JP3783724B2 - Credit monitoring system and credit monitoring device used therefor - Google Patents

Description

  The present invention relates to a credit monitoring system capable of detecting an illegal act of counting up credits (number of coins inserted) in a slot game machine installed in a pachinko hall using an unauthorized device, and a credit monitoring used in the credit monitoring system. It relates to the device.

  Conventionally, in a slot game machine, a passage sensor that detects the passage of a coin is installed in the vicinity of the coin insertion slot, and a detection signal output from the passage sensor is counted every time a coin inserted from the coin insertion slot passes. By doing so, the credit is counted up. Specifically, the passage sensor irradiates infrared rays from the light emitting unit, and counts up when the reflected light of the infrared rays is received by the light receiving unit. That is, when the coin passes, the infrared light emitted from the light emitting part is reflected on the coin surface, and the reflected light is received by the light receiving part to detect that the coin has passed.

  In such a slot game machine or the like, Patent Documents 1 and 2 propose an apparatus for detecting fraud.

In the devices described in Patent Documents 1 and 2, cheating is monitored using two passage sensors based on outputs from the two passage sensors. Specifically, two passing sensors are directly mounted in the coin passing path on the game table so that the two passing sensors are close to each other. Then, it is determined whether or not the order of coins passing through the two passage sensors is correct, and further whether or not the interval of the passage time of the coins passing through the two passage sensors is appropriate, and the order of the coins is correct, In addition, if the interval of coin passing time is appropriate, it is determined that there has been no cheating, and if not, it is determined that there has been cheating.
JP 2000-325549 A Japanese Patent Laid-Open No. 10-230068

  In recent years, the fraudulent act which counts up the credit of a slot game machine using an unauthorized device is prevalent. This fraudulent device is a palm-sized device that has a tip that can be inserted into the coin slot, and has an infrared light emitter attached to the tip, allowing infrared light emitted by the infrared light emitter to pass through. By irradiating the light receiving part of the sensor, the credit is counted up. This unauthorized device emits infrared rays, for example, about 25 to 30 times per second, and credits can be raised to 50 by using it for about 2 seconds. For this reason, it is possible to count up credits even in a short time, and the damage to pachinko halls is great. In addition, due to such fraudulent behavior, accurate data on the number of credits IN (the number of coins inserted) and the number of OUTs (the number of coins to be paid out) cannot be obtained, which affects slot settings and the like. May suffer damage.

  In addition, as for the credit counting method in the slot game machine, the light from the infrared light emitting part is guided to the light receiving part by the U-shaped reflecting member, and the credit counting is performed by blocking the infrared ray when the coin passes. However, even in such a form, it is possible to perform the same illegal act by blocking the infrared ray at the tip of the unauthorized device and repeating the infrared irradiation as described above. . For this reason, the same problem as described above occurs.

  It is conceivable to take measures against such illegal acts by using the devices described in Patent Documents 1 and 2 described above. However, in these devices, both of the two passage sensors are used by an unauthorized device. If the infrared rays are repeatedly irradiated, the passage of coins will be detected by both of the two passage sensors, so the credit will be counted up as usual, and it will be detected that fraud has occurred. Can not do it.

  The present invention has been made in view of the above points, and it is an object of the present invention to provide a credit monitoring system capable of detecting fraudulent acts of illegally counting up credits and preventing damage to pachinko halls and a credit monitoring device used therefor. .

  In order to achieve the above object, according to the first aspect of the present invention, there is provided a current sensor (3) connected to the signal line of the passage sensor and sensing an output current of the passage sensor flowing in the signal line and outputting an analog signal. A conversion means (12) for converting the analog signal into a digital signal by comparing the analog signal with a predetermined reference value, and a predetermined set time as a threshold value, and the analog signal output from the current sensor to the conversion means. By determining whether or not the pulse width of the converted digital signal exceeds a threshold value, a determination means (110) for determining an abnormal waveform of the pulse signal output from the passage sensor, and a pulse of the digital signal by the determination means And a warning command means (150) for outputting a warning command signal for performing a warning when it is determined that the width exceeds the threshold value. To have.

