JP2006122715A - Game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a game machine capable of preventing a fraudulent act concerning the throwing-in of tokens. <P>SOLUTION: The game machine is equipped with a detection means which is arranged in a route through which tokens to be thrown pass and detects the passage of the tokens. The game machine is also equipped with a determination means to determine whether or not the number of tokens passed through the route within a prescribed time is over a preset reference number of tokens based on a result detected by the detection means, and a processing means to perform error processing in the case of determining that it exceeds the preset reference number by the determination means. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a gaming machine typified by a slot machine, and more particularly to a technique for preventing fraudulent acts related to medal insertion.

  In a gaming machine where a medal is inserted and a game is paid out according to the game result as in a slot machine, a medal selector for selecting a regular medal is provided (see, for example, Patent Document 1). . This medal selector forms a medal passage that leads from the medal insertion slot, and when a fake medal different in size from a regular medal is inserted, it is dropped from the passage and discharged to the medal tray. ing. A sensor for detecting the passage of medals is provided in the medal passage to count the number of medals inserted. As this sensor, an optical sensor is usually employed, and two sensors are provided along the passage. FIG. 20A is a timing chart showing how to detect the passage of medals by two sensors. Since the sensors 1 and 2 are displaced along the passage, when the medal passes through the passage, the sensor 1 is first turned ON. Subsequently, the sensor 2 is turned on. Next, the sensor 1 is turned off and the sensor 2 is turned off. Then, when the ON / OFF of the sensor 1 and the sensor 2 is performed in the sequence shown in the figure, the control unit of the gaming table determines that the medal has passed normally and counts it as one effective medal insertion number. Will do.

Japanese Patent Laid-Open No. 2001-17611

  On the other hand, paying attention to the medal detection principle, fraudulent acts using special instruments are performed. FIG. 21 is a block diagram of an instrument used for fraud. The base includes a base material 1 made of plastic or the like curved along the shape of the medal passage of the medal selector, a switch 2 provided at one end of the base material 1, a control circuit 3, and a medal selector 2 Two light emitting elements 4 provided in accordance with the arrangement of one sensor, and a signal line 5 connecting the electric circuit 3 and the light emitting element 4 are provided. The control circuit 3 causes the light emitting element 4 to blink at a predetermined period when the switch 2 is pressed.

  Therefore, this instrument is inserted into the medal selector from the medal insertion slot with the light emitting element 4 side as the head until the light emitting element 4 just reaches the two sensors of the medal selector. Then, pressing the switch 2 causes the light emitting element 4 to emit light. At this time, the two light emitting elements 4 are driven by the control circuit 3 so as to repeat light emission and extinction at slightly different timings. As a result, the two sensors of the medal selector are turned on and off in the same sequence as when the medal actually passes, for example, as shown in FIG. For this reason, the blinking of the light emitting element 4 is detected as a medal passing, and it is counted as a medal inserted even though no medal is inserted. In addition, since the light emitting element 4 blinks at high speed, the credits stored electronically in an instant are full (in the case of a slot machine, the maximum number is usually 50).

  In view of the problems as described above, an object of the present invention is to provide a gaming machine capable of preventing an illegal act related to medal insertion.

  According to the present invention, in a gaming machine that is provided in a passage through which a medal to be inserted passes and that includes detection means for detecting the passage of a medal, the passage within a predetermined time based on a detection result of the detection means. Determination means for determining whether or not the number of medals that have passed exceeds a preset reference number, and processing means for performing error processing when the determination means determines that the reference number has been exceeded. , A game table characterized by comprising:

  Further, according to the present invention, in a gaming machine that is provided in a passage through which a medal to be inserted passes and that has detection means for detecting passage of the medal, detection state information based on the detection result of the detection means is stored. Storage means, comparison means for comparing the previous detection state information stored in the storage means with the current detection state information, processing means for performing error processing based on a comparison result of the comparison means, There is provided a game stand characterized by comprising:

  Further, according to the present invention, in a game table provided with a detection means for detecting the passage of medals, the display means for displaying the number of medals inserted, and the detection means arranged in a passage through which the inserted medals pass. Based on the detection result, a first counting means for counting the number of medals that have passed through the passage, and a numerical value of the inserted number displayed on the display means until reaching a count value of the first counting means. A difference between a count value of the second count means that counts at a timing independent of the first count means, a count value of the first count means, and a count value of the second count means is a predetermined value. There is provided a game machine characterized by comprising processing means for performing error processing when the number exceeds.

  In addition, the gaming table of the present invention has a plurality of types of images and a plurality of reels that are rotationally driven, lottery means for determining whether or not an internal winning of a plurality of types of winning combinations is won by lottery, and rotation of the reels. A start switch for starting, a stop switch provided for each of the reels for individually stopping the rotation of the reels, and stop control of the reels based on a lottery result of the lottery means. Reel stop control means for performing, and winning determination means for determining a winning based on whether or not the combination of the pictures displayed by the reels at the time of stop is a predetermined combination of pictures. It can be set as the game stand which pays out a medal based on the determination result of determination.

  According to the present invention, it is possible to prevent fraudulent acts related to medal insertion.

<First Embodiment>
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an external perspective view of a slot machine 100 according to an embodiment of the present invention. In the slot machine 100, a game is started when a medal is inserted, and a medal is paid out according to the result of the game.

<Overall configuration>
Inside the center of the main body 101 of the slot machine 100, three reels (left reel 110, middle reel 111, and right reel 112) having a plurality of types of patterns arranged on the outer peripheral surface are stored and rotated inside the slot machine 100. It is configured to be able to. In this embodiment, an appropriate number of each pattern is printed on the belt-like member at equal intervals, and the reels 110 to 112 are configured by sticking this belt-like member to a predetermined circular frame material. When viewed from the player, approximately three patterns on the reels 110 to 112 are displayed in the vertical direction from the pattern display window 113 so that a total of nine patterns can be seen. Then, by rotating each of the reels 110 to 112, the combination of pictures that can be seen by the player varies. In the present embodiment, three reels are provided in the center of the slot machine 100, but the number of reels and the installation position of the reels are not limited to this.

  In addition, a backlight (not shown) for illuminating each picture displayed on the picture display window 113 is disposed on the back surface of each reel 110 to 112. It is desirable that the backlight is shielded for each pattern so that each pattern can be illuminated evenly. In the slot machine 100, an optical sensor (not shown) including a light projecting unit and a light receiving unit is provided in the vicinity of each reel 110 to 112. The light projecting unit and the light receiving unit of this optical sensor are provided. A light shielding piece of a certain length provided on the reel passes between the parts. Based on the detection result of this sensor, the position of the pattern on the reel in the rotation direction is determined, and the reels 110 to 112 are stopped so that the target pattern is displayed on the winning line 114.

  The winning line display lamp 120 is a lamp that indicates an effective winning line. An effective winning line is determined in advance by the number of medals inserted into the slot machine 100. Of the five winning lines 114, for example, when one medal is inserted, the middle horizontal winning line is valid, and when two medals are inserted, the upper horizontal winning line and the lower horizontal winning line are added. When three medals are inserted and three medals are inserted, the five added with the right-down winning line and the upper-right winning line become effective as the winning line. Note that the number of winning lines 114 is not limited to five.

