC1 at the timing T30. Accordingly, the reset signal illustrated in FIG. 49E is changed from the on state to the off state. On the other hand, in the operation example shown in FIG. 49, since the power supply voltage VSL does not reach the predetermined value VSL1 at the timing T31, it is determined that the power-off signal shown in FIG. 49C is in the on state (low level). (Sa 3 5 in FIG. 30; Y). In accordance with this determination result, the watchdog timer 520 is activated by the processing of Sa 3 6. Thus, the reset operation due to occurrence of timeout is validated.

Processing of Sa 3 6 shown in FIG. 30 after being performed, an infinite loop is repeated. Therefore, for example, at time T35, even when the power supply voltage VSL shown in FIG. 49A reaches the predetermined value VSL1, the game control process (game control timer interrupt process, etc.) is not executed, and it waits until a timeout occurs. It becomes a state. Thereafter, when a maximum time 225 × TSCLK × 15 that can be set as a time-out time that is a time to be monitored by the watchdog timer 520 has elapsed, the watchdog timer 520 outputs a time-out signal. As a result, a reset operation due to occurrence of a timeout is performed. At this time, the execution of the game control is started from the head of the control code indicating the user program (game control processing program for game control) stored in the ROM 506 based on, for example, the specified contents in the predetermined vector table. A game control process as shown in FIG. 33 is executed from the beginning. As a result, when the power supply voltage supplied when the power of the slot machine 1 is turned on decreases (instantaneous power interruption) in a short period of time, by performing a reset operation due to the occurrence of a timeout, It can be restored properly. Moreover, and to the process of Sa 3 6 shown in FIG. 30 is executed, when the processing of Sa 3 6 is not performed, since stopping the watchdog timer 520, the count value measured by the watchdog timer 520 There is no need to periodically clear (initialize) and restart, and the control burden for controlling the progress of the game can be reduced.

The processes of steps Sa 3 5 and Sa 3 6 shown in FIG. 30 are executed before access to the RAM 507 is permitted by the process of Sa4. As a result, when the power supply voltage supplied at the time of power-on of the slot machine 1 is unstable such as a drop (instantaneous power failure) in a short time, the stored contents in the backup storage area provided in the RAM 507 are incorrect. While preventing the change (damage), the reset operation due to the occurrence of the timeout can be validated to appropriately recover from the instantaneous power supply interruption.

  Bit number [5-4] of reset setting KRES shown in FIG. 10B is set so that the time-out time as the monitoring time in watchdog timer 520 is the longest time that can be set among a plurality of predetermined types. And a bit value in bit number [3-0] is set in advance. Thus, the time-out time in the watchdog timer 520 is set to be longer than, for example, the time when the power supply voltage VSL is lower than the voltage value capable of generating the power supply voltage VCC after the power cut-off signal is turned on due to the stop of power supply. Just do it. Since the watchdog timer 520 operates using the power supply voltage VCC as a drive voltage, the time-out time is set to be longer than the operable time of the watchdog timer 520 when power supply is stopped due to power supply switch disconnection or the like. Therefore, when the power supply is stopped due to the power switch of the slot machine 1 being cut off, etc., if the power supply voltage is lowered and the supply is stopped as it is, the watch is stopped before the reset operation is performed before a timeout occurs. The dog timer 520 and other circuit components will not operate. Therefore, when the power supply is properly stopped by cutting off the power switch or the like, the reset operation can be prevented from being erroneously performed, and the power supply can be appropriately recovered from the instantaneous power supply interruption.

  In the game control board 40, the CPU 505 stores a security check program stored in the ROM 506 or the like when initial power is supplied from the power board 101 (when power is turned on without a backup power supply) or when restarting after a system reset occurs. By reading and executing 506A, the game control microcomputer 100 enters the security mode. At this time, as a process corresponding to the security check program 506A, for example, a security check process as shown in FIG. 29 is executed. Here, the security time during which the game control microcomputer 100 is in the security mode is different from a certain fixed time according to the setting data stored in advance in the security time setting KSES stored in the program management area of the ROM 506. A time component can be included.

  For example, according to the bit value [5-0] of the security time setting KSES, any of a plurality of fixed extension times that can be selected in advance in addition to the fixed time by setting as shown in FIG. 10B. Can be set as a time component included in the security time (step S2 in FIG. 29). If the bit value [7-6] of the security time setting KSES is a value other than “00” (step S4; No), the short mode, the middle mode, and the long mode as shown in FIG. Corresponding to one of the modes, a variable extension time that changes in a predetermined time range every time the initial setting process is executed based on system reset or power-on can be set as a time component included in the security time. (Step S5).

