JP5458502B2 - Magnetic detector installed in pachinko machines - Google Patents

Description

  The present invention relates to a magnetic detection device using a magnetic impedance element, and more particularly to a magnetic detection device mounted on a pachinko gaming machine.

Examples of an element (hereinafter referred to as a magnetic impedance element) used in a magnetic detection device mounted on a conventional pachinko machine include a reed switch disclosed in Patent Document 1 and a Hall element disclosed in Patent Document 2. . These magnetic detectors are used to find magnets that allow illegal pachinko ball winning.
On the other hand, there is also a fraud in which a gaming machine malfunctions due to radio waves, and an illegal prize ball is obtained.

Japanese Patent Laid-Open No. 5-212152 JP 2007-209592

  The purpose of the present invention is not only to detect magnets for unauthorized use of pachinko machines, but also to detect unauthorized use of radio waves, and to prevent unauthorized use of radio waves from general wireless devices such as mobile phones that are not intended for unauthorized use. The purpose is to prevent it from being used.

  In order to achieve the above object, according to a first aspect of the present invention, there is provided at least two magnetic impedance elements for detecting magnetism on a front surface side of a windshield of a pachinko gaming machine, and an output of the magnetic impedance element A processing unit for detecting the presence or absence of unauthorized use of the pachinko gaming machine by comparing the amplitude value of the signal with a predetermined threshold, and the processing unit is used for magnetic detection to detect magnetism as the predetermined threshold. Magnetics installed in pachinko machines, which use a threshold and a threshold for detecting radio waves to detect radio waves as well as unauthorized use by radio waves. It is a detection device.

  According to a second aspect of the present invention, there is provided a comparison for comparing a signal obtained by A / D converting an analog signal obtained from at least two magnetoimpedance elements for detecting magnetism with a predetermined threshold value. A magnetic sensing device comprising: a storage unit for storing the predetermined threshold value; a processing unit for calculating a comparison result in the comparison unit; and an output unit for outputting a calculation result by the processing unit The memory unit stores a magnetic detection threshold value for detecting magnetism and a radio wave detection threshold value for detecting radio waves. Device.

  According to the third aspect of the present invention, the radio wave detection means for increasing the amplitude of the output signal of the analog output unit that changes due to the arrival of radio waves is connected to the line between the analog output unit and the A / D conversion unit. Yes.

  According to the fourth aspect of the present invention, the radio wave detecting means is a coil.

  According to the fifth aspect of the present invention, the magneto-impedance element and the analog output unit are mounted on a single module.

  According to the sixth aspect of the present invention, the processing unit is configured such that the output from the comparison unit includes all the A / D conversion values of the output signals of the at least two magnetic impedance elements by the A / D conversion unit. If it indicates that the value is greater than the value, or if the A / D conversion values of the output signals of at least two magneto-impedance elements are all less than the magnetic detection threshold, The threshold is used to determine whether the magnet is illegally used or the radio wave is illegally used, and one of the A / D conversion values of the output signals of the output signals of at least two magnetic impedance elements is the threshold for magnetic detection. When it is indicated that the other is larger than the value and smaller than the magnetic detection threshold, it is determined whether or not the magnet is illegally used by using the magnetic detection threshold.

  According to the seventh aspect of the present invention, the magneto-impedance element is installed in parallel to the windshield surface of the pachinko gaming machine.

  According to the eighth aspect of the present invention, the absolute value of the radio wave detection threshold value includes the absolute value of the magnetic detection threshold value and the magneto-impedance element by a general radio device not intended for unauthorized use of a pachinko gaming machine. Is larger than the absolute value of the output voltage of the magnetic impedance element, and smaller than the absolute value of the output voltage of the magneto-impedance element by the radio for the purpose of illegal use of the pachinko gaming machine.

According to the present invention, in a magnetic detection device having at least two or more magneto-impedance elements, a magnetic detection threshold value for detecting an illegal magnet and a radio wave detection threshold value for detecting the arrival of a radio wave are provided. By setting and processing the analog change of the magnetoresistive element, the following effects can be obtained in the pachinko gaming machine.
(1) With the detection unit having the minimum configuration necessary for magnetic detection, it is possible to take countermeasures against two types of unauthorized use, that is, unauthorized use by a magnet of a pachinko machine and unauthorized use by radio waves.
(2) Since it can be determined whether the analog change of the magneto-impedance element is due to a magnet or due to radio waves, it is possible to determine what unauthorized use the pachinko gaming machine is.
(3) It is possible to prevent a user of a general wireless device from improperly using a pachinko gaming machine by preventing magnetic detection by radio waves from a general wireless device not intended for unauthorized use such as a mobile phone. .

