JP2006068432A - Game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide the fair games by preventing the generation of the specified random number with the higher probability even when the vicious players operate the games using the vibrations as a reference from the illegal gadgets with a simple circuitry. <P>SOLUTION: The LPF 320 forms a first random number acquisition signal into the second random number acquisition signal by removing the higher pass component from the first signal. A temperature control circuit 321, a heater 322 and a temperature sensor 323 change the time constant of the LPF 320 by varying the temperature of the resistor R1 of the LPF 320. When a second random number acquisition signal generated by the LPF 320 reaches the prescribed value, a waveform forming circuit 314 forms the second random acquisition signal into the steplike latch signal in a waveform to be outputted as a third random number acquisition signal. A memory circuit 313 temporarily holds the counts given by a counting circuit 312 when the third random number acquisition signal is inputted from the waveform forming circuit 314. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a gaming machine that acquires the count value indicated by the count calculation means as a random number value, and thereby draws a winning combination, an effect pattern, and the like.

  2. Description of the Related Art Conventionally, in gaming machines that perform lotteries for winning combinations and production patterns, etc., as described in Patent Document 1, for example, a clock signal with a predetermined period generated by a clock generation circuit made of a crystal oscillator Is provided with a random number generation device that obtains a random number value from the count circuit in response to a game operation performed by the player at an arbitrary time.

  Random number generators composed of such hardware can easily generate uniformly distributed random numbers by increasing the clock cycle, etc., compared to the so-called software random number extraction method that obtains random numbers according to a random number generation algorithm. Therefore, it is widely used in gaming machines such as slot machines or pachinko machines that perform internal lottery such as winning a prize because it reduces the calculation load of the CPU that controls the overall operation of the gaming machine.

  By the way, in recent years, an illegal player operates a game on the basis of vibration from an unauthorized device with a diaphragm attached to an electronic metronome, thereby generating a specific random number with a high probability in a random number generator, and the inside of the gaming machine. The act of winning a random lottery is a problem. However, it is difficult for an unauthorized player who performs such an act to find out early because he or she hides an unauthorized device in his clothes. Corresponding to this, two lots of main and sub are prepared in the lottery counter circuit, and each time the main counter circuit makes a count, the random number is picked up from the sub-counter circuit updated in an infinite loop. The random number generator of the plus random number system that changes the starting point of the main counter circuit each time is copied to the count of the main counter circuit.

JP 2003-190483 A

  However, since the plus random number random number generator used in the conventional gaming machine described above requires two counting operation means, that is, a main circuit and a sub circuit, as a counter circuit, the manufacturing cost of the counting operation means is less than that of one thing. There has been a problem that the amount of the increase has increased greatly.

  The present invention has been made in view of such conventional problems, and an unauthorized player operated a game on the basis of vibration from an unauthorized device without complicating a circuit configuration for performing a lottery in a game. Even in such a case, an object is to provide a gaming machine for ensuring the fairness of the game.

  In order to solve the above-mentioned problem, the invention according to claim 1 is characterized in that a random number acquisition signal generating means for generating a first random number acquisition signal triggered by a predetermined game operation by a player, and the first random number acquisition signal A low-pass filter that shapes the first random number acquisition signal into a second random number acquisition signal by removing high-frequency components from the low-pass filter, and changes the temperature of at least one component of the low-pass filter. Time constant changing means for changing a constant, clock signal generating means for generating a clock signal having a predetermined cycle, count calculating means for counting a count value in synchronization with the clock signal, and the second random number acquisition signal are predetermined. A random number acquisition unit that acquires the count value indicated by the count calculation unit as a random value, and a winning combination based on the random value acquired by the random number acquisition unit. Characterized in that it comprises an internal lottery means for drawing.

  A second aspect of the present invention is the gaming machine according to the first aspect, wherein the time constant changing means includes a heater that heats at least one component of the low-pass filter, and a predetermined specific trigger. Heater driving means for turning on and off the heater is provided.

  A third aspect of the present invention is the gaming machine according to the second aspect, wherein the time constant changing means is further provided with a temperature sensor for detecting a temperature of a component heated by the heater, and the heater driving The means supplies power to the heater so that the temperature of the component heated by the heater rises and falls within a predetermined range based on the detection result of the temperature sensor.

  The invention according to claim 4 is the gaming machine according to claim 2 or 3, wherein at least one component of the low-pass filter is a resistor.

  According to the gaming machine of claim 1, the time until the random number acquisition means acquires the random number value from the timing of the predetermined game operation by the player by the time constant changing means changing the time constant of the low-pass filter by the time constant changing means. Therefore, it is possible to increase a specific random number even when an unauthorized player performs a game operation based on vibrations from unauthorized equipment without complicating the circuit configuration for performing lottery in games. It is possible to prevent acquisition by establishment.