  Until the security time thus set elapses (step S11; No), the execution of the game control main process by the user program stored in the ROM 506 is not started. Then, the operation of generating numerical data to be a random number value by the random number circuits 509A and 509B may be prevented from being started during the period in which the game control microcomputer 100 is in the security mode. This makes it difficult to specify the operation start timing of the random number circuits 509A and 509B and the numerical data to be updated from the operation start timing due to power-on of the slot machine 1, system reset, etc., and analysis of the game control processing program By aiming based on the result or inputting a fraud signal at a predetermined timing by connecting a so-called “hanging board”, it is possible to reliably prevent an act such as illegally generating a big hit gaming state.

  As an example, the bit value in the bit number [5-0] of the security time setting KSES is set to a different value for each model of the slot machine 1. In this case, the fixed extension time set in step S2 shown in FIG. 25 can be made different for each model of the slot machine 1, and the operation of the random number circuits 509A and 509B is started from the operation start timing of the slot machine 1. It becomes difficult to specify the timing. Further, by setting the bit value in the bit number [7-6] of the security time setting KSES to “01”, “10”, or “11”, the variable extension time set in step S5 is Different for each system reset. This makes it extremely difficult to specify the operation start timing of the random number circuits 509A and 509B from the operation start timing of the slot machine 1.

  For example, based on the input of a predetermined signal such that the detection signal SS1 from the start switch 7 is turned on, the random number circuit 509A updates the random number in a predetermined procedure by the random number generation circuit 553A, the random number sequence change circuit 554A, or the like. When numerical data included in the column RSN is stored in the hard latch random number register 559A, the bit values of the hard latch flag data RL00HF to RL02HF stored in the random number hard latch flag register RHF are changed from “0” to “1”. And change. When the bit value [3] of the corresponding hard latch selection register RL0LS is “0”, the random number latch flag corresponding to the hard latch random number value register 559A that stores numerical data is turned on. This limits the storage of new numerical data. On the other hand, when numerical data that becomes a random value is read from the hard latch random number value register 559A at the read timing of the random value, for example, when the CPU 505 executes the processing of Sk21 shown in FIG. The random number latch flag corresponding to the hard latch random number value register 559A from which the data has been read is turned off, and storage of new numerical data is permitted. Thereby, the numerical data stored in the hard latch random number value register 559A based on the input of the predetermined signal is not altered by noise or the like before being read by the CPU 505 or the like, and the numerical data becomes an accurate random number value. Can be obtained.

  When the execution of game control is started by the CPU 505 of the game control microcomputer 100 or the like, each random number latch flag can be set to an OFF state by reading numerical data from the hard latch random number register 559A. As a result, when power supply is resumed after the power supply in the slot machine 1 or the like is stopped or the power supply voltage is unstable such as when the power is turned on, it is erroneously stored in the hard latch random number value register 559A. It is possible to prevent the obtained numerical data from being acquired as a random value.

  When the bit value [7-6] of the security time setting KSES shown in FIG. 9A or FIG. 12 is set to a value other than “00”, an initial setting process is executed based on a system reset or power-on. A variable extension time that changes in a predetermined time range every time is set as a time component included in the security time. Further, according to the bit value in the bit number [5-0] of the security time setting KSES shown in FIG. 9A or FIG. Set as a time component included in the security time. This makes it difficult to specify the operation start timing of the random number circuits 509A and 509B and the numerical data to be updated from the operation start timing due to power-on of the slot machine 1, system reset, etc., and analysis of the game control processing program By aiming based on the result or inputting a fraud signal at a predetermined timing by connecting a so-called “hanging board”, it is possible to reliably prevent an act such as illegally generating a big hit gaming state.

  For example, in the 16-bit random number circuit 509A, the random number sequence change circuit 554A changes the count value permutation RCN output from the random number generation circuit 553A based on a predetermined random number change rule, whereby numerical data is determined in a predetermined procedure. Are updated cyclically from the initial update value to a predetermined final update value. When the bit value in the bit number [6] of the 16-bit random number initialization third KRL3 shown in FIG. 9A or FIG. 11C is “1”, the random number value generated by the random number circuit 509A The start value of the numerical data is changed at every system reset. For the 8-bit random number circuit 509B, the start value of the random number value may be changed in the same manner. As a result, even if the operation start timing of the random number circuits 509A and 509B can be specified, it becomes difficult to specify numerical data read from the hard latch random number value register included in the random number circuits 509A and 509B. Aiming based on the analysis result of the control processing program or the input of an illegal signal due to the connection of a so-called “hanging board” can be surely prevented.