  The start lamp 121 is a lamp that informs the player that the reels 110 to 112 are in a state of being able to rotate. The re-playing lamp 122 is a lamp for notifying the player that the current game can be replayed (no medal insertion is required) when winning a re-playing role that is one of the winning roles in the previous game. is there. The notification lamp 123 is a lamp that informs the player that a specific winning combination (for example, a bonus such as BB (big bonus) or RB (regular bonus)) is won internally in an internal lottery described later. The medal insertion lamp 124 is a lamp that notifies that a medal can be inserted. The payout number display 125 is a display for displaying the number of medals to be paid out to the player as a result of winning a winning combination. The number-of-games display 126 is an indicator for displaying an error display when a medal is inserted, which will be described later, the number of games during the big bonus game (in the BB game), the number of winnings of a predetermined winning combination, and the like. The stored number display 127 is a display for displaying the number of medals electronically stored in the slot machine 100. The reel panel lamp 128 is an effect lamp.

  The medal insertion buttons 130 and 131 are buttons for inserting a predetermined number of medals stored electronically in the slot machine 100. In this embodiment, every time the medal insertion button 130 is pressed, a maximum of three are inserted one by one, and when the medal insertion button 131 is pressed, three are inserted. The medal slot 134 is an slot for a player to insert a medal when starting a game. That is, the medal can be inserted electronically by the medal insertion button 130 or 131, or an actual medal can be inserted from the medal insertion slot 134.

  The start lever 135 is a lever-type switch for performing a game start operation. That is, when a desired number of medals are inserted into the medal insertion slot 134 and the start lever 135 is operated, the reels 110 to 112 are rotated as a trigger, and the game is started. The stop buttons 137 to 139 are buttons for performing a stop operation on the reels 110 to 112 that have started rotating by operating the start lever 135, and are provided corresponding to the reels 110 to 112. When any one of the stop buttons 137 to 139 is operated, any one of the corresponding reels 110 to 112 is stopped.

  The adjustment button 132 is a button for adjusting the medals electronically stored in the slot machine 100 and the bet medals and discharging them from the medal payout outlet 155 to the tray 210. The medal return button 133 is a button that is pressed to remove a medal when the inserted medal is jammed. The door key 140 is a hole into which a key for unlocking the front door 102 of the slot machine 100 is inserted. The medal payout exit 155 is a payout exit for paying out medals. The medal tray 210 is a container for collecting medals paid out from the medal payout opening 155. In this embodiment, the medal tray 210 employs a tray that can emit light, and may be hereinafter referred to as a tray lamp.

  The sound hole 160 is a hole for outputting the sound of a speaker provided inside the slot machine 100 to the outside. The upper lamp 150, the side lamp 151, the center lamp 152, the waist lamp 153, the lower lamp 154, and the saucer lamp 210 are decorative lamps for exciting the game. The ashtray unit 200 is a container for containing cigarette butts, and is screwed inside the tray 210. The reel panel 161 is a panel having a pattern display window 113, and the title panel 162 is a panel on which the model name of the slot machine and various designs are drawn. The rendering device 600 includes a liquid crystal display device and displays various types of information.

<Medal selector>
The slot machine 100 is provided with a medal selector for selecting regular medals while forming a passage through which medals inserted from the medal insertion slot 134 pass. FIG. 18A is an exploded perspective view of the medal selector 20, and FIG. 19 is a diagram showing how medals pass through the medal selector 20. The medal selector 20 has the same configuration as a known medal selector. Briefly, the medal selector 20 includes a main body 21, a guide member 22 that can be attached to and detached from the main body 21, and a lower portion of the main body 21. And a detachable cover member 23, and is attached to the back surface of the front door 102 via the fixing member 24.

  The main body portion 21 includes a guide plate portion 21a. When the guide member 22 is attached to the main body portion 21, the guide plate portion 22a of the guide member 22 and the guide plate portion 21a are arranged to face each other with a gap. Thus, a receiving part is formed which becomes an entrance of the medal passage. As shown in FIG. 19, the medal first passes through the receiving portion (see A in FIG. 19). The main body portion 21 is provided with a lower guide rail portion 21b and an upper guide rail portion 21c having an L-shaped cross section, and the inserted medal is shown in FIG. 19 as these guide rail portions 21b and 21c. And rolls through the medal selector 20. The guide member 22 is provided with a guide piece 22b that is rotatable in a direction orthogonal to the medal path, and guides the medal so that the medal does not tilt toward the guide member 22 by abutting against the side surface of the passing medal.

  The guide rail portion 21c is set so as to guide a small range at the upper end of the passing medal. If a fake medal smaller than the regular medal is about to pass, the guide rail portion 21c is located at the position B in FIG. It will drop out without being guided by. Since the hole of the medal insertion slot 134 is substantially the same size as a regular medal, a fake medal larger than the regular medal cannot be inserted from the medal insertion slot 134. On the other hand, the main body 21 is provided with a movable piece 21d that is rotatable in a direction orthogonal to the medal passage. When a medal jam occurs, the medal return button 133 is pressed, and the movable piece 21d rotates to the medal path side so that the jammed medal is dropped from the medal selector 20. The main body 21 is provided with a medal blocker 21e that can rotate in a direction orthogonal to the medal passage, and an electromagnetic solenoid 21f that urges the medal blocker 21e to rotate. When the medal is not inserted, the medal blocker 21e is returned so that the medal cannot pass the position C in FIG. 19 (the medal blocker 21e protrudes into the medal passage and the medal passage is closed). To do.

  On the other hand, a sensor unit 21g is arranged at the downstream end of the medal passage of the main body 21. As shown in FIG. 18B, the sensor unit 21g includes two medal insertion sensors 320a and 320b (generally referred to simply as medal insertion sensors 320). The medal insertion sensor 320 is an optical sensor, and includes a light receiving element and a light emitting element as shown in FIG. 18C, and a medal passes between them (see position D in FIG. 19). The passage of medals is detected by blocking the light from the element. As shown in FIGS. 18B and 19, the medal insertion sensors 320a and 320b are arranged along the medal passage, the medal insertion sensor 320a is upstream of the passage, and the medal insertion sensor 320b is downstream of the passage. It is arranged on the side. In this embodiment, two sets of medal insertion sensors 320 are provided, but the present invention is not limited to this, and one or three or more may be provided.

  In the medal selector 20 having such a configuration, as shown in FIG. 19, the medal inserted from the medal slot 134 first passes through the receiving portion (A in FIG. 19) and is guided to the guide rail portions 21b and 21c. Then, it rolls in the medal selector 20 (FIGS. B to D). At this time, a fake medal smaller than a regular medal is selected and dropped by the above-described action, reaches the medal payout exit 155, and is returned to the player. A regular medal is detected by the medal insertion sensor 320 at the position D in the figure, and then guided to the rail portion 24a of the fixing member 24 and dropped to the medal payout device.

<Control unit>
Next, the circuit configuration of the control unit of the slot machine 100 will be described in detail with reference to FIGS. The control unit of the slot machine 100 is roughly divided into a main control unit 300 that controls the central part of the game, and a sub control unit 400 that controls various devices in accordance with commands transmitted from the main control unit 300. Has been.

<Main control unit>
First, the main controller 300 of the slot machine 100 will be described with reference to FIG. The main control unit 300 includes a CPU 310 that is an arithmetic processing unit for controlling the entire main control unit 300, a data bus and an address bus for the CPU 310 to transmit and receive signals to and from each IC and each circuit, It has the structure described below. The clock correction circuit 314 is a circuit that divides the clock oscillated from the crystal oscillator 311 and supplies it to the CPU 310. For example, when the frequency of the crystal oscillator 311 is 12 MHz, the divided clock is 6 MHz. The CPU 310 operates by receiving the clock divided by the clock correction circuit 314 as a system clock.