  According to the gaming machine of claim 2, since the heater driving means operates the heater to turn on and off at a predetermined specific timing to heat at least one component of the low-pass filter, the time constant of the low-pass filter is efficiently obtained. Even when an unauthorized player performs a game operation based on vibration from an unauthorized device without increasing the complexity of the circuit configuration for performing a lottery in a game, a specific random value is increased. It is possible to prevent acquisition by establishment.

  According to the gaming machine of the third aspect, the heater driving means supplies power to the heater so that the temperature of the component heated by the heater rises and falls within a predetermined range based on the detection result of the temperature sensor. , When the low-pass filter time constant can be changed efficiently, and the illegal player performs a game operation based on the vibration from the illegal equipment without complicating the circuit configuration for the lottery in the game. Also, it is possible to prevent a specific random value from being acquired with high probability.

  According to the gaming machine of claim 4, the time constant of the low-pass filter can be changed efficiently by using a resistor having a large change in time constant due to heat as at least one component of the low-pass filter. It is possible to acquire a specific random value with high probability even when an unauthorized player performs a game operation based on vibration from an unauthorized device without complicating a circuit configuration for performing a lottery in a game. Can be prevented.

  According to the gaming machine of the present invention, a specific random number value can be obtained even when an unauthorized player performs a game operation based on vibration from an unauthorized device without complicating a circuit configuration for performing a lottery in a game. Can be acquired with high probability. Therefore, an act in which an unauthorized player illegally wins an internal lottery of a gaming machine can be eliminated without significantly increasing the manufacturing cost of the gaming machine, and a fair game can be provided.

  Hereinafter, a preferred embodiment of a gaming machine according to the present invention will be described with reference to the drawings, taking a slot machine as an example. 1 is a perspective view showing the external structure of the slot machine 1, and FIG. 2 is a view showing the internal structure of the slot machine 1 with the front door 3 opened.

  In FIG. 1, a slot machine 1 includes a housing 2 that is a substantially rectangular box, and a front door 3 that is attached to the housing 2 and can be opened and closed by a hinge mechanism.

  The front side of the front door 3 is roughly divided into an upper panel portion 4 and a lower panel portion 5, which are integrally formed of hard plastic as a so-called decorative board designed to enhance the visual effect. Further, below the lower panel portion 5, there is provided a tray unit 6 in which a tray portion 6a for storing medals (game media) to be paid out at the time of winning is integrally formed.

  An operation console 7 is integrally formed between the upper panel portion 4 and the lower panel portion 5 so as to protrude toward the player and on which switches for performing game operations are arranged. In addition, the upper panel part 4, the console 7, the lower panel part 5, and the saucer unit 6 face the player side, and these constitute a "front panel part".

  A panel surface 41 formed of a hard plastic plate or the like is provided at the center of the upper panel portion 4. A substantially rectangular transparent display window 42 is formed substantially at the center of the panel surface 41, and the three reels 101a, 101b, 101c of the reel unit 100 provided in the housing 2 are viewed through the display window 42. .

  Here, in the reel unit 100 installed in the housing 2, cylindrical reels 101a, 101b, and 101c are arranged in the rotation axis direction, respectively, and the outer circumferential surfaces of the reels 101a, 101b, and 101c are arranged in the circumferential direction. A plurality of types of symbols are drawn along. The player can visually recognize three symbols in the vertical direction drawn on three rows of reels through the display window 42.

  In addition, on the panel surface 41, a lamp (not shown) provided on the back side is turned on, for example, a game state display unit 43 that displays information related to a game state such as an internal winning for a winning combination, and a plurality of light emitting diodes The dot matrix display unit 44 that displays the dot image by lighting up, information on the number of medals credited (stored) in the slot machine 1, the number of medals earned by winning, or the number of winning winning combinations Numerical information display sections 45 to be displayed are provided around the display window 42, respectively.

  On the upper part of the upper panel part 4, there are arranged an effect lighting part 46 incorporating lamps such as high-intensity light emitting diodes and an effect sound emitting part 47a, 47b containing a speaker for generating sound effects relating to the game. Has been.

  In addition, a liquid crystal display unit 48 is disposed between the production sound emitting units 47a and 47b so as to face a display window formed by fitting a transparent hard plastic plate or the like. Note that the liquid crystal display unit 48 mainly displays information related to the game effect and information related to the game (game).

  On the side of the upper panel portion 4 are provided lighting units 49a and 49b for production made of fluorescent lamps or high-intensity light emitting diodes. The plurality of effect lighting units 46, 49a, 49b and the like described above are turned on or blinking in accordance with the progress of the game, so that the visual effect in the game is enhanced.

  On the upper right side of the console 7, a medal insertion part 71 having an insertion slot for inserting medals is provided. Further, on the left side of the upper surface, three bet buttons 72, 73, 74 which are push button switches are provided.