  More specifically, the count value serving as the initial value determination data is updated by the free-run counter 509C or the like separately from the operation of the CPU 505 of the game control microcomputer 100. Based on the setting by the start value setting circuit 553C of the random number circuits 509A and 509B, the start value of the numerical data that becomes the random value is determined using the count value of the free-run counter 509C. This makes it difficult to specify numerical data that is a random value from the operation mode of the CPU 505 of the game control microcomputer 100, and is based on aiming based on the analysis result of the game control processing program or connection of a so-called “hanging board”. It is possible to reliably prevent an illegal signal from being input.

  In the external bus interface 501 provided in the game control microcomputer 100, the internal resource access control circuit 501A allows external data other than the internal circuit such as the CPU 505 to externally read the internal data of the game control microcomputer 100 such as data stored in the ROM 506. Limited. Thereby, it is possible to prevent a game control processing program such as a game control user program stored in the ROM 506 from being read from the outside of the game control microcomputer 100 and provided for analysis or the like. Further, it is possible to reliably prevent aiming based on the analysis result of the game control processing program and input of an illegal signal due to connection of a so-called “hanging board”.

  The random number circuits 509A and 509B built in or externally attached to the game control microcomputer 100 are provided with frequency monitoring circuits, and the input state of the random number clock RCK supplied from the random number clock generation circuit 112 is compared with the internal system clock SCLK. Thus, when a frequency abnormality in the random number clock RCK is detected, the bit value at a predetermined bit number in the internal information register CIF may be set to “1”. Then, the CPU 505 determines that the number of times that the bit value at the predetermined bit number in the internal information register CIF is continuously “1” in the game control main process has reached a predetermined clock abnormality determination value, for example. May be determined that an abnormality has occurred in the operating state of the random number circuits 509A and 509B. Thereby, it is possible to reliably prevent an illegal act by inputting an illegal signal as the random number clock RCK.

  The CPU 505 of the game control microcomputer 100 executes a predetermined random value register read process when the system reset of the game control microcomputer 100 is released based on the start of power supply in the slot machine 1 or the like. Alternatively, the numerical data stored in the hard latch random value register 559A may be read to turn off the corresponding random number latch flag. Thus, it is possible to prevent the numerical data stored in the hard latch random value register 559A from being erroneously acquired as a random value when the power supply voltage is unstable, for example, when the power is turned on.

Further, in response to the determination that the power interruption flag is set in Sk3 shown in FIG. 34, for example, after a decrease in a predetermined power supply voltage such as the power supply voltage VSL is detected, the game control microcomputer 100 is detected. Until the operation is stopped, the input state of the power-off signal may be repeatedly determined by executing the processes of Sa 3 5 and Sa 3 5B shown in FIG. Then, when it is determined in Sa 3 5 that the power-off signal is in an off state and is not input, a predetermined disturbance is applied before the game control is started from the head of the control code stored in the ROM 506. The numerical value register read process may be executed to turn off the random number latch flag that is on. As a result, it is possible to prevent the numerical data stored in the hard latch random number value register 559A from being erroneously acquired as a random value when the power supply voltage is unstable, such as when the predetermined power supply voltage VSL is lowered. .

  Next, the data conversion executed in Sm2, Sm7, Sm12, and Sm17 of the power interruption process (main) in FIG. 36 will be specifically described with reference to FIGS.

  FIG. 50 is an explanatory diagram showing the contents of data in the backup RAM when data is transferred between the work RAM and the backup RAM with (A) the same bus width (B) and different bus widths. In the present embodiment, data is expanded in the work RAM for processing, and the data expanded in the work RAM is stored in the backup RAM as backup data. “(H)” indicates a hexadecimal number.

  The work RAM stores 16 pieces of 8-bit (1 byte) data at each address. For example, data “00”, “01”, and “0F” are stored in addresses “0000h” to “000Fh”, respectively, and data “10” and “001Fh” are stored in addresses “0010h” to “001Fh”. 11 "..." 1F "is stored.

  As shown in Fig. 50 (A), a 8-bit bus accessible microprocessor is used for external devices such as external memory, and the external RAM backup RAM can be accessed with a bus width of 8 bits (1 byte). In this case, that is, when the accessible bus widths coincide with each other, when the backup data is transferred from the work RAM to the backup RAM, the 8-bit backup data is stored as it is. Does not happen. Specifically, for example, when the data stored in the work RAM at the address “0000h” is read in 8-bit units and the 8-bit backup data “00” is transferred to the backup RAM, the transferred backup data “00” is transferred. Is stored in “0000h” of the backup RAM. Similarly, when the 8-bit backup data “01” stored at the address “0001h” in the work RAM is transferred to the backup RAM, the transferred backup data “01” is stored in the backup RAM. Similarly, backup data stored at other addresses is also stored at corresponding addresses.