Embodiments of the present invention will be described below in detail with reference to the drawings. Throughout the drawings, the same reference numerals denote the same parts.
FIG. 1 is a block diagram showing a configuration of a magnetic detection device mounted on a pachinko gaming machine according to the first embodiment of the present invention. In FIG. 1, the magnetic detection device 1 includes a module 11 and a microcomputer 12.

  The module 11 includes a magnetic impedance element (X) 111, a magnetic impedance element (Y) 112, an analog output unit (X) 113 that amplifies an analog signal output from the magnetic impedance element (X) 111, and outputs a magnetic signal. And an analog output unit (Y) 114 that amplifies and outputs the analog signal output from the impedance element (Y) 112.

  The microcomputer 12 is output from the analog output unit (X) 121 for converting the analog signal output from the analog output unit (X) 113 of the module 11 into a digital signal and the analog output unit (Y) 114. An A / D converter (Y) 122 for converting an analog signal into a digital signal; a comparator (X) 123 that compares an output signal from the A / D converter (X) 121 with a predetermined threshold; Comparison unit (Y) 124 that compares an output signal from A / D conversion unit (Y) 122 with a predetermined threshold value, and threshold values for magnetic detection and radio wave detection that are the predetermined threshold values A first processing unit 126 that performs a first process (detailed later) of the results obtained by the comparison unit (X) 123 and the comparison unit (Y) 124, and a first processing unit Depending on the processing result of 126, the second processing (after A second processing unit 127 for the elaborating), and an output unit 128 for outputting an output process which is the result of the first processing unit 126 and the second processing section 127. By using the magnetic detection threshold and the radio wave detection threshold, the output unit 128 outputs a magnetic detection output or a radio wave detection output.

  A radio wave detection coil 13 may be connected between the analog output unit (X) 113 and the A / D conversion unit (X) 121. The coil 13 serves as an antenna. Reference numeral 14 denotes a capacitor for adjusting a frequency at which reception sensitivity is maximized. Since the amplitude of the output signal of the analog output unit (X) 113 is increased by connecting the coil 13, the reception sensitivity of the radio wave can be adjusted by the coil 13.

  The storage unit 125 stores the threshold value for magnetic detection and the threshold value for radio wave detection, and voltage values (magnets and radio waves) within a specified range necessary for initial setting processing of those threshold values described in FIG. (A digital voltage value corresponding to the output voltage of the magneto-impedance element in the state where there is no influence of the above).

  The magnetic impedance element (X) 111 and the magnetic impedance element (Y) 112 are disposed substantially at an angle of 90 ° substantially parallel to the surface of the windshield of the pachinko gaming machine.

  FIG. 2 is a block diagram showing a configuration of a magnetic detection device mounted on a pachinko gaming machine according to the second embodiment of the present invention. 2, the same parts as those in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted. In FIG. 2, the magnetic detection device 2 includes a module 21 and a microcomputer 22.

  The module 21 switches the output of the magnetic impedance element (X) 111 and the magnetic impedance element (Y) 112 in accordance with a switching signal output from the microcomputer 22 and outputs it from the switching unit 211. And an analog output unit 212 that amplifies and outputs the output of the time-switched magneto-impedance element.

The microcomputer 22 includes a switching output unit 221 that outputs a switching signal to the switching unit 211 in the module 21, and an A / D conversion unit 222 that converts an analog signal output from the analog output unit 212 of the module 21 into a digital signal. A comparator 223 that compares the amplitude of the output signal from the A / D converter 222 with a predetermined threshold value, and stores a magnetic detection threshold value and a radio wave detection threshold value that are the predetermined threshold values. While comparing the output amplitude of the storage unit 224 and the output amplitude of one of the magnetic impedance elements with a predetermined threshold value, the comparison result immediately before the predetermined threshold value of the output amplitude of the other magnetic impedance element is stored. a storage unit 225 which are obtained by the comparison unit 223, a first processing unit 126 to the first processing result stored in the storage unit 225 (to be described later), the first processing unit 126 A second processing unit 127 that performs second processing (to be described in detail later) according to the processing result; and an output unit 128 that outputs processing results that are outputs of the first processing unit 126 and the second processing unit 127. ing. The storage unit 224 also stores a specified voltage range necessary for the threshold initial setting process described with reference to FIG. By using the magnetic detection threshold value and the radio wave detection threshold value, the output unit 128 outputs a magnetic detection output or a radio wave detection output as in the case of FIG. When the output of the switching output unit 221 is high (H) level, the switching unit 211 enables the output of the magnetic impedance element (X) 111, and when the output is low (L) level, the output of the magnetic impedance element (Y) 112 is output. To enable.