  The bet buttons 72, 73, and 74 are button switches for presenting the number of medals to bet on one game of the slot machine. When the game is started, the bet button 72 is pressed, so that one medal is bet on the game from the stored medals. Similarly, when the bet button 73 is pressed, two medals are bet, and when the bet button 74 is pressed, three medals are bet. The bet button 74 is particularly called a “max bet button” because it bets the maximum number of medals.

  On the left side of the front surface of the console 7, a start lever 75 for instructing the start of rotation of the reels 101a, 101b, and 101c is provided. The start lever 75 is provided with a swingable operation rod having a spherical operation knob at the tip, and is turned on when the operation rod is tilted, and automatically when the hand is released from the operation rod by the biasing force of the spring. It is formed of a switch unit that returns to a position and is turned off.

  In the center of the console 7, stop buttons 76a, 76b, and 76c for instructing to stop the rotation of the reels 101a, 101b, and 101c are arranged in parallel corresponding to the arrangement of the reels.

  A key hole 77 into which a key for unlocking the front door 3 is inserted is provided on the right side of the front surface of the console 7. When an administrator or the like of the slot machine 1 inserts a predetermined key into the key hole 77 and performs an unlocking operation, the front door 3 attached to the housing 2 can be opened forward by a hinge mechanism, and the front door 3 can be opened. These are automatically locked when closed to the housing 2 side.

  The lower panel 5 is provided with a panel 51 for displaying a picture of an appearing character and the like so that the player can recognize the model type of the slot machine 1. The saucer unit 6 disposed below the lower panel part 5 includes a medal payout opening 61 for discharging medals at the time of winning a prize, a saucer part 6a for storing the paid-out medals, and a speaker for generating an effect sound. Built-in production sound emitting units 62 are respectively arranged.

  Next, the internal structure of the housing 2 and the back surface structure of the front door 3 will be described with reference to FIG. In the figure, a main control board 20 having a CPU (microcomputer) for centrally controlling the entire operation of the slot machine 1 and housed in a hard plastic case is attached to the upper part of the housing 2.

  A reel unit 100 including reels 101a, 101b, and 101c is provided in the center of the housing 2. The reel unit 100 is positioned and attached to a predetermined frame so that the reels 101a, 101b, and 101c face the display window 42 of the front door 3 when the front door 3 is closed to the housing 2 side. Note that each of the reels 101a, 101b, and 101c is rotationally driven by a built-in stepping motor.

  Further, on the upper part of the reel unit 100, a spinning device board for sending a four-phase drive pulse signal to the stepping motor that rotationally drives each reel is attached, and the main control board 20 is rotated to the spinning device board. By sending drum drive (excitation) pulse data, each reel is controlled to rotate, brake and stop.

  Below the reel unit 100, a hopper device 21, an auxiliary storage unit 22 for storing medals overflowing from the hopper device 21, and a main power supply device 23 are provided. On the side surface of the main power supply device 23, a power supply device substrate 24 corresponding to a so-called switchboard is provided. Further, an external concentration terminal board 25 that can be connected to a management computer called a “hall computer” installed in the game hall is attached to the inner wall on the upper right side of the housing 2.

  Next, a plurality of high-intensity light-emitting diodes 31 that are light sources of the effect illumination unit 46 are arranged on the upper surface on the back side of the front door 3, and the speaker faces the effect sound emission units 47a and 47b. 32a and 32b are attached. Although not shown in FIG. 2, a liquid crystal display unit 48 is attached between the speakers 32a and 32b. Further, a sub-control board 30 formed of an electric circuit board is attached to the back side of the liquid crystal display unit 48.

  Note that the overall operation of the slot machine 1 is comprehensively controlled by the main control board 20 provided on the housing 2 side, and the sub control board 30 controls the display of effect video by the liquid crystal display unit 48 and effect lighting. Control mainly related to game effects, such as illumination control using the parts 46, 49a, 49b, and effect sound effect control using the effect sound emitting parts 47a, 47b, 62, is performed.

  Below the sub-control board 30, a panel plate having a transparent display window 42 for visually observing the reels 101a, 101b, 101c is disposed. Below the display window 42, a start lever 75 on the front side and A central display board 33 that functions as a relay board for transferring output signals of operation switches such as stop buttons 76a, 76b, 76c to the main control board 20 is provided.

  A medal sorting device 34 is attached below the central display substrate 33. The medal sorting device 34 is a device that determines and distributes the suitability of medals inserted into the medal insertion unit 71. Further, the medal sorting device 34 has a built-in medal sensor, and when a normal medal is inserted in a standby state of the game or the like, and the medal sensor detects this medal, a signal indicating acceptance of medal insertion is sent to the main control board. 20 to send. The medal sorting device 34 has a built-in reverse movement detection sensor that detects the movement of the object moving in the medal path in the direction of the slot.