  On the other hand, as shown in FIG. 50B, as shown in this embodiment, an external memory using a microprocessor capable of only 32-bit or 16-bit bus access to an external device such as an external memory is used. When the backup RAM can be accessed with a bus width of 8 bits (1 byte), that is, when the accessible bus widths do not match, data is read from the work RAM in units of 16 bits, and the backup RAM When the data is transferred to the data, the upper 8 bits of data transferred from the work RAM are lost, and the entire 16 bits cannot be transferred. Specifically, for example, when 16-bit backup data “0001” stored at addresses “0000h” and “0001h” in the work RAM is transferred to the backup RAM, the upper 8-bit data “01” is lost. Only the lower 8 bits of data “00” are stored in “0000h” of the backup RAM. Similarly, when the 16-bit backup data “0203” stored in the addresses “0002h” and “0003h” in the work RAM is transferred to the backup RAM, the upper 8-bit data “03” is lost and the lower 8-bit data is lost. Only data “02” is stored in “0002h” of the backup RAM. That is, the upper 8 bits of the 16-bit backup data are lost, and the backup data is stored only at even addresses in the backup RAM.

  Therefore, in order to prevent data loss even when the bus widths of the data buses of the work RAM and the backup RAM do not match, in the present invention, the power interruption processing (main) Sm2, Sm7, Data conversion is performed in Sm12 and Sm17.

  First, the case where the bus width to be accessed on the microprocessor side does not match the bus width accessible on the backup RAM side and data in the upper 1 byte is lost will be described with reference to FIG. For example, when storing data from the work RAM to the backup RAM in Sm3, Sm8, Sm13, and Sm18 of the power interruption process (main) in FIG. 36, “1234” that is 16-bit backup data is transferred to the backup RAM. To do. In this case, as described with reference to FIG. 50, the upper 8-bit data “34” is missing and stored. Therefore, when performing the restoration process in Sa24 of FIG. 32, when the backup data is read from the backup RAM, the upper 8-bit data “34” is lost, and only the lower 1-byte data “12” is stored in the work RAM. The However, this cannot return to the state before the power interruption.

  Therefore, as shown in FIG. 51B, in this embodiment, when data is transferred from the work RAM to the backup RAM, the data conversion is performed in Sm2, Sm7, Sm12, and Sm17 of the power interruption processing (main) in FIG. It is carried out.

  Specifically, for example, “1234 (H)” that is 16-bit data is converted into two data. For the first data, the data “1234 (H)” read from the work RAM is masked with the mask value “00FF (H)” as it is, and converted to “0034 (H)”. For the second data, the data read from the work RAM is shifted by 8 bits, masked with the mask value “00FF (H)”, and converted to “0012 (H)”. As a result, when 16-bit backup data “1234 (H)” is read from the work RAM and data conversion is performed, it is composed of two 16-bit data consisting of “0012 (H)” and “0034 (H)”. A total of 32 bits (4 bytes) of backup data is created. When each of the two 16-bit backup data is sequentially written in the backup RAM, as described above, the upper 8 bits of data “00” are lost, so the lower 8 of the one backup data “0012”. Bit data “12” is stored in the backup RAM. Similarly, “34”, which is lower byte data of the other backup data “0034”, is stored in the backup RAM. As a result, even when 16-bit backup data “1234” is transferred using a data bus having an 8-bit bus width, the data can be stored in the backup RAM without being lost.

  In addition, when performing the return process in Sa24 of FIG. 32, the reverse data conversion process is performed. Specifically, since only 8-bit data can be read from the backup RAM, the data “12 (H)” and the data “34 (H)” are sequentially read out and combined to form the data “1234 ( H) "is restored, and the restored data is stored in the work RAM.

  Next, referring to FIG. 52, the data in the backup RAM when the data conversion is performed in Sm2, Sm7, Sm12, Sm17 in the power interruption processing (main) in FIG. 36 and the data is stored from the work RAM to the backup RAM. The storage state of will be described.