  The CPU 310 is connected to a timer circuit 315 for setting a timer interrupt processing cycle for constantly monitoring the state of sensors and switches, which will be described later, and a motor drive pulse transmission cycle, via a bus. When the power is turned on, the CPU 310 transmits the frequency dividing data stored in the predetermined area of the ROM 312 to the timer circuit 315 via the data bus. The timer circuit 315 determines an interrupt time based on the received frequency division data, and transmits an interrupt request to the CPU 310 at each interrupt time. In response to this interrupt request, the CPU 310 executes monitoring of each sensor and transmission of drive pulses. For example, when the system clock of the CPU 310 is set to 6 MHz, the frequency division value of the timer circuit 315 is set to 1/256, and the data for frequency division of the ROM 312 is set to 44, the reference time for this interrupt is 256 × 44 ÷ 6 MHz = 1. 877 ms.

  In addition, the CPU 310 stores a program for controlling each IC, a lottery data used for the internal lottery of a winning combination, various data such as a reel stop position, and a ROM 312 for storing temporary data. A RAM 313 is connected. Other storage means may be used for these ROM 312 and RAM 313, and this is the same in the sub-control unit described later. The CPU 310 is connected to an input interface 360 for receiving an external signal. The medal insertion sensor 320, the start lever sensor 321, the stop button sensor 322, and the checkout button sensor are connected to the CPU 310 via the input interface 360 every interrupt time. 324: The state of the medal payout sensor 326 is detected, and each sensor is monitored.

  The start lever sensor 321 is a sensor for detecting the operation of the start lever 132. The stop button sensor 322 is a sensor for detecting which stop button is pressed when any of the stop buttons 133 to 135 is pressed. The medal insertion button sensor 323 is a sensor for detecting which medal insertion button is pressed when one of the medal insertion buttons 130 and 131 is pressed. The settlement button sensor 324 is provided on the settlement button 132, and when the settlement button 132 is pressed once, the stored medals and the bet medals are settled and paid out. The medal payout sensor 326 is a sensor for detecting a payout medal.

  The CPU 310 further has an input interface 361 and output interfaces 370 and 371 connected to an address bus via an address decoding circuit 350. The CPU 310 exchanges signals with external devices via these interfaces. An index sensor 325 is connected to the input interface 361. The index sensor 325 is installed at a predetermined position on the mounting base of each of the reels 110 to 112, and becomes H level each time the light shielding piece provided on the reel passes through the index sensor 325. When detecting this signal, the CPU 310 determines that the reel has made one rotation, and resets the rotational position information of the reel to zero. The output interface 370 includes a reel motor driving unit 330 that controls a motor for driving the reel, and a motor of a hopper (a device for paying out medals accumulated in the bucket from the medal payout outlet 155). A hopper motor driving unit 331 for driving the game, a game lamp 340 (specifically, a winning line display lamp 120, a start lamp 121, a re-playing lamp 122, an announcement lamp 123, a medal insertion lamp 124, etc.), and 7 segments A (SEG) display 341 (a payout number display 125, a game number display 126, a stored number display 127, etc.), and an electromagnetic solenoid 21f are connected.

  A random number generation circuit 317 is connected to the CPU 310 via a data bus. The random number generation circuit 317 is an increment counter capable of incrementing a value within a certain range and outputting the count value to the CPU 310 based on a clock oscillated from the crystal oscillator 311 and the crystal oscillator 316, which will be described later. Used for various lottery processes, including internal lottery for winning positions. The random number generation circuit 317 in the present embodiment includes two random number counters. An output interface 371 for transmitting a command to the sub control unit 400 is connected to the data bus of the CPU 310. Information communication between the main control unit 300 and the sub control unit 400 is one-way communication, and the main control unit 300 transmits a command to the sub control unit 400, but any command or the like from the sub control unit 400 to the main control unit 300 Cannot be sent.

<Sub control unit>
Next, the sub-control unit 400 of the slot machine 100 will be described with reference to FIG. The sub-control unit 400 is an arithmetic processing unit that controls the entire sub-control unit 400 based on a main control command or the like transmitted from the main control unit 300, and the CPU 410 transmits and receives signals to and from each IC and each circuit. It has a data bus and an address bus for performing, and has a configuration described below. The clock correction circuit 414 is a circuit that corrects the clock oscillated from the crystal oscillator 411 and supplies the corrected clock to the CPU 410 as a system clock. Further, a timer circuit 415 is connected to the CPU 410 via a bus. The CPU 410 transmits the frequency dividing data stored in the predetermined area of the ROM 412 to the timer circuit 415 via the data bus at a predetermined timing. The timer circuit 415 determines an interrupt time based on the received frequency division data, and transmits an interrupt request to the CPU 410 at each interrupt time. The CPU 410 controls each IC and each circuit based on the interrupt request timing.

  In addition, the CPU 410 temporarily stores a ROM 412 in which commands and data for controlling the entire sub-control unit 400, backlight lighting patterns and data for controlling various displays, and the like are stored. The RAM 413 is connected via each bus. The CPU 410 is connected to an input / output interface 460 for transmitting and receiving external signals. The input / output interface 460 includes a backlight 420 for illuminating the picture of each reel 110 to 112 from the back, a front surface. A door sensor 421 for detecting opening / closing of the door 102 and a reset switch 422 for clearing data in the RAM 413 are connected.

  An input interface 461 for receiving a main control command from the main control unit 300 is connected to the CPU 410 via a data bus, and an effect process that excites the entire game based on the command received via the input interface 461. Etc. are executed. A sound source IC 480 is connected to the data bus and address bus of the CPU 410. The sound source IC 480 controls sound according to a command from the CPU 410. The sound source IC 480 is connected to a ROM 481 that stores sound data. The sound source IC 480 amplifies the sound data acquired from the ROM 481 by the amplifier 482 and outputs the sound data from the speaker 483. The CPU 410 is connected to an address decoding circuit 450 for selecting an external IC, similar to the main control unit 300, and the input interface for receiving a command from the main control unit 300 is connected to the address decoding circuit 450. 461, an input interface 471 for inputting a signal from the rendering device control unit 500, a clock IC 423, an output interface 472 for outputting a signal to the 7-segment display 440, and the like are connected.

  The CPU 410 can acquire the current time by connecting the clock IC 423. The 7-segment display 440 is provided inside the slot machine 100 so that a store clerk or the like can check predetermined information set in the sub-control unit 400, for example. Further, a demultiplexer 419 is connected to the output interface 470. The demultiplexer 419 distributes the signal transmitted from the output interface 470 to each display unit and the like. That is, the demultiplexer 419 includes an upper lamp 150, a side lamp 151, a center lamp 152, a waist lamp 153, a lower lamp 154, a reel panel lamp 128, a title panel lamp 170, a saucer lamp 210, according to data received from the CPU 410. The outlet strobe 171 is controlled. The title panel lamp 170 is a lamp that illuminates the title panel 162, and the payout outlet strobe 171 is a strobe type lamp installed inside the payout opening. CPU 410 performs signal transmission to rendering device control unit 500 via demultiplexer 419. The rendering device control unit 500 is a control unit that controls the rendering device 600 of FIG.

<Basic control of games>
FIG. 4 is a flowchart showing the basic control of the game in the slot machine 100 of the present embodiment. Basic control of the game is performed mainly by the Main CPU 310, and the game process shown in FIG. Hereinafter, this game process will be described. When the power is turned on, first, initial processing for initializing the main control unit 300 is executed in S101. In S102, game start processing is performed. Here, processing relating to medal insertion and processing relating to the start of a game by the start lever 135 are performed. Details will be described later.