  Thus, the fact that the pulse signal is output from the passage sensor is detected by sensing the current flowing through the signal line with the current sensor. Whether the pulse width is due to normal coin insertion or fraud by determining whether the pulse width of the digital signal when the analog signal output by this current sensor is converted to digital exceeds the threshold value Can be detected. Therefore, when a misconduct is detected, an alarm means alerts the pachinko hall clerk so that the cheating can be detected and the misconduct can be suppressed. This can be prevented beforehand.

  Incidentally, there is a case where a solenoid is provided in the vicinity of the coin insertion slot, and the current sensor picks up a signal when the solenoid is driven. In such a case, it is not preferable to determine that an illegal act is being performed only by the pulse width exceeding the threshold value.

Therefore, in the invention according to claim 2, the determination means obtains an IN signal indicating the number of coins inserted from the slot game machine. When the pulse width exceeds the threshold value, the IN signal If is not included, the alarm command means is made to output an alarm command signal. Further, in the invention according to claim 4, determining means, as when the when the digital signal obtained by converting the analog signal output by the current sensor at converting means is interrupted coin was last turned, is 該Ko Inn before there will be a predetermined time since it last turned, digital signal determines whether showed the following pulse, when the pulse width exceeds the threshold value, pulses before the predetermined time has vacant When a signal is output, the alarm command means outputs an alarm command signal.

  As described above, an alarm may be issued when the pulse width exceeds the threshold value when the solenoid is not operating.

In the invention according to claim 3, the determination means sets the threshold longer than a predetermined set time when the pulse width of the digital signal exceeds the threshold and the IN signal is input. When the set time is changed and the pulse width exceeds the changed threshold value, the alarm command means outputs an alarm command signal. Furthermore, in the invention according to claim 5, the determination means sets the threshold value from a predetermined set time when a pulse signal is not output before a predetermined time has passed since the coin was last inserted. If the pulse width exceeds the changed threshold value, the alarm command means outputs an alarm command signal.

  As described above, when the solenoid is activated, the threshold value is changed to a set time longer than the predetermined set time, and an alarm is issued when the pulse width exceeds the changed threshold value. You may make it do.

  The invention described in claim 6 relates to a credit monitoring device used in the credit monitoring system described in claims 1 to 5. By attaching such a credit monitoring device to each slot game machine, a credit monitoring system can be configured and the above effects can be obtained.

  In addition, the code | symbol in the bracket | parenthesis of each said means shows the correspondence with the specific means as described in embodiment mentioned later.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, the same or equivalent parts are denoted by the same reference numerals in the drawings.

(First embodiment)
A schematic configuration of a credit monitoring system to which an embodiment of the present invention is applied is shown in FIG. Hereinafter, the configuration of the credit monitoring system will be described with reference to FIG.

  The credit monitoring system includes a slot gaming machine 1 installed in a pachinko hall, a passage sensor 2 and a current sensor 3 attached in the vicinity of the coin slot 1a of each slot gaming machine 1, a credit monitoring board 4, a number The lamp 5 and the hall computer 6 are provided. Among these, the current sensor 3 and the credit monitoring board 4 correspond to the credit monitoring device according to the present invention.

  The slot gaming machine 1 is provided with, for example, each board (central management board) attached to each slot gaming machine 1, and from each 6P information output 1b serving as an output terminal of each board, each slot gaming machine 1 Various signals indicating common information such as information on the number of IN and OUT, as well as jackpot information, jackpot information, challenge time (CT) information, and the like are output.

  The passage sensor 2 is used for counting credits. When a coin is inserted from a coin insertion slot provided in each slot game machine 1, the coin passes through the signal line 2a every time the coin passes. The pulse signal (detection signal) shown is output to each substrate. Each base board obtains information on the number of IN by detecting the number of pulses of the pulse signal. For example, the passage sensor 2 emits infrared rays from the light emitting portion, and when the reflected light of the infrared rays is received by the light receiving portion, a pulse signal is output, and the counter is counted up on each base substrate side. Yes. That is, when the coin passes, the infrared light emitted from the light emitting part is reflected on the coin surface, and the reflected light is received by the light receiving part to detect that the coin has passed.