  As described above, for example, the 16-bit backup data “0001” stored in the addresses “0000h” and “0001h” in the work RAM is converted, and “0000” which is a total of 32-bit backup data. And “0001” are created. When this is transferred to the backup RAM, the upper 8-bit data “00” added at the time of conversion is lost, and only the lower 8-bit data “00” and “01” are stored in the backup RAM. If the upper 8 bits of data (data “00” added at the time of data conversion) is lost, no data is stored in the odd addresses “+ 0001h” and “+ 0003h”, so the lower 8 bits of the transferred 16-bit data “0000” The bit data “00” is stored in the even address “+ 0000h”, and the data “01” of the lower 8 bits of the 16-bit data “0001” transferred subsequently is stored in the even address “+ 0002h”. As described above, when data conversion is performed on other data and the data is transferred, the data is similarly stored at even addresses in the backup RAM.

  In the present embodiment, the game control microcomputer 100 is connected to an SRAM 50 as an external memory, and this SRAM 50 is used as a backup RAM. In this way, when the external memory is used as a backup RAM instead of the built-in memory of the game control microcomputer 100, the CPU accesses the RAM when the supply voltage is unstable, such as during a power failure. Even if it is prohibited, a chip select signal for designating the RAM or a WR signal indicating the timing of writing to the RAM may be output. If these signals coincide, the external memory There was a problem that data was rewritten.

  On the other hand, in this embodiment, the voltage at which the CPU 505 of the game control microcomputer 100 stops when the power is cut off (the voltage at which a reset signal is output to the CPU 505) is input / output of signals from the game control microcomputer 100. The I / O port 41d to be controlled is set lower than the voltage at which the I / O port 41d stops (the voltage at which the reset signal for the I / O port is output), and the I / O is set before the CPU 505 of the game control microcomputer 100. As a hardware configuration in which the operation of the port 41d is stopped first, the I / O port 41d is not operated after the operation of the CPU 505 is stopped, so that the chip select signal designating the SRAM and the timing of writing to the SRAM can be set. Prevents the occurrence of the phenomenon that the WR signal is output, It is adapted to prevent re of data has rewritten.

  In addition to the SRAM 50, the driving voltage of the CPU 505 is also used for other devices mounted on the same substrate (LED driving circuit, liquid crystal driving circuit, etc.). In some cases, the speed at which the voltage drops when power is interrupted may not be stable. As described above, the hardware configuration is adopted in which the I / O port 41d stops operating before the CPU 505 of the game control microcomputer 100. Even so, it has been confirmed that the operation of the CPU 505 is stopped before the I / O port 41d stops the operation. There is a possibility that the WR signal indicating the output will be output, and the data in the external memory may be rewritten.

  Therefore, in this embodiment, after the backup data is stored in the backup RAM in the event of a power failure, the general-purpose port setting corresponding to the general-purpose terminal connected to the CS signal line connected to the backup RAM is set to the input port. Therefore, the chip select signal output function for the backup RAM is forcibly disabled, and the writing of data to the backup RAM is also disabled for software, and the voltage is unstable as during a power failure. Thus, it is possible to more reliably prevent the data in the backup RAM from being rewritten.

  In the present embodiment, the configuration in which the backup RAM is mounted on the same board as the game control microcomputer 100 is described. However, the backup RAM is executed on a board separate from the game control microcomputer 100. Even in such a configuration, by forcibly disabling the output function of the chip select signal to the backup RAM as described above, the data in the backup RAM can be stored in an unstable voltage state such as during a power failure. It can be surely prevented from being rewritten.

  Further, in this embodiment, after the game control microcomputer 100 is started, after the setting of the built-in device and other built-in registers, it is connected to the SRAM 50 at a stage before determining whether the backup data is normal. By setting the general-purpose port corresponding to the general-purpose terminal to which the CS signal line is connected to the output port, the output of the chip select signal of the SRAM 50 is validated and stored in the SRAM 50. The function of outputting the chip select signal to the SRAM 50 is disabled until it is determined whether or not the recovery is possible based on the backup data that is present, so the data in the SRAM 50 is unstable in an unstable state after the power supply is started. Can be prevented from being rewritten.

The present invention is not limited to the above embodiment, and various modifications and applications are possible. For example, the slot machine 1 may not have all the technical features shown in the above embodiment, and some of the parts described in the above embodiment may be solved so that at least one problem in the prior art can be solved. It may have a configuration. As a specific example, in the above embodiment, while enabling the reset operation by starting the watchdog timer 520 due to the occurrence of time-out by treatment Sa 3 6 shown in FIG. 30, by the processing of Sm23 shown in FIG. 36 It has been described that the watchdog timer 520 is activated to enable the reset operation due to the occurrence of a timeout. In contrast, among the processing in the processing and Sm23 of Sa 3 6, but enable the reset operation due to the occurrence of any start the watchdog timer 520 times out by one of the processes, which the other processing not performed It may be.