  In S103, the random number generated by the random number generation circuit 317 is acquired. In S104, an internal lottery of a winning combination is performed using the random number acquired in S103 and the winning combination lottery table stored in the ROM 312. As a result of the internal lottery, when any winning combination is won internally, the winning combination flag set in the RAM 313 is turned ON. Examples of winning combinations include replay (replay), small combination, bonus (BB, RB), and the like.

  Each winning combination has a winning probability of internal lottery set for each bet number of medals and set values (1 to 6), and the winning combination lottery table is configured in accordance with this and is obtained at the time of the lottery. The numerical value range (for example, 0 to 16384) is divided in advance into several areas (areas corresponding to the size of each winning probability), and each area is associated with winning or losing of each winning combination. . In the internal lottery of the winning combination, whether or not the internal winning of the winning combination is successful is determined according to which range the acquired random number value belongs. This method is also adopted in other lottery processes.

  In S104, the reel stop control table is selected after the internal lottery. This is a process of selecting a control for the stop operation of each reel. Here, the stop control of the reels 110 to 112 will be briefly described. The reel stop control is performed based on the selected reel stop control table by selecting one of a plurality of predetermined reel stop control tables based on the internal lottery result. The reel stop control table is stored in the ROM 312 of the main control unit 300. The reel stop control table is allowed to display the corresponding combination of symbols for the winning combination won internally by the internal lottery or the so-called flag carryover winning combination. It is configured so that the pattern combinations corresponding to each winning combination are not displayed together. For example, if the “bell” of the small role is not internally won, even if the reels 110 to 112 are stopped at the timing when the “bell” symbol combination is displayed, the reels 110 to 112 are stopped immediately. Therefore, control is performed so that the combination of bell patterns is not completed. On the other hand, when “Bell” is won internally, even if the reels 110 to 112 are not stopped at the timing when the bell picture combination is displayed, the reels 110 to 112 are within a certain range. It will be controlled so that the combination of the pattern of the bells is aligned without stopping immediately.

In S105, rotation of all reels 110 to 112 is started. Thereafter, the stop buttons 137 to 139 can be received. In S106, reel stop control is performed. Here, in response to an operation on the stop buttons 137 to 139, one of the reels 110 to 112 corresponding to the operated stop button 137 to 139 is stopped according to the reel stop control table selected in S104. When all the reels 110 to 112 are stopped, the process proceeds to S107.
Stop according to the table.

  In S107, a winning determination is performed. Here, it is determined that a winning combination has been won when a picture combination corresponding to an internally winning winning combination or a winning combination with a flag carryover is displayed on the activated winning line 114. For example, if “bell-bell-bell” is arranged on the validated winning line 114, it is determined that the bell is won. In addition, the flag corresponding to the winning combination won is reset. In S108, if any winning combination with payout is won, the number of medals corresponding to the winning combination is paid out. In S109, game state control processing is executed. In this gaming state control process, control for changing the gaming state is performed. For example, in the case of a bonus winning such as a big bonus or a regular bonus, a corresponding bonus game is prepared so that it can be started from the next time. In the game, prepare to start the normal game next time. As described above, the process of one game is completed, and then the process returns to S102 and the same process is repeated to advance the game.

<Outline of fraud prevention>
The prevention technique in the present embodiment against fraud using the appliance shown in FIG. 21 will be outlined. 21 is performed by interposing the light emitting element 4 between the light receiving element of the medal insertion sensor 320 of the medal selector 20 and the light emitting element and causing the light emitting element 4 to blink, thereby receiving the light receiving element of the medal insertion sensor 320. Is used to detect this. Here, the blinking cycle of the light emitting element 4 is extremely fast and the detection cycle of the medal insertion sensor 320 is significantly faster than the case of actually detecting a medal in order to end the illegal act in an instant. Therefore, in this embodiment, based on the detection result of the medal insertion sensor 320, the time interval between medals passing through the passage of the medal selector 20 is measured, and this is shorter than a preset time (referred to as a reference time). It is determined that fraudulent activity has been performed and error handling is performed.

  The medal passage interval is counted using an interrupt process executed by the main control unit 300. As described above, in this embodiment, the interrupt process is performed at a cycle of 1.877 ms. Therefore, the value obtained by multiplying the number of executions of the interrupt process from the detection of the passage of a certain medal to the detection of the passage of the next medal by 1.877 ms. Is the passing interval of medals. In the present embodiment, the number of executions of interrupt processing during game start processing is stored in a predetermined area of the RAM 313, and this is updated by a software counter, thereby counting the number of executions of interrupt processing (hereinafter referred to as “interrupt processing”). The software counter is referred to as a medal passage timing counter), and the passage interval is counted with the number of executions.

  The reference time can be determined on the basis of an actually measured value obtained by actually measuring a passing interval of medals when a medal is actually inserted. In the present embodiment, when medals are actually inserted, the passing interval of medals takes at least about 20 msec, and the number of executions of interrupt processing is 11 times (11 × 1. (877 msec = 20.6647 msec), it is determined that an illegal act has been performed, and error processing is performed. In the present embodiment, 11 times are initially set as the initial value of the count value of the medal passing time counter, and each time an interrupt process is executed, one is subtracted from the detection of the passage of a certain medal. Error processing is performed when the count value of the medal passing time counter does not reach zero until the next medal passage is detected. Conversely, one is added each time interrupt processing is executed. The error processing may be performed when the count value of the medal passing time counter does not exceed 11 from the detection of the passing of a certain medal to the detection of the passing of the next medal. Details of the processing will be described below.

<Game start processing>
The game start process in S102 will be described with reference to FIG. FIG. 5 is a flowchart showing the game start process of S102. In S111, the specified number is set. The prescribed number means the maximum number of medals that can be bet in the game. The prescribed number depends on the game specifications of the slot machine 100, but is set to 3 for normal games and 1 for RB games, for example. In S112, the interrupt status is set to medal insertion processing. The interrupt status is information indicating the contents of processing to be executed in interrupt processing. There are a plurality of types of contents to be executed in the interrupt process, and the contents in the medal insertion process are selected in the interrupt process to be executed after that according to the setting in S112.

  In S113, it is determined whether or not the medal insertion is abnormal. If applicable, the process proceeds to S118, and if not, the process proceeds to S114. Whether or not a medal insertion abnormality has occurred depends on whether or not a medal insertion abnormality has been set in an interrupt process to be described later, and this medal insertion abnormality also includes a case where an illegal act using the above-described instrument of FIG. 21 is detected. . In S114, it is determined whether or not the number of inserted medals is one or more. If applicable, the process proceeds to S115, and if not, the process returns to S113. In S115, it is determined whether or not the start lever 135 has been operated. If applicable, the process proceeds to S116, and if not, the process returns to S113. In S116, the number of winning lines effective in the current game is set out of the five winning lines 114. As described above, for example, when one medal is inserted, the middle horizontal winning line is valid, and when two medals are inserted, three lines including the upper horizontal winning line and the lower horizontal winning line are valid. Thus, when three medals are inserted, five lines including a right-down winning line and an upper-right winning line are valid as winning lines. When the specified number is one, the insertion of one medal makes the middle horizontal winning line effective, for example.

  In S117, the interrupt status is set to the next status after the medal insertion process. As a result, the execution of the content processing in the medal insertion processing is terminated in the interrupt processing. In S118, error processing is performed. The contents of the error processing can be selected variously, but here, a predetermined error code is displayed on the game number display 126 and the game is interrupted. This state is released when a reset switch provided in the slot machine 100 is operated. Note that the content of the error processing is not limited to this. For example, an alarm is issued, or information indicating that an error has occurred in the hall computer is transmitted.