  The current sensor 3 is connected to a signal line 2 a of the passage sensor 2, that is, a line that outputs a detection signal, takes in the detection signal of the passage sensor 2, and outputs it to the credit monitoring board 4. The current sensor 3 can detect the state of the pulse signal output from the passage sensor 2. As the current sensor 3, various well-known ones can be applied. For example, when a current flows through the signal line 2 a of the passage sensor 2, the passage sensor 2 is based on a magnetic variation caused thereby. It is possible to use a Hall element type current sensor that senses that a current has passed through the signal line. The output waveform of the current sensor 3 basically corresponds to the current waveform flowing in the signal line 2a of the passage sensor 2, but from the relationship of responsiveness, the output waveform of the current sensor 3 is moderate to the current waveform flowing in the signal line 2a of the passage sensor 2. It becomes a waveform that follows.

  The credit monitoring board 4 detects the fraud by monitoring the credit based on the output signal from the current sensor 3 and the signal obtained from the 6P information output 1b of the slot gaming machine 1, and the fraud is detected. The number lamp 5 is sometimes used to give an alarm. Since this credit monitoring board 4 is connected to the 6P information output 1b in the slot gaming machine 1, it also plays a role of transmitting information obtained from the 6P information output 1b of the slot gaming machine 1 to the hall computer 6 side. ing.

  Each terminal of the credit monitoring board 4 includes a sensor signal input terminal 4a, an alarm output terminal 4b, a reset input terminal 4c, a 6P information input terminal 4d, a 6P information output terminal 4e, a power input terminal 4f and a DIP input from the current sensor 3. Each terminal 4g is configured to be connected to each part of an electric circuit provided in the credit monitoring board 4.

  FIG. 2 shows a circuit configuration of an electric circuit provided in the credit monitoring board 4.

  The credit monitoring board 4 includes a low-pass filter circuit 10, an amplifier circuit 11, a comparator circuit 12, a range conversion circuit 13, a PIC (microcomputer) 14, a regulator circuit 15, and the like.

  The low-pass filter circuit 10 cuts the high frequency component of the detection signal from the current sensor 3 input from the sensor signal input terminal 4a, extracts the low frequency component, and demodulates the analog signal. For example, the low-pass filter circuit 10 includes a resistor 10a and a capacitor 10b. When the resistor 10a is set to 10 kΩ and the capacitor 10b is set to 0.056 μF, for example, a time constant ω (= RC) = 0.56 ms. That is, the frequency is set to about 1.79 kHz so that signals having a frequency higher than 1.79 kHz can be removed. The low-pass filter circuit 10 can stabilize the detection signal of the current sensor 3 that is an analog value, and can extract an appropriate pulse signal waveform from which noise components and the like are removed.

  The amplifier circuit 11 is composed of a non-inverting amplifier, and amplifies the signal sent from the low-pass filter circuit 10 at a predetermined magnification. Specifically, the amplifier circuit 11 includes a fixed resistor 11a and a semi-fixed resistor 11b connected in series, a resistor 11c, and an operational amplifier 11d. When the resistance value of the combined resistance of the fixed resistor 11a and the semi-fixed resistor 11b is R1, and the resistance value of the resistor 11c is R2, the amplification factor is expressed as (R1 + R2) / R1, and thus each of the resistors 11a to 11c The amplification factor can be adjusted depending on the setting of the resistance value. In the present embodiment, adjustment is possible from a minimum of 900 times to a maximum of 10,000 times.

  The comparator circuit 12 is for comparing the detection signal amplified by the amplifier circuit 11 with an analog signal by comparing it with a predetermined reference voltage Vref, and the amplified pulse signal is higher than the reference voltage Vref. In this case, a high level output (about 5 V here) is output, and a low level output (about 0 V here) is output when the output is low. Here, as will be described later, the reference voltage Vref is set by dividing the predetermined voltage formed by the regulator circuit 15 by the fixed resistors 12a and 12b and the semi-fixed resistor 12c. In the comparator 12d, the amplified detection signal is input to the + side, and the reference voltage is input to the-side.

  The range conversion circuit 13 is for converting the detection signal digitally converted by the comparator circuit 12 through the photocoupler 13a into a 0V to 5V range. Specifically, the first PIN (that is, the positive terminal on the light emission side) of the photocoupler 13a is connected to the comparator circuit 12, and the second PIN (that is, the negative terminal on the light emission side) is connected to the GND. The third PIN (that is, the light receiving side output terminal) of the photocoupler 13a is connected to the PIC 14, and the fourth PIN (that is, the light receiving side input terminal) is connected to the 5V power source (Vcc). Accordingly, the range is converted from 0V to 5V from the fourth PIN so that 5V is output if the output of the comparator circuit 12 is high level (around 5V) and 0V is output if the output is low level (around 0V). It becomes possible. By performing such range conversion, the detection signal of the current sensor 3 is represented as a pulse signal having an accurate rectangular waveform.