  When a reset operation is performed due to the occurrence of a timeout in the watchdog timer 520, numerical data is read from the hard latch random number value register 559A and a process for setting each random number latch flag to an off state is executed. Good. This prevents, for example, the numerical data stored in the hard latch random value register 559A from being erroneously acquired as a random value when the power supply is momentarily interrupted in the slot machine 1 and the power supply voltage is unstable. it can.

  The fixed extension time set in step S2 of FIG. 29 may be determined as one of a plurality of fixed extension times for each system reset, for example, by setting in a user program stored in the ROM 506. In this case, the fixed extension time set in step S2 is defined to be longer than the longest variable extension time that can be set in step S5. Then, after a rough extension time is determined in step S2, a detailed extension time may be determined in step S5. As a result, the security time in the security mode when the power of the slot machine 1 is turned on or when the system is reset can be greatly changed every time the system is reset. It becomes more difficult to specify the start timing and the numerical data to be updated.

  The fixed extension time added to the fixed time may be determined using an ID number assigned to each chip constituting the game control microcomputer 100. As an example, an extension time corresponding to the calculated value is executed by executing a part or all of an operation for performing a predetermined scramble process on the ID number and an operation such as addition / subtraction / multiplication / division using the ID number. May be set. In this case, the extension time may be randomly determined for each system reset, for example, by changing an arithmetic expression used for determining the extension time for each system reset. Furthermore, the count value of the free run counter, the ID number, and the like, for example, the arithmetic expression for determining the extension time using the ID number is determined corresponding to the count value of the free run counter stored at the time of system reset. The extended time may be determined randomly at each system reset by using a combination of the above. In addition, when changing the start value of the random number generated by the random number circuits 509A and 509B at each system reset, the random number start can be started by using a combination of the count value of the free-run counter and the ID number. The value may be determined.

  The clock signal supplied to the CPU 505 of the gaming control microcomputer 100 and the clock signal supplied to the random number circuits 509A and 509B are generated using an oscillation signal generated by one oscillator included in the common clock generation circuit. It may be generated. In this case, for example, a frequency divider for generating the random number clock RCK and the control clock CCLK is provided so that the latch clock and the control clock CCLK or the internal system clock SCLK are less likely to be synchronized. What is necessary is just to set the frequency division ratio in each frequency divider. A part or all of the control clock generation circuit 111 and the random number clock generation circuit 112 may be provided inside the game control microcomputer 100 or provided outside the game control microcomputer 100. May be.

  The oscillation signal that becomes the random number update clock RGK or the latching clock may be generated outside the random number circuits 509A and 509B such as the random number clock generation circuit 112, for example. Alternatively, a circuit for generating the random number update clock RGK and a circuit for generating the latch clock RC0 may be separately provided in the random number circuits 509A and 509B. As an example, a random number update clock RGK is generated by a flip-flop similar to the clock flip-flop, while an inversion circuit for inverting the signal state of the random number update clock RGK is provided, and a signal output from the inversion circuit is used for latching It may be used as a clock.

  When restricting external reading of the ROM 506 or the like, for example, the connection terminal for externally reading out the data stored in the ROM 506 in the game control microcomputer 100 is sealed so that the external device cannot be connected to the provider of the slot machine 1. It may be stopped.

  In the above embodiment, the slot machine that sets the bet number using medals and credits is described as an example of the slot machine. However, the present invention is not limited to this. For example, a game ball is used as a game medium. Applying the configuration shown in the above embodiment to a pachinko machine to be used, a slot machine that sets a bet number using a game ball, and a complete credit type slot machine that sets a bet number using only credits, The invention according to claim 1 can be realized. When a game ball is used as a game medium in the slot machine, for example, when one medal is made to correspond to five game balls, and 3 is set as the bet number in the above embodiment, 15 This is equivalent to setting the number of bets using one game ball.

  The slot machine of the present invention is not limited to one that uses only one of a plurality of types of game media such as medals and game balls, but a plurality of types of games such as medals and game balls. The medium may be used in combination. That is, it is possible to play a game by setting the number of bets using any one of a plurality of types of game media such as medals and game balls, and a plurality of types of game media such as medals and game balls when a winning occurs. Any of the slot machines that can pay out any of these is also included in the slot machine of the present invention.