<Interrupt processing>
Next, the details of the interrupt processing described above will be described with reference to FIG. In S121, processing such as saving the information of each register of the CPU 310 to the RAM 313 (temporary storage of data currently being processed) is performed. In S122, the port value of the input interface 360 is acquired and stored in a predetermined area of the RAM 313. FIG. 6B is a diagram showing the allocation of each bit (8 bits) of the port of the input interface 360. As described with reference to FIG. 2, the medal insertion sensor 320 and the like are connected to the input interface 360, the detection result of the medal insertion sensor 320a is in bit D0, the detection result of the medal insertion sensor 320b is in bit D1, Each is assigned. Hereinafter, among the values of each port, the values of bits D0 and D1 indicating the detection result of the medal insertion sensor 320 are also referred to as a medal selector state. Note that the port value for a plurality of times is stored in the predetermined area of the RAM 313, and the port value acquired this time is overwritten with the oldest port value in S122.

  In S123, it is determined whether or not the current interrupt status is a medal insertion process. When the medal insertion process is in progress, the process proceeds to S125, and a game medal insertion acceptance process described later is executed. If not, the process proceeds to S124, and processing according to the current interrupt status is executed. In S126, the timer counter is updated. There are a plurality of types of timer counters, and the medal passing time counter described above is included in one of them. The medal passing time counter subtracts one count value by the processing of S126 (when the count value is 0, it is not subtracted). In S127, processing such as restoring the information of each register saved in S121 is performed, and one unit of interrupt processing is completed.

<Game medal insertion acceptance process>
Next, the game medal insertion acceptance process in S125 will be described with reference to FIG. In S131, medal selector processing is performed. Details of the processing will be described later. In S132, other processing is performed. Here, for example, acceptance processing for the settlement button 132, acceptance processing for the medal insertion buttons 130 and 131, and the like are performed.

<Medal selector processing>
Next, the medal selector process in S131 will be described with reference to FIG. In S141, the previous medal selector state stored in the RAM 313 is acquired. In S142, the current medal selector state stored in the RAM 313 is acquired. In S143, it is determined whether or not the medal blocker 21e is in a return state. If so, the process ends. If not, the process proceeds to S144. In S144, the previous medal selector state acquired in S141 is compared with the current medal selector state acquired in S142, and it is determined whether or not the medal selector state has changed. If there is a change, the process proceeds to S145, and if not, the process ends.

  In S145, normal passage determination data is acquired. The normal passage determination data is data for determining whether or not the inserted medal normally passes through the medal selector 20 and is stored in the ROM 312. This will be described with reference to FIG. FIG. 8 shows a change in the detection result of each medal insertion sensor 320a, 320b when the medal normally passes the medal selector 20. A state ST1 in the figure shows a state in which no medal is inserted through the medal insertion sensor 320, and any of the medal insertion sensors 320a and 320b is in a non-detection state. In the state ST2 in the figure, the medal insertion sensor 320a is in a detection state, but the medal insertion sensor 320b is in a non-detection state. Since the medal insertion sensors 320a and 320b are relatively disposed on the upstream side of the passage, the medal insertion sensor 320a first detects the passage of the medal as shown in the state ST2 of FIG.

  In the state ST3 in the figure, both medal insertion sensors 320a and 320b are in a detection state. This indicates that a medal is passing through both medal insertion sensors 320a and 320b. In the state ST4 in the figure, the medal insertion sensor 320a is in the non-detection state, and the medal insertion sensor 320b remains in the detection state. This indicates that the medal has passed the medal insertion sensor 320a but is passing the medal insertion sensor 320b. After the state ST4 in the figure, the state returns to the state ST1 again.

  As described above, in this embodiment, the medal insertion sensors 320a and 320b are relatively arranged on the upstream side of the passage, so that when the medal normally passes, the detection result of the medal insertion sensor 320 is detected. That is, the medal selector state is ST1-> ST2-> ST3-> ST4-> ST1. . . It changes. The normal passage determination data is data composed of the value of the medal selector state in each of the states ST1 to ST4. If the state is ST1 in the previous processing, the data in the state ST2 is acquired in the current processing in S145. The data of each state ST1 to ST4 is cyclically acquired, for example, when the state ST2 is obtained in the previous process, the data of ST3 is acquired by the current process of S145.

  Returning to FIG. 7, in S146, the current medal selector state acquired in S142 is compared with the normal passage determination data acquired in S145, and it is determined whether or not the normal passage is in progress. If it is passing normally, the process proceeds to S148, and if not, the process proceeds to S147. Here, for example, when the current medal selector state acquired in S142 is the state ST2 shown in FIG. 8, and the normal passage determination data acquired by the normal passage determination data acquired in S145 is the state ST2 shown in FIG. Is determined to pass normally. Conversely, when the current medal selector state acquired in S142 is the state ST3 shown in FIG. 8, and the normal passage determination data acquired in the normal passage determination data acquired in S145 is the state ST2 shown in FIG. This means that the medal has been passed without passing through the state ST2, and it is determined that there is some abnormality and that it is not passing normally.

  In S147, a medal insertion abnormality is set. When this setting is performed, it is determined in S113 of FIG. 5 that there is a medal insertion abnormality, and the error process of S118 is performed. In S148, it is determined whether or not the medal has normally passed. The case where the passage is normally completed is a case where the state is shifted from the state ST4 of FIG. 8 to the state ST1. If applicable, the process proceeds to S151, and if not, the process ends. In S151, it is determined whether or not the count value of the medal passing time counter is zero. If it is not 0, the process proceeds to S152. If it is 0, the process proceeds to S147 on the assumption that an illegal act has been performed using the appliance shown in FIG. By proceeding to S147, a medal insertion abnormality is set. In S113 of FIG. 5, it is determined that there is a medal insertion abnormality, and the error processing of S118 is performed. In the present embodiment, the same medal insertion abnormality occurs when the medal is not normally passed in the determination of the medal according to S146 and when the cheating using the appliance shown in FIG. However, these medal insertion anomalies may be handled separately, and different error processing may be performed in the error processing in S118 to clarify which error.

  In S152, an initial value (11) is set in the medal passing time counter. In S153, it is determined whether or not the number of medals inserted is smaller than the prescribed number set in S111 of FIG. If applicable, the process proceeds to S155, and medals inserted as the number of bets are added. When not applicable, it progresses to S154 and it is determined whether the number of stored sheets is smaller than 50 which is the maximum number. If applicable, the process proceeds to S155, and medals inserted as credit medals stored electronically in the slot machine 100 are added. If not applicable, the process is terminated. This completes the medal selector process. Note that the addition of medals in S155 is performed by the bet number counter from S153, and the stored number counter from S154. The bet number counter and the stored number counter are software counters in which each count value is stored in a predetermined area of the RAM 313, and the bet number and the stored number are counted by updating each count value. The bet number counter is cleared at the end of one game.

  As described above, in this embodiment, the passing interval between the medals passing through the passage of the medal selector 20 is counted, and when this is shorter than the reference time, it is determined that the cheating has been performed, error processing is performed, and cheating is performed. Can be prevented. Here, in the present embodiment, timing of the interval between each medal is started when a certain medal completes passing the medal insertion sensor 320 (S152), and ends when the next medal completes passing the medal insertion sensor 320. It is then determined whether the reference time has been reached (S151). At the same time, a new time measurement is started (S152). FIG. 9 is a diagram showing a timed time and a change in the detection state of each medal insertion sensor 320a and 320b. As shown in the figure, in the present embodiment, time measurement is started at the fall of the downstream medal insertion sensor 320b, time measurement is finished at the next fall, and the next time measurement is started. An error occurs if the interval N, which is the passing interval, is 20.647 msec or less. Note that the timing of starting and ending counting of the passage interval is desirable in that it can be measured on the premise that the medal has correctly passed through the passage by using the medal passage completion as a reference, but it is not limited to this. For example, any of T1 to T5 in FIG. However, as in T5, the end of passage of a certain medal is detected by the medal insertion sensor 320b, this is started, and the start of passage of the next medal is detected by the medal insertion sensor 320a. Needless to say, when the reference of the passage interval is changed, the reference time needs to be changed accordingly.