  As described above, the detection signal of the current sensor 3 is subjected to signal processing by the low-pass filter circuit 10 to the range conversion circuit 13 and is output to the PIC 14.

  The PIC 14 is configured by a known microcomputer including a CPU, ROM, RAM, I / O, and the like, and detects fraud. In the PIC 14, in addition to the detection signal of the current sensor 3 after the signal processing described above, a signal indicating the number of INs obtained from the 6P information output 1b of the slot gaming machine 1 through the 6P information input terminal 4d (hereinafter referred to as IN signal). And a signal indicating the number of OUTs (hereinafter referred to as OUT signal), a signal indicating the on / off state of the reset switch 7 input via the reset input terminal 4c, and a signal input via the DIP input terminal 4g. Various setting signals from the DIPSW 8 are input.

  Specifically, among the 6 terminals of the 6P information input terminal 4d, the IN signal and the OUT signal input to the 1st PIN and the 2nd PIN are both 7th PIN of the PIC 14 through the photocouplers 16a and 16b. And PIN No. 8 are entered.

  Note that the remaining four terminals among the six terminals of the 6P information input terminal 4d are not used for detection of fraud, and are thus connected to the 6P information output terminal 4e side as they are. ing. Various information output from the 6P information output terminal 4e is input to the hall computer 6. In the hall computer 6, information on the number of INs and OUTs of each slot gaming machine 1, information on jackpots, Based on the small hit information and the like, each slot gaming machine 1 can be managed.

  The DIP input terminal 4g inputs data corresponding to the on / off state of each SW of the DIPSW 8 configured to include the first to third SWs to the PIC. For example, in the first SW of the DIPSW 8, the external output mode is switched, and when it is on, it is a one-shot output, and when it is off, it is a holding output. The length of the alarm command signal from the 17th PIN of the PIC 14 to be described later is set by the output according to the ON / OFF of the No. 1 SW, and the alarm command signal is output for 1 second at the time of one-shot output. In the hold output, the alarm command signal is set to be output until the reset switch 7 is pressed.

  In the second SW of DIPSW8, the abnormality recognition time is set, that is, the detection time for determining an abnormality is switched, and the time is set to 70 ms or more when turned on and 100 ms or more when turned off.

  In the third SW of the DIPSW 8, the use / non-use of the timing detection mode is set. When the switch is on, the mode using the timing detection is set. When the switch is off, the non-use mode is set.

  Specifically, the 1st to 3rd PINs of the DIP input terminal 4g are connected to the GND, and the 4th to 6th PINs are connected to the 9th to 11th PINs of the PIC14. Since each PIN on the PIC 14 side is pulled up internally, when the DIPSW 8 is turned on and each PIN on the PIC 14 side is connected to GND, the DIPSW 8 is turned off and the DIPSW 8 is turned off. Each PIN is set to a high level (5 V) when disconnected from GND.

  The reset input terminal 4c is input to the fourth PIN of the PIC 14, and inputs a reset signal to the PIC 14 when the reset switch 7 is pressed. When the reset switch 7 is pressed and a reset signal is input to the PIC 14 through the reset input terminal 4c, the output of the alarm command signal is stopped as described above.

  The 17th PIN of the PIC 14 is connected to the alarm output terminal 4b via the photocoupler 17. The PIN outputs an alarm output to report to the clerk in the pachinko hall that the fraud has been detected when the fraud is detected after the fraud detection processing based on the data processing of the PIC 14 is executed. An alarm command signal is output to the terminal 4b. Specifically, the first PIN of the photocoupler 17 is connected to the 5V power source, and the second PIN is connected to the PIC 14. The third and fourth PINs of the photocoupler 13a are connected to the alarm output terminal 4b. In such a configuration, the 17th PIN of the PIC 14 outputs a high level (5V) during normal times when no fraud is detected, and outputs a low level (0V) when an irregularity is detected. It has become. For this reason, since no current flows through the diode of the photocoupler 17 at normal times, no light is emitted, and the contact between the third PIN and the fourth PIN remains open. And the contact between PIN 4 and PIN4 are closed.