  Below the main body of the medal sorting device 34, a guide member 35 that guides regular medals distributed by the medal sorting device 34 to the hopper device 21 provided in the housing 2 and removed by the medal sorting device 34. A guide member 36 that guides the medal (or foreign matter) that has been made to the medal discharge port 61 is provided. In addition, a guide member 37 that guides medals discharged from the hopper device 21 to the medal discharge port 61 is provided at the lower part on the back side of the front door 3. Further, a speaker 38 is attached adjacent to the medal discharge port 61 so as to face the above-described effect sound emitting unit 62.

  Next, a control system provided in the slot machine 1 will be described with reference to the block diagram of FIG.

  The main control board 20 includes a CPU 201, a random number generator 202, a storage unit 203, a timer 212, a timer interrupt generation unit 213, and a medal credit unit 214.

  The storage unit 203 is configured by a semiconductor memory such as a ROM or a RAM, and stores a system program 204 for a slot machine game in advance. The main control board 20 performs overall control of the overall operation of the slot machine 1 by the CPU 201 executing arithmetic processing according to the system program 204 stored in the storage unit 203.

  Operation switches such as bet buttons 72, 73 and 74, start lever 75, stop buttons 76a, 76b and 76c, and detection switches such as a medal sensor 34a of the medal sorting device 34 are connected to the main control board 20 with a wiring cable. Has been. The main control board 20 detects an operation related to the game based on output signals from the switches.

  The medal credit means 214 of the main control board 20 adds the number of medals inserted in the medal sorting device 34 and detected by the medal sensor 34a to the number of credits of medals stored internally.

  Further, the main control board 20 inputs detection signals from the reference position sensors 120a, 120b, and 120c provided on the reels 101a, 101b, and 101c, and grasps the rotation position serving as the reference of each reel, while rotating the rotating apparatus board. Predetermined cylinder drive pulse data is sent to 130. The rotating device substrate 130 controls the rotation and stopping of the reels 101a, 101b, and 101c by rotating the stepping motors 110a, 110b, and 110c in accordance with the rotating drive pulse data from the main control substrate 20. ing.

  In addition, a medal payout device such as a hopper device 21 and a sub control board 30 are connected to the main control board 20 by wiring cables. The main control board 20 pays out a predetermined number of medals to the tray portion 6a by controlling the hopper device 21 when a winning is confirmed.

  The sub-control board 30 controls and drives the liquid crystal display unit 48, the effect lighting units 46, 49a, 49b, and the effect sound emitting units 47a, 47b, 62 based on the control signal from the main control board 20. Productions that appeal to the visual and auditory sense of the person are performed as the game progresses.

  The storage unit 203 of the main control board 20 stores a winning lottery table 205 and an internal lottery flag 206. For example, the CPU 201 activates the random number generator 202 when the start lever 75 is operated, acquires a random number value, and refers to the winning lottery table 205 to thereby determine the winning combination or loser assigned to the obtained random number value. Lottery. Then, if there is a winning combination corresponding to the random number value, the CPU 201 wins the lottery result by using the winning combination as the winning combination of the game, and stores the winning combination in the internal lottery flag 206 of the storage unit 203. Here, the lottery method of winning combination is called “internal lottery”.

  The storage unit 203 stores non-rewritable reference data tables such as symbol arrangement data 207, reel stop position search table 208, and reel stop position selection table 209, and further includes a reel stop frame flag 210, a reel control flag 211, and the like. A rewritable data flag memory area is secured. These reference data table and data flag are used for the rotation and stop control of the reels 101a, 101b, and 101c.

  Note that the timer 212 measures the time until the automatic stop control of the reels 101a, 101b, and 101c is started, for example. The timer interrupt generation unit 213 is for synchronizing pulse signals (rotating drum drive pulse data) for controlling the stepping motors 110a, 110b, and 110c of the reels 101a, 101b, and 101c.

  Next, an outline of the game operation in the slot machine 1 will be described.

  The slot machine 1 enters a standby state when a prize is won in a previous game and a medal payout is completed, or when a loss is confirmed in the previous game. In this standby state, a standby mode effect is provided that suggests the state to the player and prompts a game operation. Next, when the player inserts a medal into the medal insertion unit 71 and presses any one of the bet buttons 72, 73, 74, the slot machine 1 determines a predetermined game from the medal (credit) stored inside. A number of medals are bet and the game is prepared.

  When the start lever 75 is tilted and the game is started in the game preparation state, the main control board 20 starts to rotate the three reels 101a, 101b, and 101c all at once and executes the internal lottery described above. The result of the internal lottery is stored in the internal lottery flag 206.

  Next, when one of the stop buttons 76a, 76b, and 76c is pressed by the player and the main control board 20 detects an operation of stopping the reel, the main control board 20 is changed to the pressed stop button. Control to stop the corresponding reel. When the main control board 20 detects that all the reels 101a, 101b, and 101c have stopped, the combination of the symbols displayed on each reel and the symbols related to the winning combination corresponding to the internal lottery flag 206 is one. Determine if you are doing it.