  The radio wave detection coil 13 may be connected between the analog output unit 212 and the A / D conversion unit 222 as in FIG. An antenna may be connected instead of the coil 13. Reference numeral 14 denotes an AC grounding capacitor.

  The switching signal output from the switching output unit 221 is a signal for switching and outputting the output of the magnetic impedance element to be used by the switching unit 211. By synchronizing the operations of the analog output unit 212 and the storage unit 224, the output of the magneto-impedance element (X) 111 is compared with the threshold value as shown in FIG. Can be realized by a single A / D converter 222 and a single comparator 223.

  In the embodiment shown in FIG. 2, the magnetic sensing device is equivalent to using two magneto-impedance elements simultaneously as shown in FIG. 1 by instantaneously switching two magneto-impedance elements having different sensing areas. A detection area can be secured.

  The module itself shown in FIGS. 1 and 2 is commercially available.

FIG. 3 is an exploded perspective view of a module in which the magnetic detection device shown in FIG. 1 or 2 is integrated. In FIG. 3, 31 is a case , 32 is a module, 33 is a microcomputer, 34 is a circuit board, 35 is a connector, and 36 is a cover that covers the connector 35. The module 32 and the microcomputer 33 are mounted on the same circuit board 34. The magnetic detection device is integrated by covering the circuit board 34 on which the module 32 and the microcomputer 33 are mounted with the case 31 and covering the connector 35 with the cover 36. The module 32 and the microcomputer 33 may be the module 11 and the microcomputer 12 shown in FIG. 1 or the module 21 and the microcomputer 22 shown in FIG. In the following description, the magnetic detection apparatus shown in FIG. 1 is used.

  As shown in FIG. 3, the circuit board 34 on which at least the module 32 and the microcomputer 33 are mounted is housed inside the case 31 and the cover 36.

  4A is a front view of a pachinko gaming machine to which a magnetic detection device according to the present invention is attached, and FIG. 4B is an enlarged cross-sectional view taken along line AA of FIG. 4A and 4B, reference numeral 41 denotes a pachinko gaming machine, 42 denotes a windshield on the surface of the pachinko gaming machine 41, 43 denotes a board surface of the pachinko gaming machine 41, and 44 denotes a pachinko game on the front side of the windshield 42. A magnet placed for the purpose of unauthorized use of the machine. On the back side of the panel surface 43, the magnetic detection device 1 shown in FIG. As shown, at least the upper surface of the package of the module 32 is parallel to the surface of the windshield 42 of the gaming machine, that is, the magnetic impedance element (X) 111 and the magnetic impedance element (Y) 112 in the module 32 are front. The magnetic detection device 1 is installed behind the panel surface 43 so as to be parallel to the surface of the glass 42. Thereby, the area | region which can detect the magnet 44 becomes the maximum.

  FIG. 5 is a diagram showing an image of a detection region of magnetism from the magnet 44 on the surface of the windshield 42 of the pachinko gaming machine when the magnetic detection device 1 is attached as shown in FIG. Since the angle between the magnetic impedance element (X) 111 and the magnetic impedance element (Y) 112 is approximately 90 °, the detection region has directivity. In the figure, the dotted elliptical area indicates the magnetic detection area from the magnet 44 by the magnetic impedance element (X) 111, and the solid elliptical area indicates the magnetic detection area from the magnet 44 by the magnetic impedance element (Y) 112. Show. It is assumed that the magnet 44 moves along the locus (1) to (5) in the direction indicated by the dotted line. Then, in the hatched portion in the figure, both the outputs of the magnetic impedance element (X) 111 and the magnetic impedance element (Y) 112 can be detected, but in the other areas, the magnetic impedance element (X) 111 and the magnetic impedance element ( Y) Only the output from either one of 112 can be detected.

  FIG. 6 is a graph showing the relationship between the output of the magneto-impedance element and the output of the comparison unit when the magnet 44 moves along the locus (1) to (5) in the detection region on the windshield as shown in FIG. (A) is a graph showing a change in the analog output signal of the magnetic impedance element (X) 111, (B) is a graph showing a change in the analog output signal of the magnetic impedance element (Y) 112, and (C). Is a graph showing a digital output waveform of the comparison unit 123 in the microcomputer 12, (D) is a graph showing a digital output waveform of the comparison unit 124 in the microcomputer 12, and (E) is an output waveform of the first processing unit 126. FIG. The magnet placed its north pole at the beginning in the direction of movement. When the S pole is moved at the head in the moving direction, the signs are reversed from those in the graphs of FIGS. 6A and 6B.