  Therefore, the conduction interruption state between the two terminals of the alarm output terminal 4b can be controlled based on the output of the 17th PIN of the PIC 14, and the energization state to the number lamp 5 can be controlled. . As a result, it is possible to control the energization of the number lamp 5 by closing the contact point between the third PIN and the fourth PIN of the photocoupler 17 in the event of an abnormality. The slot game machine 1 that is present is displayed.

  Note that the LED 18 is connected to the first PIN of the PIC 14, and when the PIV 14 confirms that the passing sensor 2 has reacted based on the detection signal from the current sensor 3 after the signal processing, the first PIN A predetermined voltage is output from the LED 18 so that the LED 18 emits light.

  The regulator circuit 15 converts, for example, a 12V DC power input from the power input terminal 4f into a 5V DC power, for example, by the three-terminal regulator 15a. Electric power is supplied to each part in the credit monitoring board 4 using a DC power source of 5 V formed by the regulator circuit 15.

  Specifically, the + terminal of the 12V power input terminal 4f is connected to the first PIN of the three-terminal regulator 15a, and the third PIN and the negative terminal of the power input terminal 4f are connected to GND. Thereby, the voltage is converted to 5 V by the three-terminal regulator 15a, and the converted voltage is output from the second terminal of the three-terminal regulator 15a.

  An LED 19 is connected to the regulator circuit 15, and the LED 19 emits light when 5 V is output from the second terminal of the three-terminal regulator 15 a.

  The credit monitoring system is configured as described above. The operation of the credit monitoring system configured as described above will be described.

  The credit monitoring system configured as described above is driven when each slot gaming machine 1 is used. Specifically, when a detection signal from the current sensor 3 is input to the credit monitoring board 4, the detection signal is subjected to signal processing through the low-pass filter circuit 10, the amplifier circuit 11, the comparator circuit 12, and the range conversion circuit 13. , Input to the PIC 14. At this time, the circuits 11 to 13 and the PIC 14 are driven based on power supply from a DC power source formed by the regulator circuit 15.

  On the other hand, the IN signal and the OUT signal of each slot gaming table 1 are input to the PIC 14 from the 6P information output 1b of each slot gaming table 1 through the 6P information input terminal 4d.

  Then, the PIC 14 detects fraud based on the detection signal from the current sensor 3 after the signal processing and the IN signal and the OUT signal of the slot game machine 1.

  FIG. 3 shows a flowchart of the fraud detection process executed by the PIC 14, and the fraud detection method will be described based on this figure. This fraud detection process is always executed when power is supplied to the credit monitoring board 4.

  First, in step 100, the reaction time of the passage sensor 2 is measured. The reaction time here indicates how long the passage sensor 2 outputs a signal indicating the passage of coins, and the signal processing of the current sensor 3 output according to the output of the passage sensor 2. It is obtained from a later detection signal and is obtained by measuring the pulse width of the detection signal.

  Here, FIG. 4 shows a waveform after signal processing is performed on the output of the current sensor 3 in a normal state when no fraud is performed and the current sensor 3 in an abnormal state when the fraud is performed. The waveform after signal processing of the output is shown. Also, in this figure, the output waveforms of the passage sensor 2 and the current sensor 3 in each case, the waveform when the output waveform of the current sensor 3 is amplified by the amplifier circuit 11, and the reference voltage Vref compared by the comparator circuit 12 are shown. Also show.

  When a coin is inserted from the coin insertion slot, no matter how fast the coin passes, it does not exceed a predetermined speed. Therefore, as shown in FIG. The output waveform is normal so that the insertion of coins can be confirmed. Similarly, the output waveform of the current sensor 3 has such a shape that an output is generated every time a pulse signal of the passage sensor 2 is generated.

  For this reason, even if the output of the current sensor 3 gradually decreases, it sufficiently decreases until the passage sensor 2 generates the next pulse signal. Therefore, even if the signal of the current sensor 3 is amplified by the amplifier circuit 11, it is small except when the pulse signal is output by the passage sensor 2, and does not exceed the reference voltage Vref. This is the same waveform as the output waveform. In this case, the pulse width is determined by a certain value (for example, 10 to 30 ms) and does not exceed the predetermined time.