Second Embodiment
As described above, in the fraud using the appliance shown in FIG. 21, the blinking cycle of the light emitting element 4 is extremely fast, and the detection cycle of the medal insertion sensor 320 is significantly faster than the case of actually detecting the medal. This means that the number of medals detected as being inserted within a predetermined time is significantly larger than when medals are actually inserted. Therefore, in this embodiment, it is determined whether or not the number of medals that have passed through the passage of the medal selector 20 within a predetermined time exceeds a preset number (referred to as a reference number), and it is determined that the reference number has been exceeded. If this happens, perform error handling. Only differences from the first embodiment will be described below. FIG. 11 is a flowchart showing medal selector processing (corresponding to FIG. 7) in the second embodiment. 11, steps that perform the same processing as in FIG. 7 are given the same reference numerals, and descriptions thereof are omitted.

  The outline of the medal selector process of the second embodiment is as follows. In the second embodiment, a software counter that counts the number of medals that have passed through the passage of the medal selector 20 within a predetermined time, instead of the above-described medal passage time counter. As a medal count counter, and a medal passing count counter as a software counter that counts the predetermined time. These counters also store count values in predetermined areas of the RAM 313 and update them in the same manner as the medal passing time counter described above. The time to be counted by the medal passing number counting counter is arbitrarily determined, but 399.804 msec is assumed here. The medal passage count counter uses the interrupt processing interrupt cycle in the same manner as the medal passage count counter described above, and the number of executions of interrupt processing reaches 213 times (213 × 1.877 msec = 399.804 msec). The time for counting the number of passing medals is counted as one unit. Specifically, 213 is set as the initial value of the count value of the medal passing time counter, and is subtracted one by one through the processing of S126 in FIG.

  The reference number is set according to the time of one unit measured by the medal passing time counter. In the case of this embodiment, when medals are actually inserted, the reference number is set to 9 because at least 10 or more medals are not inserted within 399.804 msec. In this embodiment, when 9 is set as the initial value of the count value of the medal number counter, one is subtracted every time the medal passes, and the count value becomes 0 before the time-up of the medal passing time counter Does error handling. In this embodiment, the initial value of the count value of the medal number counter is set to 9 times first and is subtracted one by one every time a medal passes. It may be added each time and compared with the reference number.

  Here, in the above-described first embodiment, the passing interval between medals passing through the passage of the medal selector 20 is individually counted, and error processing is performed when this is shorter than the reference time. In order to prevent this, the reference time must be shorter than the shortest passage interval when a medal is actually inserted, and is set to be relatively severe. However, when a plurality of medals are actually inserted continuously, it is impossible in reality that all passing intervals between medals become the shortest passing intervals as long as humans insert medals. That is, in this second embodiment, the unit time counted by the medal passage number time counter does not necessarily need to be “the shortest passage interval × the reference number”. Detection can be prevented. As a result, the rate of fraud capture using the instrument shown in FIG. 21 can be increased.

  In FIG. 11, in S161, it is determined whether or not the count value of the medal passage count counter is zero. If applicable, the process proceeds to S162. Otherwise, the process proceeds to S164. In S162, the count value of the medal passage count counter is set to the initial value (213). This means that the time for counting the number of medals passed is up. In S163, the count value of the medal number counter is set to the initial value (9). In S164, it is determined whether or not the count value of the medal number counter is zero. If applicable, the process proceeds to S162. Otherwise, the process proceeds to S165. In S165, one medal number counter is subtracted. In S166, it is determined whether or not the count value of the medal number counter is zero. If not applicable, the process is terminated, and if applicable, the process proceeds to S147. Thereafter, error processing is performed in S118 of FIG.

  As described above, in this embodiment, the number of medals passing through the passage of the medal selector 20 within a predetermined time is counted, and the number of medals passing through the passage of the medal selector 20 within the predetermined time is set as a preset reference number. It is possible to prevent fraud by performing error processing when it is determined whether or not the reference number has been exceeded. Here, in the present embodiment, timing of the time for counting the number of passing medals and counting of the number of passing medals are started when a certain medal completes passing the medal insertion sensor 320 (S162, S163), and a predetermined time T After a lapse of (399.804 msec), a new timing and counting of the number of passages are started (S162, S163). FIG. 12 is a diagram showing the time counted, the count value of the medal number counter, and the change in the detection state of each medal insertion sensor 320a and 320b. (A) is the case where a medal is actually inserted, (b) Indicates a case where an illegal act using the appliance shown in FIG. 21 is performed. As shown in the figure, in the present embodiment, the time counting and counting of the number of passing medals are started at the fall of the downstream medal insertion sensor 320b, but the start timing may be any time. Then, as shown in FIG. 12B, in the case of a fraudulent act, the medal passing number reaches the reference number before the predetermined time T elapses, and error processing is performed. As shown in FIG. 12A, when medals are actually inserted, the number of medals passing does not reach the reference number even when the predetermined time T has elapsed.

<Third Embodiment>
In the fraud using the appliance shown in FIG. 21, since the blinking of the light emitting element 4 is controlled by the control circuit 3, it is periodically performed. That is, when medals are actually inserted, they are not periodically inserted, but rather randomly inserted, so that the detection waveform of the medal insertion sensor 320 is aperiodic, but the instrument shown in FIG. When an illegal act using is performed, the detection waveform of the medal insertion sensor 320 is extremely periodic. Therefore, when the past detection waveform of the medal insertion sensor 320 and the current detection waveform substantially coincide, it can be determined that an illegal act using the instrument shown in FIG. 21 has been performed.

  Therefore, in the present embodiment, the detection state information based on the detection result of the medal insertion sensor 320 is stored, the stored past detection state information is compared with the current detection state information, and based on the comparison result, Perform error handling. In the present embodiment, as this detection state information, a passing interval between medals passing through the passage of the medal selector 20 is measured and set as the passing interval. Then, error processing is performed when the difference between the past passage interval and the current passage interval is within a preset range. However, as this detection state information, for example, other information such as the time of the detection state of the medal insertion sensor 320 may be used. This is because, when an illegal act is performed using the instrument shown in FIG. 21, the time of the detection state of the medal insertion sensor 320 is almost the same time every time, unlike when the medal is actually inserted. In this regard, in the first and second embodiments described above, in the fraudulent act using the appliance shown in FIG. 21, the flashing cycle of the light emitting element 4 is extremely fast, and the detection cycle of the medal insertion sensor 320 is actually a medal. Although attention is paid to the fact that it is significantly faster than the case of detection, in the third embodiment, even when the flashing cycle of the light emitting element 4 is slow, the fraud can be detected. Only differences from the first embodiment will be described below. FIG. 13 is a flowchart showing medal selector processing (corresponding to FIG. 7) in the third embodiment. In FIG. 13, steps for performing the same processing as in FIG. 7 are denoted by the same reference numerals, and description thereof is omitted.