  When the winning of the winning combination is confirmed, the slot machine 1 is determined in advance according to the type of the winning combination based on the control of the main control board 20 until the number of credits of the internally stored medals reaches a predetermined number. Add the medal of the number of dividends to the number of credits. Further, when the addition result of the number of payouts and the number of credits exceeds the predetermined number, the slot machine 1 pays out the surplus number of medals to the tray unit 6a.

  FIG. 4 is a model diagram for explaining an internal lottery method using the winning lottery table 205. This figure shows an example in the case where the slot machine 1 is in a general gaming state. As a winning combination, a small combination <1>, <2>, a re-playing combination called replay, and a regular bonus (RB) ) And a big win called Big Bonus (BB).

  Here, the small role is a winning combination in which a predetermined number of medals are paid out to the player, and the re-playing role (replay) is the player who has the right to re-game while maintaining the number of medals inserted in the previous game. It is a winning combination to give to. Further, the special combination (RB) is a winning combination that gives a player a gaming state (special gaming state) in which a medal with a higher payout is paid compared to the general gaming state until a predetermined number of times or a predetermined number of winnings is reached. The big winning combination (BB) is a winning combination that gives the player the gaming state of the special combination a predetermined number of times.

  In the winning lottery table 205, a range of random values corresponding to each winning combination is assigned according to a winning probability defined for each winning combination. That is, in the winning lottery table 205, for example, the range of random values corresponding to a loss is the largest, followed by a small role <1>, a small role <2>, a replay (replaying role), a special role (RB), In the order of big winning combination (BB), the range of random values corresponding to each winning combination is set to be gradually reduced.

  When the start lever 75 is turned on, the internal lottery means of the main control board 20 acquires a random number value from the random number generator 202 and compares the acquired random number value with the winning lottery table 205 to draw a winning combination of the game. To do.

  For example, if the acquired random value Ri satisfies the relationship of R1 ≦ Ri <R2 shown in FIG. 4, the small role <1> is drawn, and if the relationship of R2 ≦ Ri <R3 is satisfied, the small role <2> is drawn. If the relationship of R3 ≦ Ri <R4 is satisfied, a replay (re-playing role) is drawn, and if the relationship of R4 ≦ Ri <R5 is satisfied, a special role (RB) is drawn, and the relationship of R5 ≦ Ri ≦ Rmax is satisfied. Draw a big hit (BB). Further, when the obtained random number value is 0 ≦ Ri <R1, it is lost. When the main control board 20 wins any of the winning combinations, the main control board 20 stores a flag corresponding to the combination.

  In the slot machine 1, a plurality of types of winning lottery tables 205 are prepared for use in accordance with the general game state, the special game state, and the payout rate setting stage.

  Next, when the player turns on the stop buttons 76a, 76b, and 76c in an arbitrary order, the main control board 20 performs control to sequentially stop the reels accordingly. When it is detected that all the reels 101a, 101b, and 101c are stopped, it is determined whether or not the symbols displayed on the reels match the symbols associated with the winning combination corresponding to the flag.

  For example, when three medals are bet on the game by pressing the bet button 74, the nine symbols that are viewed through the display window 42 are arranged on three horizontal rows in the upper, middle, and lower rows. Examine the three sets of symbols and two sets of symbols arranged on two diagonal lines in the diagonally right and left diagonal directions, and the symbol combination condition of the winning combination corresponding to the above flag is determined by any one of the symbols. When satisfied and complete, it is determined that the winning combination has been won. When the winning of the winning combination is confirmed, a medal with a predetermined number of payouts according to the type of the winning combination is paid out to the tray 6a, or medals corresponding to the payout number are added to the number of credits stored internally.

  Next, the random number generator 202 provided in the internal lottery means will be described with reference to FIGS. FIG. 5 is a block diagram showing the system configuration of the internal lottery means. FIG. 6 is a graph showing the relationship between the temperature of the resistor used in the low-pass filter and time. FIG. 7 is a time chart showing main signal waveforms in the internal lottery means.

  In FIG. 5, the CPU 201 generates a first random number acquisition signal that is the trigger signal T in response to the start lever 75 being turned on. Note that the CPU 201 does not output the first random number acquisition signal even if the start lever 75 is turned on until the slot machine 1 enters the above-described standby state after the first random number acquisition signal is output once. With such a configuration, the CPU 201 serves as a random number acquisition signal generation unit that generates a first random number acquisition signal in response to a predetermined game operation by the player.