  On the other hand, when an illegal act is performed, the number of times of infrared irradiation is about 30 times per second and the blinking cycle is very fast. Therefore, as shown in FIG. They become close to each other, and the output waveform of the current sensor 3 is connected for each infrared irradiation once. That is, since the passing sensor 2 outputs the next pulse signal before the output of the current sensor 3 sufficiently decreases, the output of the current sensor 3 does not decrease so much. For this reason, when the signal of the current sensor 3 is amplified by the amplifier circuit 11, the reference voltage Vref is exceeded during the reaction time of the passage sensor 2, and the output of the comparator circuit 12 has a pulse width exceeding the predetermined time (for example, 100 ms).

  Accordingly, in step 110, the threshold value is obtained in step 100 using a predetermined set time (for example, 70 ms) between the pulse width when the pulse width is a normal output waveform and the pulse width of the abnormal output waveform as a threshold value. It is determined whether or not the reaction time of the passage sensor 2 exceeds the threshold value. The set time at this time is determined by the switching state of the second SW of DIPSW8. If a negative determination is made in this step, it is determined that no fraud has been performed and the process returns to step 100. If the determination is affirmative, the process proceeds to step 120 assuming that there is a possibility that an illegal act has been performed.

  At this time, since the reaction time of the passage sensor 2 exceeds the predetermined time, a signal indicating that an illegal act is being performed may be output immediately. However, a solenoid is provided in the vicinity of the coin insertion slot, and the current sensor 3 sometimes picks up a signal (current) when the solenoid is driven. For this reason, when the condition is such that the solenoid operates, the threshold value is set to twice the set time to eliminate the influence of the operation of the solenoid.

Specifically, the solenoid operates at the last time when the interval is more than 1 second after the last insertion of the coin, and at the first time when the IN signal is raised. Therefore, at step 120, it is determined based on the output of the current sensor 3 whether or not the next passing signal has come within one second, and at the subsequent step 130, the IN signal is input. whether did Tei is adapted to be determined.

  If a negative determination is made in any one of these steps, the process proceeds to step 140, and it is determined whether or not the reaction time has exceeded twice the set time. If the determination in step 140 is affirmative, the process proceeds to step 150 on the assumption that the pulse width of the detection signal of the current sensor 3 has increased due to fraud regardless of whether or not the solenoid has an influence. An alarm command signal for performing an alarm is output. Conversely, if a negative determination is made in step 140, even if it is detected that the pulse width of the detection signal of the current sensor 3 is long and the reaction time of the passage sensor 2 is long, it is due to the influence of the solenoid. Returning to step 100 as it is.

In addition, when both of the above steps 120 and 130 are affirmed, it is not the timing to be affected by the solenoid, so if the reaction time exceeds the set time as described above, it is due to fraud. as a warning command signal is output to an alarm proceed to step 150.

  When a command signal for performing such an alarm is output, this output is output through the 17th PIN of the PIC 14. As a result, the photocoupler 17 brings the two terminals of the alarm output terminal 4b into a conductive state, and the number lamp 5 is energized. Is displayed. Therefore, a pachinko hall clerk can find an illegal act with the number lamp 5, and it becomes possible to suppress the illegal act, thereby preventing damage to the pachinko hall.

  According to the credit monitoring system of the present embodiment described above, the current sensor 3 is put on the signal line of the passage sensor 2 and the reaction time of the passage sensor 2 is detected based on the output of the current sensor 3. Then, when the reaction time of the passage sensor 2, that is, the pulse width of the digital signal after the signal processing of the current sensor 3, exceeds a predetermined threshold value, an abnormality in the output of the passage sensor 2 is detected. Yes.

  This makes it possible to detect fraud. Further, since the current sensor 3 is not directly attached to the signal line of the passage sensor 2, that is, the current sensor 3 is not directly attached to the slot game machine 1, something is directly attached to the slot game machine 1 itself. It is possible to detect fraud without performing legally regulated acts.

(Other embodiments)
In the above-described embodiment, a counting method is described in which credit is increased by reflecting infrared rays with coins. However, as a credit counting method in the slot game machine 1, credit is counted by utilizing the fact that the light from the infrared light emitting part is guided to the light receiving part by the U-shaped reflecting member and the infrared ray is blocked when the coin passes. As with the above, the present invention can also be applied to those performing up.