  In the above embodiment, the game control program is composed of four program modules: an internal lottery control module, an input / output control module, a reel rotation control module, and a payout control module. However, the present invention is not limited to this embodiment. A slot machine having a game control program in a module structure with at least one program module of the above, or a slot machine having a game control program in a module structure with a program module other than at least one of the four program modules and the above four program modules The configuration shown in the above embodiment may be applied.

  In the above embodiment, in the power interruption process (main), the backup process is performed in the order of the internal lottery control module, the input / output control module, the reel rotation control module, and the payout control module. However, the backup process is not limited to this example. The configuration shown in the above embodiment may be applied to a slot machine whose processing order is different from that in the above embodiment.

  In this embodiment, for each program module, check data for determining whether the backup data is normal is created using data used in the program module (Sm4, Sm9, Sm14 and Sm19).

  Therefore, even if the program structure is composed of a plurality of program modules and the backup process is performed by a common method regardless of the model, the program development man-hours can be reduced.

  Further, in this embodiment, for each program module, it is determined whether backup data based on data used in the program module is normal, and it is determined that all backup data is normal. Based on this, a return process is performed (portions Sa8, Sa12, Sa17, Sa21 in FIG. 30). Therefore, even if the start address is specified so that the start address of the data creation area of the backup data differs for each program module, the return process can be performed reliably.

  In the above embodiment, in the start-up process (main), the state before the power interruption is restored on condition that all the checksums of the respective program modules match. However, the checksum is not limited to this embodiment. If there is a program module that matches and a program module that does not match the checksum, only the function related to the program module with the matching checksum is restored to the state before the power interruption, or all functions before the power interruption. The configuration shown in the above embodiment may be applied to the slot machine that returns to the above state.

  In this embodiment, regardless of which program module uses backup data based on data, a common data conversion process is performed and the backup data is stored in the backup RAM (Sm2, Sm7,. In the portions of Sm12 and Sm17, the portion for performing data conversion shown in FIG. Therefore, the number of program development steps can be reduced.

  In the above embodiment, data conversion for adding 8-bit data is performed. However, the present invention is not limited to this embodiment, and the configuration shown in the above embodiment is applied to a slot machine that performs data conversion processing by another method. It may be applied.

  The slot machine 1 is not limited to a game that can be played using medals and credits. For example, a slot machine that plays games using pachinko balls, or a game that uses credits without medals being discharged to the outside. The present invention can also be applied to a possible full credit type slot machine, an image type slot machine in which a variable display device displays an image showing a symbol.

  The programs and data for realizing part or all of the configuration and functions of the slot machine 1 are not limited to a form distributed and provided to a computer device or the like by a detachable recording medium. A distribution form may be adopted by preinstalling in a storage device such as a computer device in advance. Furthermore, some or all of the programs and data for realizing the present invention can be downloaded from other devices on a network connected via a communication line or the like by providing a communication processing unit. You may take the form to distribute.

As described above, in the slot machine such as the slot machine 1 in the above embodiment, the bit value in the bit number [6] of the reset setting KRES stored in the program management area of the ROM 506 is set to “1”. The watchdog timer 520 can be switched between start and stop by a user program (software). When the CPU 505 of the game control microcomputer 100 determines that the power interruption flag is set in the processing of Sk3 shown in FIG. 34, the CPU 505 executes the power interruption processing (main) shown in FIG. Is shifted to a standby state in which repetitive execution is performed, and the watchdog timer 520 is activated in the process of Sm23 accompanying the execution of the power interruption process (main) to enable the reset operation due to the occurrence of a timeout. As described above, when the progress of the game in the slot machine 1 is controlled by starting the watchdog timer 520 after it is determined that the power-off signal is in the ON state, the monitoring time of the watchdog timer 520 is periodically measured. There is no need to clear (initialize) and restart. Thus, while reducing the control load for controlling the progress of the game, it is possible to properly recover from stop instantaneous power supply in the slot machine such as a slot machine 1.

Further, CPU 505 of the game control microcomputer 100, when the power supply in the slot machine 1 is started, before the access to the RAM507 by treatment Sa4 shown in FIG. 30 is permitted, the process of Sa 3 5 To determine whether the power-off signal is in the on state. If the power failure signal at this time is determined to be ON state, in the process of Sa 3 6 due to be transferred to the standby state to run repeatedly endless loop activates the watchdog timer 520 times out Enables reset operation due to occurrence of. As described above, when the progress of the game in the slot machine 1 is controlled by starting the watchdog timer 520 after it is determined that the power-off signal is in the on state at the start of power supply or when the reset operation is performed. There is no need to periodically clear (initialize) the measurement of the monitoring time in the dog timer 520 and restart it. Thereby, it is possible to appropriately recover from an instantaneous power supply interruption in a slot machine such as the slot machine 1 while reducing the control burden for controlling the progress of the game.