  The random number generation device 202 includes a clock generation circuit 311 formed from a crystal oscillator, a count circuit 312 that counts the clock signal CK generated by the clock generation circuit 311, and the first random number acquisition signal generated by the CPU 201. A low-pass filter (hereinafter referred to as LPF) 320 for shaping the first random number acquisition signal into a second random number acquisition signal by removing the band component, and a temperature control circuit 321 for controlling the temperature of the resistor R1 of the LPF 320; , A waveform shaping circuit 314 that shapes the second random number acquisition signal generated by the LPF 320 into a step-shaped latch signal and outputs the waveform as a third random number acquisition signal, and a third random number acquisition signal from the waveform shaping circuit 314 Then, a storage circuit 313 that temporarily holds the count value indicated by the count circuit 312 is provided.

  The clock generation circuit 311 constantly outputs, for example, a clock signal CK of about 14 MHz regardless of the operation of the CPU 201. With this configuration, the clock generation circuit 311 serves as a clock signal generation unit that generates a clock signal having a predetermined period.

  The count circuit 312 serves as a count calculation unit that counts a count value in synchronization with the clock signal CK.

  The LPF 320 includes a resistor R1 and a capacitor C1. One end of the resistor R1 is connected to the input terminal of the LPF 320. The other end of the resistor R1 is connected to the output terminal of the LPF 320 and is connected to the reference potential point via the capacitor C1. A heater 322 and a temperature sensor 323 are attached in contact with the resistor R1. The heater 322 generates heat when power is supplied from the temperature control circuit 321 and heats the resistor R1. The temperature sensor 323 detects the temperature of the resistor R1.

  When the detection result of the temperature sensor 323 becomes equal to or lower than the first predetermined temperature A1 (for example, 35 ° C.), the temperature control circuit 321 sets the detection result of the temperature sensor 323 to the second predetermined temperature A2 (for example, 60 ° C.). Until the heater 322 is supplied with electric power, the temperature of the resistor R1 is increased. Further, when the detection result of the temperature sensor 323 becomes equal to or higher than the second predetermined temperature A2, the temperature control circuit 321 supplies power to the heater 322 until the detection result of the temperature sensor 323 reaches the first predetermined temperature A1. Is stopped to lower the temperature of the resistor R1. In the LPF 320, when the temperature of the resistor R1 rises, the resistance value of the resistor R1 increases, and the delay amount of the signal by the LPF 320 increases.

  With this configuration, the temperature control circuit 321, the heater 322, and the temperature sensor 323 change the time constant of the LPF 320 by changing the temperature of at least one component of the LPF 320 (in this embodiment, the resistor R1). It is a time constant changing means. The temperature control circuit 321 serves as heater driving means for supplying electric power to the heater 322 so that the temperature of the component heated by the heater 322 rises and falls within a predetermined range based on the detection result of the temperature sensor 323. Yes.

  The waveform shaping circuit 314 includes a Schmitt trigger IC, and the second random number acquisition is performed when the second random number acquisition signal generated by the LPF 320 becomes a rising threshold (hereinafter referred to as L → H threshold). The signal is shaped into the stepped latch signal and output as a third random number acquisition signal.

  The count circuit 312 is formed of a 16-bit increment counter, for example, and repeatedly outputs the count value from 0 to 65535 in synchronization with the clock signal CK. The storage circuit 313 acquires and stores the count value indicated by the count circuit 312 when receiving the third random number acquisition signal from the waveform shaping circuit 314. At this time, the CPU 201 reads the count value acquired by the storage circuit 313 and uses it as a random value for internal lottery. With such a configuration, the waveform shaping circuit 314 and the memory circuit 313 acquire the count value indicated by the count circuit 312 as a random value when the third random number acquisition signal reaches a predetermined value. It has become.

  Next, the operation of the temperature control circuit 321 will be specifically described with reference to the graph of FIG.

  In FIG. 6, the temperature control circuit 321 increases the temperature of the resistor R1 by supplying power to the heater 322 when the detection result of the temperature sensor 323 is equal to or lower than the first predetermined temperature A1, as shown at timing T1. Let Then, when the temperature of the resistor R1 rises and the detection result of the temperature sensor 323 becomes equal to or higher than the second predetermined temperature A2, as shown in the timing T2, the temperature control circuit 321 supplies power to the heater 322. The operation is stopped until the timing T3, and the temperature of the resistor R1 is lowered to the first predetermined temperature A1. Hereinafter, the temperature control circuit 321 performs control to repeatedly increase and decrease with respect to the temperature of the resistor R1. As a result, the temperature control circuit 321 repeatedly increases and decreases the signal delay amount by the LPF 320.

  In this embodiment, the amount of heat generated by the heater 322 and the amount of heat released by the resistor R1 are set such that the time from the timing T1 to the timing T2 is, for example, 10 seconds, and the time from the timing T2 to the timing T3 is, for example, 50 seconds. Is set.