  Note that the steps shown in each figure correspond to means for executing various processes.

It is a figure which shows schematic structure of the credit monitoring system in 1st Embodiment of this invention. FIG. 4 is a diagram showing a part of a circuit configuration in a credit monitoring board 4. FIG. 4 is a diagram showing a part of a circuit configuration in a credit monitoring board 4. It is a flowchart of the fraud detection process which PIC performs. (A) is a waveform diagram showing a normal output waveform, (b) is a waveform diagram showing an abnormal output waveform.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Slot game stand, 2 ... Pass sensor, 3 ... Current sensor, 4 ... Credit monitoring board, 4a ... Sensor signal input terminal, 4ba ... Alarm output terminal, 4c ... Reset input terminal, 4d ... 6P information input terminal, 4e ... 6P information output terminal, 4f ... power input terminal, 4g ... DIP input terminal, 5 ... number lamp, 6 ... hall computer, 7 ... reset switch, 8 ... DIPSW.

Claims (6)

A slot gaming table (1) capable of playing games according to the number of coins inserted from the coin slot (1a);
A passage sensor (2) provided in the slot game machine and outputting a pulse signal through a signal line in accordance with the passage of the coin;
A current sensor (3) connected to the signal line of the passage sensor and sensing an output current of the passage sensor flowing in the signal line and outputting an analog signal;
Conversion means (12) for converting the analog signal into a digital signal by comparing the analog signal with a predetermined reference value;
By setting a predetermined set time as a threshold value, and determining whether or not the pulse width of the digital signal obtained by converting the analog signal output from the current sensor by the converting means exceeds the threshold value, Determination means (110) for determining an abnormal waveform of the pulse signal output from the passage sensor;
An alarm command means (150) for outputting an alarm command signal for issuing an alarm when the determination means determines that the pulse width of the digital signal exceeds the threshold;
A credit monitoring system comprising alarm means (5) for receiving an alarm command signal from the alarm instruction means and issuing an alarm. The determination means obtains an IN signal indicating the number of inserted coins from the slot game machine, and the IN signal is input when the pulse width of the digital signal exceeds the threshold value. 2. The credit monitoring system according to claim 1, wherein if there is not, the alarm command means is configured to output the alarm command signal. The determination means changes the threshold to a set time longer than the predetermined set time when the pulse width of the digital signal exceeds the threshold and the IN signal is input. The alarm command signal is output from the alarm command means when the pulse width of the digital signal exceeds the changed threshold value. Credit monitoring system. Said determination means, predetermined from the time when the digital signal obtained by converting the analog signal in which the current sensor outputs by said converting means is interrupted coin as it last turned該Ko-in was last turned before the time becomes available, pre Kide digital signal is controlled so as to determine whether showed the following pulse, when the pulse width of the digital signal exceeds the said threshold, said predetermined time The alarm command signal is output from the alarm command means when the digital signal indicates the next pulse before the signal becomes empty. Credit monitoring system as described in. The determination unit, when the digital signal before said predetermined time is free from the time the coin was last turned did not been shown the next pulse, than the threshold the predetermined set time When changing to a long setting time and the pulse width of the digital signal exceeds the changed threshold value, the alarm command signal is output to the alarm command means. The credit monitoring system according to claim 4. A slot that measures the number of coins inserted according to the output from the passage sensor (2) that outputs a pulse signal through the signal line when a coin is inserted from the coin insertion slot (1a). A current sensor (3) connected to the signal line of the game machine (1) and outputting an analog signal corresponding to the output current of the passing sensor flowing in the signal line;
Conversion means (12) for converting the analog signal into a digital signal by comparing the analog signal with a predetermined reference value;
By setting a predetermined set time as a threshold value, and determining whether or not the pulse width of the digital signal obtained by converting the analog signal output from the current sensor by the converting means exceeds the threshold value, Determination means (110) for determining an abnormal waveform of the pulse signal output from the passage sensor;
An alarm command means (150) for outputting an alarm command signal for performing an alarm when the determination means determines that the pulse width of the digital signal exceeds the threshold value; A credit monitoring device.

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