  For example, in the reset setting KRES shown in FIG. 10B, the monitoring time measured by the watchdog timer 520 is set in advance by setting the bit values in the bit numbers [5-4] and [3-0]. It can be set from a plurality of types. By setting such that the bit value in the bit number [5-4] of the reset setting KRES is “11” and the bit value in the bit number [3-0] is “1111”, the timeout time as the monitoring time is set. Set the maximum time that can be set. As a result, for example, when power supply is completely stopped for a predetermined period due to, for example, the power switch being turned off in the slot machine 1, the reset operation due to the occurrence of a timeout is restricted so that the reset operation is erroneously performed. It is possible to appropriately recover from an instantaneous power supply interruption in a slot machine such as the slot machine 1.

In the process of Sm23 shown in processing and Figure 36 Sa 3 6 shown in FIG. 30, by the processing shown in FIG. 37 (B) is executed, but reset source immediately before a timeout of the watchdog timer 520 When it is determined that there is, the watchdog timer 520 may be stopped to invalidate the reset operation due to the occurrence of a timeout. As a result, the power supply voltage in the slot machine 1 or the like cannot be confirmed to be stable, so that an inadvertent reset operation is prevented from being repeatedly performed, and the power supply in the slot machine is appropriately recovered from the instantaneous power interruption. be able to.

  The CPU 505 of the game control microcomputer 100 sequentially measures WDT clear data having different values “55H” and “AAH” in the WDT clear register WCL, thereby measuring the time-out time that is the monitoring time of the watchdog timer 520. Clear (initialize) and restart (restart). As a result, when the power supply instantaneously stops in the slot machine such as the slot machine 1, the measurement of the monitoring time is prevented from being erroneously initialized due to noise or the like. It can be restored properly.

DESCRIPTION OF SYMBOLS 1 Slot machine 2L, 2C, 2R Reel 6 MAXBET switch 7 Start switch 8L, 8C, 8R Stop switch 100 ... Game control microcomputer 301 ... Transformer circuit 302 ... DC voltage generation circuit 303 ... Power supply monitoring circuit 304 ... Clear switch 501 ... External bus interface 501A ... Internal resource access restriction circuit 502 ... Clock circuit 503 ... Specific information storage circuit 504A ... Reset controller 504B ... Interrupt controller 505 ... CPU
506 ... ROM
506A: Security check program 507: RAM
508 ... Timer circuits 509A, 509B ... Random number circuit 510 ... PIP
511 ... Serial communication circuit 512 ... Address decoding circuit 520 ... Watchdog timer 533 ... WDT control circuit 535 ... Count clock generation circuit 536 ... 16-bit up counter 537 ... Output control circuit 551 ... Random number update clock selection circuit 553A ... Random number generation circuit 553B ... Random number activation setting circuit 553C ... Start value setting circuit 554A ... Random number sequence change circuit 554B ... Random number sequence change setting circuit 555 ... Maximum value comparison circuit 558A ... Hard latch selector 559A ... Hard latch random number value register 559S ... Soft latch random number value register

Claims (1)

A variable display unit capable of variably displaying a plurality of types of identification information each capable of being identified,
After displaying the variable display unit in a variable manner, the display result is derived by stopping the variable display of the variable display unit, and in a slot machine capable of generating a prize according to the display result,
Follow the control program, after performing the initial setting process, and a control means for performing control of the slot machine,
Monitors the state of being that power used in the slot machine, a power supply monitoring means detecting conditions relating to the supply stop of electric power to the slot machine to output a detection signal based on the satisfied,
Having a time measuring means for measuring a predetermined monitoring time, and comprising a reset means for resetting the control means when it is measured by the time measuring means that the monitoring time has elapsed ,
The reset means includes
The operation is activated by writing activation data indicating that the operation of the reset unit is activated in the operation setting storage area by the control unit,
When the operation is enabled, the control means initializes the time measuring means by writing initialization data indicating that the time measuring means is initialized in the initialization storage area,
The control means, seen including a power interruption time control means Ru is shifted to the standby state in which no execution control of the slot machine after performing the power supply stop process in response to the detection signal from the power supply monitoring means,
The power interruption control means writes the validation data in the operation setting storage area of the reset means when shifting to the standby state, and after shifting to the standby state, the timing means is initialized. A slot machine in which the initialization data is not written in the initialization storage area of the reset means so as not to be executed .

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