  The outline of the medal selector process according to the third embodiment is as follows. In the third embodiment, the passing interval between medals passing through the passage of the medal selector 20 is measured using the medal passing time counter described above. The initial value of the medal passing time counter can be arbitrarily determined, but is set to 1000 in the present embodiment. The difference between the count value of the medal passing time counter and the initial value (that is, a value indicating the passing interval) is stored in a predetermined area of the RAM 313, and the past passing interval and the current passing interval are compared. . As a result of the comparison, if the difference in the passage interval is not within a predetermined range (referred to as a reference range; here, 5 is assumed to be about 9.1 msec), error processing is performed. However, in consideration of the timing error, error processing is performed when the difference between the passage intervals is not within the reference range for a plurality of times (here, four times). This continuous number of times is counted by an error counter. The error counter is a software counter that stores a count value in a predetermined area of the RAM 313 and updates it in the same manner as the medal passing time counter. Note that the reference range is set so that the difference between the passage intervals when an actual medal is inserted is obtained by experiment or the like, and error processing is not executed when the medal is actually inserted.

  In FIG. 13, in S <b> 171, a difference between the initial value (1000) of the medal passing time counter and the current count value is obtained to calculate a passing interval, and is stored in a predetermined area on the RAM 313. In S172, the past (previous in this case) passage interval stored in a predetermined area on the RAM 313 is acquired and compared with the current passage interval. In this embodiment, the difference between the two is taken here. In S173, as a result of the comparison in S172, it is determined whether or not the difference between the current passage interval and the previous passage interval is within the reference range. If applicable, the process proceeds to S174, and if not, the process proceeds to S176. The case where it corresponds, that is, indicates that there is a high probability that an illegal act has been performed with the device of FIG. In S174, an initial value is set in the medal passing time counter (1000 in this example). In S175, one count value of the error counter is added. In S176, it is determined whether or not the count value of the error counter is greater than or equal to a predetermined value (here, 4). That is, it is determined whether or not the case where the fraudulent act is performed with the appliance of FIG. If applicable, the process proceeds to S147. Thereafter, error processing is performed in S118 of FIG. If not applicable, the process proceeds to S153. In S177, the error counter is cleared to zero. In S178, an initial value is set in the medal passing time counter (1000 in this example). The process ends as described above.

  As described above, in the present embodiment, the detection state information based on the detection result of the medal insertion sensor 320 is stored, the stored past detection state information is compared with the current detection state information, and based on the comparison result. By performing error processing, fraud can be prevented. In the present embodiment, timing of the passing interval between each medal is started when a certain medal completes passing the medal insertion sensor 320 (S177), and ends when the next medal completes passing the medal insertion sensor 320 ( In step S171, the current and past (previous) passage intervals are compared (S173). That is, as shown in FIG. 14, the times T1 and T2 are compared, but it goes without saying that the start timing and the end timing of the passage interval are not limited to this.

<Fourth embodiment>
In general, a slot machine is provided with a display for displaying the number of medals inserted by a player and stored electronically. Also in this embodiment, a stored number display 127 is provided, and the number of medals stored electronically in the slot machine 100 is displayed. Here, the display of the stored number indicator 127 is updated at a predetermined timing so that the player can easily recognize the number of inserted medals. More specifically, when the player inserts medals, the number of stored medals is counted by the stored number counter. When the display of the stored number indicator 127 is updated in synchronization with this count, When a player inserts medals in quick succession, the display may be updated so early that the values appear to be displayed. That is, actually, for example, 1 → 2 → 3 → 4. . . However, the display visible to the player may be 1 → 4. Therefore, in general, the update of the display of the stored number display unit 127 is updated at a certain period independent of the count timing of the stored number counter so that the player can easily recognize it. In the case of quick insertion, the update of the display of the stored number indicator 127 is executed with a slight delay from the insertion timing.

  On the other hand, as described above, in the illegal act using the appliance shown in FIG. 21, the blinking cycle of the light emitting element 4 is extremely fast and the detection cycle of the medal insertion sensor 320 is actually set in order to end the illegal act instantly. Significantly faster than detecting. Therefore, the update of the display of the stored number display unit 127 is executed extremely late with respect to the update of the count value of the stored number counter. Therefore, in the present embodiment, the number of medals that have passed through the passage of the medal selector 20 is counted by the stored number counter, and the number of inserted sheets (stored number) displayed on the stored number display 127 until the count value of the stored number counter is reached. Are counted at a timing independent of the stored number counter, and error processing is performed when the difference between the two count values exceeds a predetermined value. The inserted number displayed on the stored number display 127 is counted by a display number counter. The display number counter is a software counter that stores a count value in a predetermined area on the RAM 313 and updates the count value to count the number of input sheets displayed on the stored number display unit 127. Further, the count timing of the display number counter is determined by the display update time counter. The display update timing counter is also a software counter that stores a count value in a predetermined area of the RAM 313 and updates it. In the present embodiment, the display number counter is updated at a cycle of about 85 msec so that the player can visually recognize the display update of the stored number display unit 127. Accordingly, the display update time counter is set to 45 as an initial value, and is subtracted one by one through the process of S126 in FIG. Therefore, the update timing of the display number counter has a period of 84.465 msec (= 1.877 msec × 45).

  Hereinafter, the details of the fourth embodiment will be described only with respect to differences from the first embodiment. FIG. 15 is a flowchart showing medal selector processing (corresponding to FIG. 7) in the fourth embodiment. 15, steps that perform the same processing as in FIG. 7 are given the same reference numerals, and descriptions thereof are omitted. In FIG. 15, in S181, it is determined whether or not the count value of the display update time counter is zero. If it is 0, it is determined that it is the display update timing of the stored number indicator 127, and the process proceeds to S182. If not, the process ends. In S182, it is determined whether or not the target number matches the count value of the display number counter. The target number is the count value of the current stored number counter. If they match, the process ends. If they do not match, the process proceeds to S183. In S183, the count value of the display number counter is incremented by one. By the processing in S182 and S183, the display number counter counts up to the target number.

  In S184, the display of the stored number display unit 127 is updated with the count value of the display number counter added in S183. In S185, the difference between the target number and the count value of the display number counter is calculated. In S186, it is determined whether or not the calculation result in S185 exceeds a predetermined value. For example, the predetermined value is 10. In this case, it is determined whether a display delay for ten medals has occurred. When exceeding, it progresses to S147. Thereafter, error processing is performed in S118 of FIG. If not, the process proceeds to S187, the count value of the display update time counter is set to the initial value (45), and the process ends.

  Thus, in this embodiment, fraud can be prevented. FIG. 16 is a diagram showing changes in the count values of the medal insertion number counter and the display number counter. FIG. 16A shows a case where a medal is actually inserted, and FIG. Indicates the case. T in the figure shows the update cycle of the display number counter (84.465 msec). In the case where medals are actually inserted as shown in FIG. 16A, when the count value of the display number counter is 6, the count value of the stored number counter is 7, and there is only one delay. On the other hand, when the illegal act shown in FIG. 16B is performed, the count value of the stored number counter is 10 when the count value of the display number counter is 6, and there is a delay of 4 sheets. It turns out that it is remarkably late compared with the case where a medal is inserted.

<Fifth Embodiment>
In each of the above embodiments, fraudulent acts were prevented using software shown in FIG. Although it is highly convenient in that the hardware of the existing slot machine can be used as it is due to the support by software, it is possible to prevent fraud using the appliance shown in FIG. 21 by devising the hardware. An example of this will be described below. Note that this embodiment can be combined with the above-described embodiments.