  Next, the operation of the random number generator 202 will be specifically described with reference to the time chart of FIG. Here, FIG. 7A shows a first random number acquisition signal from the CPU 201. FIG. 7B shows a second random number acquisition signal from the LPF 320. FIG. 7C shows a third random number acquisition signal from the waveform shaping circuit 314. 7B and 7C, the solid line indicates the case where the detection result of the temperature sensor 323 is the first predetermined temperature A1, and the broken line is the case where the detection result of the temperature sensor 323 is the second predetermined temperature A2. Is shown.

  As shown in FIG. 7A, the first random number acquisition signal generated by the CPU 201 instantaneously rises from the low level (L) to the high level (H) at the timing T10 when the start lever 75 is turned on. Yes. As shown in FIG. 7B, the second random number acquisition signal obtained by passing the first random number acquisition signal through the LPF 320 is a signal that gradually rises from the low level to the high level with a delay from the timing T10. Become.

  Here, the slope when the second random number acquisition signal rises from the low level to the high level is lower as the temperature is higher, as shown by the broken line. Therefore, the timing Tx at which the second random number acquisition signal exceeds the falling threshold (hereinafter referred to as the H → L threshold) B2 and becomes the L → H threshold B1 is earlier when the temperature is lower and the temperature is higher. Will be slower. When the detection result of the temperature sensor 323 is the first predetermined temperature A1 (when the temperature of the resistor R1 is the first predetermined temperature A1), the second random number acquisition signal is L → H threshold B1 at timing Tx = T11. When the detection result of the temperature sensor 323 is the second predetermined temperature A2 (when the temperature of the resistor R1 is the second predetermined temperature A2), the second random number is acquired at the timing Tx = T12 later than the timing T11. The signal becomes L → H threshold B1.

  When the second random number acquisition signal shown in FIG. 7B becomes a predetermined value (L → H threshold B1), the waveform shaping circuit 314 converts the second random number acquisition signal into the step-shaped latch signal. And is output as a third random number acquisition signal shown in FIG.

  When the detection result of the temperature sensor 323 shown in FIG. 6 is the first predetermined temperature A1, the third random number acquisition signal output from the waveform shaping circuit 314 is substantially as shown by the solid line in FIG. At timing T11, the signal rises instantaneously from the low level (L) to the high level (H).

  When the detection result of the temperature sensor 323 shown in FIG. 6 is the second predetermined temperature A2, the third random number acquisition signal output by the waveform shaping circuit 314 is substantially as shown by the broken line in FIG. At timing T12, the signal rises instantaneously from the low level (L) to the high level (H).

  When the detection result of the temperature sensor 323 shown in FIG. 6 is a value between the first predetermined temperature A1 and the second predetermined temperature A2, the low level (L ) To a high level (H) instantaneously.

  That is, the third random number acquisition signal is the timing Tx when the second random number acquisition signal becomes the L → H threshold B1 (T11 in the case of the first predetermined temperature A1, T12 in the case of the second predetermined temperature A2). In this case, the signal rises instantaneously from the low level (L) to the high level (H).

  The storage circuit 313 acquires and stores the count value indicated by the count circuit 312 at the timing Tx when the third random number acquisition signal from the waveform shaping circuit 314 is received. That is, the random number generation device 202 acquires the count value indicated by the count circuit 312 as a random number value at a timing Tx delayed from the timing T10 when the start lever 75 is turned on. Here, in the random number generation device 202, the time Tx at which the third random number acquisition signal rises with respect to the timing T10 of the predetermined game operation by the player is changed by the change of the time constant of the LPF 320 by the control of the temperature control circuit 321. Change. That is, in the random number generation device 202, the time from the timing T10 until the storage circuit 313 acquires the random number value from the count circuit 312 ranges from (T11−T10) = for example, 2 seconds to (T12−T10) = for example, 5 seconds. Can be changed arbitrarily. As a result, even if the count value of the count circuit 312 is the same at the timing T10 of the predetermined game operation by the player, the random number value generated by the random number generator 202 is arbitrarily changed.

  In the waveform shaping circuit 314, the output from the CPU 201 to the LPF 320 is reset, and the second random number acquisition signal shown in FIG. 7B falls from the high level (H) and falls below the H → L threshold A2. In this case, the output instantaneously falls from the high level (H) to the low level (L).

  According to the random number generation device 202 having such a configuration, the time from the timing T10 of the predetermined game operation by the player until the memory circuit 313 acquires the random number value from the count circuit 312 can be arbitrarily changed. With the circuit configuration, even when an unauthorized player performs a game operation based on vibration from an unauthorized device, the random number generator 202 can be prevented from generating a specific random value with high probability. Therefore, problems such as an illegal player intentionally cheating and increasing the probability of winning a prize are solved.