  First, the mounting direction of the sensor unit 21g can be changed so that the arrangement of the light emitting elements and the light receiving elements of the medal insertion sensors 320a and 320b with respect to the medal path is reversed. For example, in the example of FIG. 18C, the light receiving element is on the right side of the figure and the light emitting element is on the left side of the figure, but the sensor unit 21g is turned over to the left and right of the figure so that the light receiving element is on the left side of the figure. In addition, the light emitting elements are respectively positioned on the right side of the figure. In the instrument shown in FIG. 21, since the arrangement of the light emitting elements 4 is fixedly determined according to the arrangement of the light emitting elements and the light receiving elements of the medal insertion sensors 320a and 320b, the light emitting elements of the medal insertion sensors 320a and 320b and If the arrangement of the light receiving elements is reversed, it is possible to prevent the light emitting elements 4 in the instrument of FIG. 21 from corresponding to the light receiving elements of the respective medal insertion sensors, thereby preventing fraud.

  Second, it is possible to adopt a configuration in which each medal insertion sensor is attached to the medal path so that the arrangement of the light emitting element and the light receiving element with respect to the medal path can be set independently. In each of the above embodiments, since the sensor unit 21g in which the two medal insertion sensors 320a and 320b are integrally provided is used, the arrangement of the light emitting elements and the light receiving elements of the respective medal insertion sensors 320a and 320b is as described above. Even if one example is adopted, there are two ways. Therefore, the two medal insertion sensors 320a and 320b are not integrated as a unit, but are attached independently, thereby increasing the options for the arrangement of the light emitting elements and the light receiving elements of the medal insertion sensors 320a and 320b. It is possible to further prevent the light emitting element 4 in the instrument of FIG. 21 from corresponding to the light receiving element of each medal insertion sensor, and to prevent fraud. Hereinafter, this second example will be described in more detail.

  FIG. 17A is an external perspective view of the medal insertion sensors 320a ′ and 320b ′ according to the fifth embodiment, and FIGS. 17B to 17E are diagrams showing variations in the arrangement of the medal insertion sensors 320a ′ and 320b. As shown in FIG. 17A, in this embodiment, the two medal insertion sensors are not unitized, and medal insertion sensors 320a 'and 320b' that are individually attached are employed. Since each medal insertion sensor 320a ′ and 320b ′ is independently attached, the light emitting element and the light receiving element are arranged so as to be reversed as shown in FIGS. 17B to 17E. be able to. At this time, if the front and rear of each medal insertion sensor 320a ′ and 320b ′ are interchanged, either the assignment of the bits D0 and D1 of the port shown in FIG. 6B or the normal passage determination data explained in S145 of FIG. Therefore, it is desirable not to replace the front and rear of each medal insertion sensor 320a ′ and 320b ′. In this case, as shown in FIGS. There are 2 × 2 = 4 arrangement relationships.

  Then, if any one of the arrangements shown in FIGS. 17B to 17E is selected and the arrangement of the medal insertion sensors 320a ′ and 320b ′ is changed for each slot machine 100, an illegal act is performed using the instrument shown in FIG. Even if it tries to do, arrangement | positioning of the light emitting element 4 will correspond only by the probability of 1/4, and fraud is prevented. In addition, when arrangement | positioning of the light emitting element 4 does not correspond, it becomes an error in determination of whether it is passing normally, for example shown in S146 of FIG. Furthermore, if it is used in combination with the prevention of fraud by the software of each of the above-described embodiments, the fraud using the appliance of FIG. 21 can be more effectively prevented.

1 is an external perspective view of a slot machine 100 according to an embodiment of the present invention. 3 is a circuit block diagram of a main control unit 300. FIG. 3 is a circuit block diagram of a sub-control unit 400. FIG. 4 is a flowchart showing basic control of a game in the slot machine 100. FIG. It is a flowchart which shows the game start process of S102. (A) is a flowchart showing the interrupt process, (b) is a diagram showing the allocation of each bit (8 bits) of the port of the input interface 360, and (c) is a flowchart showing the game medal insertion acceptance process of S126. It is a flowchart which shows the medal selector process of S131. It is a figure which shows the change of the detection result of each medal insertion sensor 320a, 320b when a medal passes the medal selector 20 normally. It is a figure which shows the change of the detection result of each medal insertion sensor 320a, 320b, and the time-of-measurement start time and the time-end time of the passing interval timed. It is a figure which shows the change of the detection result of each medal insertion sensor 320a, 320b, and the other example at the time of the time measurement start of the passage interval timed, and the time end of time measurement. It is a flowchart which shows the medal selector process in 2nd Embodiment of this invention. In 2nd Embodiment of this invention, it is a figure which shows the time measured, the count value of a medal number counter, and the change of the detection state of each medal insertion sensor 320a and 320b, (a) is actually a medal inserted. (B) shows the case where the cheating with the instrument shown in FIG. 21 is performed. It is a flowchart which shows the medal selector process in 3rd Embodiment of this invention. In 3rd Embodiment of this invention, it is a figure which shows the present time measured in the past, the past time, and the change of the detection state of each medal insertion sensor 320a and 320b. It is a flowchart which shows the medal selector process in 4th Embodiment of this invention. In 4th Embodiment of this invention, it is a figure which shows the change of the count value of a medal insertion number counter and a display number counter, (a) is when a medal is actually inserted, (b) is an instrument shown in FIG. Indicates a case where an illegal act has been conducted. (A) An external perspective view of medal insertion sensors 320a 'and 320b' according to a fifth embodiment of the present invention, and (b) to (e) are diagrams showing variations in the arrangement of medal insertion sensors 320a 'and 320b. (A) is an exploded perspective view of the medal selector 20, (b) is an external perspective view of the sensor unit 21g, and (c) is a sectional view showing a configuration of the sensor 320 and a medal detection mode. It is a figure which shows the passage mode of the medal in the medal selector. (A) is a timing chart which shows the detection aspect of the passage of medals by two sensors, (b) is a timing chart which shows the detection aspect of the two sensors in the case of cheating using an instrument. It is a block diagram of the instrument used for cheating.

Explanation of symbols

100 slot machine

Claims (5)

In a game machine equipped with a detecting means disposed in a passage through which a medal to be inserted passes and which detects the passage of the medal,
Determination means for determining whether or not the number of medals passing through the passage within a predetermined time exceeds a preset reference number based on a detection result of the detection means;
Processing means for performing error processing when the determination means determines that the reference number has been exceeded;
A game table characterized by comprising: In a game machine equipped with a detecting means disposed in a passage through which a medal to be inserted passes and which detects the passage of the medal,
Storage means for storing detection state information based on the detection result of the detection means;
Comparison means for comparing the past detection state information stored in the storage means with the current detection state information;
Processing means for performing error processing based on the comparison result of the comparison means;
A game table characterized by comprising: Based on the detection result of the detection means, comprising a time measuring means for measuring a passing interval between medals passing through the passage,
The detection interval information is the passing interval timed by the time measuring means,
The processing means includes
3. The game table according to claim 2, wherein error processing is performed when a difference between the past passage interval stored in the storage unit and the current passage interval is within a preset range. . In a game machine equipped with a detecting means disposed in a passage through which a medal to be inserted passes and which detects the passage of the medal,
Display means for displaying the number of inserted medals;
First counting means for counting the number of medals passing through the passage based on the detection result of the detecting means;
Second counting means for counting the numerical value of the input number displayed on the display means at a timing independent of the first counting means until reaching the count value of the first counting means;
Processing means for performing error processing when the difference between the count value of the first count means and the count value of the second count means exceeds a predetermined value;
A game table characterized by comprising:   5. The game table according to claim 1, further comprising a medal selector for selecting regular medals, wherein the medal selector forms the passage and is provided with the detection means.

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