  In the random number generator 202 shown in FIG. 5, the LPF 320 is configured by the resistor R1 and the capacitor C1, but other types of LPF may be applied as the LPF of the random number generator. In the random number generator 202 shown in FIG. 5, the temperature control circuit 321 is configured to change the temperature of the resistor R <b> 1, but the LPF component that changes the temperature may be a component other than the resistor. In the random number generator 202 shown in FIG. 5, the detection result of the temperature sensor 323 is used as a predetermined specific trigger for the heater driving means to turn on or off the heater 322. Various triggers for turning on the 322 can be applied, for example, when a specific symbol is displayed on each reel of the slot machine 1 or when winning a jackpot. Furthermore, various triggers can be applied as a trigger for the heater driving means to turn off the heater 322, for example, when a certain period of time has passed since the heater 322 was turned on.

  The present invention can be applied not only to slot machines, but also to pachinko machines and other gaming machines that perform lotteries such as winning lotteries and production patterns using a hardware random number generator based on a clock signal.

FIG. 1 is a perspective view showing an external structure of a slot machine according to an embodiment of the present invention. FIG. 2 shows the internal structure of the slot machine according to the embodiment of the present invention. FIG. 3 is a block diagram showing a slot machine control system according to an embodiment of the present invention. FIG. 4 is a model diagram for explaining an internal lottery method using a winning lottery table according to an embodiment of the present invention. FIG. 5 is a block diagram showing the system configuration of the internal lottery means according to one embodiment of the present invention. FIG. 6 is a graph showing the relationship between the temperature and time of the resistance used in the low-pass filter according to the embodiment of the present invention. FIG. 7 is a time chart showing main signal waveforms in the internal lottery means according to the embodiment of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Slot machine, 2 ... Housing | casing, 3 ... Front door, 4 ... Upper panel part,
5 ... Lower panel part, 6 ... Receptacle unit, 6a ... Receptacle part, 7 ... Console,
20 ... main control board, 21 ... hopper device, 22 ... auxiliary reservoir,
23 ... Main power supply device, 24 ... Power supply device board, 25 ... External concentrated terminal board,
30 ... Sub-control board, 31 ... Light emitting diode,
32a, 32b ... speaker, 33 ... central display board,
34 ... Medal sorting device, 34a ... Medal sensor,
35, 36, 37 ... guide member, 38 ... speaker,
41 ... Panel surface, 42 ... Display window, 43 ... Game state display part,
44 ... dot matrix display section, 45 ... numerical information display section,
46 ... Illumination unit for production, 47a, 47b ... Sound emission unit for production,
48 ... Liquid crystal display unit, 49a, 49b ... Illumination section for effects,
51 ... Panel, 61 ... Medal payout opening, 62 ... Sound emission part for production,
71 ... medal insertion part, 72, 73, 74 ... bet button,
75 ... Start lever, 76a, 76b, 76c ... Stop button,
77 ... Keyhole,
100 ... reel unit,
101a, 101b, 101c ... reel,
110a, 110b, 110c ... stepping motors,
120a, 120b, 120c ... reference position sensor,
130 ... Cylinder device substrate,
201 ... CPU, 202 ... random number generator, 203 ... storage unit,
204 ... system program, 205 ... winning lottery table,
206 ... Internal lottery flag, 207 ... Symbol arrangement data,
208: Reel stop position search table,
209 ... Reel stop position selection table,
210: Reel stop frame flag, 211: Reel control flag,
212 ... Timer, 213 ... Timer interrupt generation unit,
214 ... Medal credit means 300 ... Directing device,
311 ... Clock generation circuit, 312 ... Count circuit,
314 ... Waveform shaping circuit, 313 ... Memory circuit, 320 ... LPF,
321 ... Temperature control circuit, 323 ... Temperature sensor, 322 ... Heater,
C1, C2 ... capacitor, R1 ... resistor, L2 ... coil

Claims (4)

Random number acquisition signal generating means for generating a first random number acquisition signal triggered by a predetermined game operation by the player;
A low-pass filter that shapes the first random number acquisition signal into a second random number acquisition signal by removing a high frequency component from the first random number acquisition signal;
Time constant changing means for changing the time constant of the low-pass filter by changing the temperature of at least one component of the low-pass filter;
Clock signal generating means for generating a clock signal of a predetermined period;
Counting operation means for counting a count value in synchronization with the clock signal;
Random number acquisition means for acquiring the count value indicated by the count calculation means as a random value when the second random number acquisition signal reaches a predetermined value;
A gaming machine comprising: an internal lottery means for drawing a winning combination based on the random value acquired by the random number acquiring means. The time constant changing means is
A heater for heating at least one component of the low-pass filter;
The game machine according to claim 1, further comprising heater driving means for turning on and off the heater at a predetermined specific opportunity.   The time constant changing means is further provided with a temperature sensor for detecting the temperature of the component heated by the heater, and the heater driving means determines the temperature of the component heated by the heater based on the detection result of the temperature sensor. The gaming machine according to claim 2, wherein electric power is supplied to the heater so as to move up and down within a predetermined range.   The gaming machine according to claim 2 or 3, wherein at least one component of the low-pass filter is a resistor.

Images