  It is known that the output amplitude of the magneto-impedance element changes as it rises and falls as shown in FIGS. 6A and 6B when the magnet is not approaching due to the approach of the magnet. It has been. In FIGS. 6A and 6B, the maximum value and the minimum value are constant because of the characteristic of the magneto-impedance element, no more or less voltage is output. Because. When the threshold value for magnetic detection is Vx1, Vx2 for the magnetic impedance element (X) 111 and Vy1, Vy2 for the magnetic impedance element (Y) 112, the analog output voltage value of the magnetic impedance element is Vx1, respectively. The magnet is detected when Vy1 is exceeded or when Vx2 and Vy2 are below. In FIG. 6C, it is detected that the magnet 44 approaches the magneto-impedance element (X) 111 between the positions P1 and P2 and between P3 and P4. In FIG. Is detected that the magnet 44 approaches the magneto-impedance element (Y) 112 between the positions P6 and P7 and between P8 and P9. In FIG. 6E, the logical sum of the output of the comparison unit (X) 123 and the output of the comparison unit (Y) 124 is calculated and output by the first processing unit 126. In this case, it is detected that the magnet 44 approaches the magnetic impedance element (X) 111 or the magnetic impedance element (Y) 112 after the position P1.

  FIG. 7 is a graph showing the relationship between the output of the magneto-impedance element and the output of the comparison unit when radio waves arrive at the magnetic sensing device, and (A) shows the change in the analog output signal of the magneto-impedance element (X) 111. (B) is a graph showing the change in the analog output signal of the magnetic impedance element (Y) 112, (C) is a graph showing the digital output waveform of the comparison unit 123 in the microcomputer 12, and (D). Is a graph showing the digital output waveform of the comparison unit 124 in the microcomputer 12, and (E) is a graph showing the output waveform of the first processing unit 126.

  Radio waves have the characteristics of both “electric field” and “magnetic field” due to their characteristics. Therefore, there is a possibility that powerful radio waves may be used for illegal use of pachinko gaming machines as well as magnets. Therefore, in the present invention, not only magnets but also strong radio waves can be detected. However, if the threshold value is the same as that shown in FIG. 6, as shown in FIG. 7, the radio wave of a general radio such as a mobile phone having a weak radio wave intensity is also detected. Even if the user of the machine does not use it illegally, it may be judged as unauthorized use.

  That is, as shown in (C), (D), and (E) of FIG. 7, an illegal radio wave having a strong radio field intensity is detected between time t1 and t2, but the radio wave intensity is detected between time t3 and t4. Radio waves from weak general radios are also detected.

  Therefore, in the embodiment of the present invention, the radio wave detection threshold value is used separately from the magnetic detection threshold value, and illegal radio waves are detected separately from the magnetism detection by the magnet. Hereinafter, signal processing that can distinguish between “illegal magnets” and “illegal radio waves” will be described.

FIG. 8 is a diagram for explaining the operation of the comparison unit (X) 123 and the comparison unit (Y) 124 when only the magnet detection threshold is used. When the magnetic detection device mounted on the pachinko gaming machine detects radio waves, the outputs of the comparison unit (X) 123 and the comparison unit (Y) 124 are both H or L. This is because, in general, radio waves tend to be non-directional compared to magnets, and are detected by the magnetic impedance element (X) 111 and the magnetic impedance element (Y) 112 together. On the other hand, since the magnet has sharper directivity than radio waves, the output of the comparison unit corresponding to one of the magnetic impedance element (X) 111 and the magnetic impedance element (Y) 112 becomes H or L, and the other is N (not detected), or both comparator outputs are both H or L. Therefore, when only one of the outputs of the comparison unit (X) 123 and the comparison unit (Y) 124 is in the detection state (H or L), it can be reliably determined that the change is caused by the magnet. Therefore, when one of the outputs of the comparison unit (X) 123 and the comparison unit (Y) 124 is in the detection state, it is determined that the magnet is detected, and when both are in the non-detection state (N). that is both determined not to have a detection radio wave magnet, (the H or L) both the comparator output detection state of when a is determined either "bad magnet" and "Telecommunications" It is divided into three states. The processing so far is referred to as processing 1, and the processing is performed by the first processing unit 126 in FIG.

  FIG. 9 shows the magnetic impedance element (X) 111 and the magnetic impedance when radio wave detection thresholds Va1, Va2, Vb1, and Vb2 are provided in addition to the magnetic detection thresholds Vx1, Vx2, Vy1, and Vy2. It is a graph which shows the relationship between the state obtained from an element (Y) 112, a magnetic detection output, and an electromagnetic wave detection output.

  9A is a graph showing a change in the analog output signal of the magnetic impedance element (X) 111, FIG. 9B is a graph showing a change in the analog output signal of the magnetic impedance element (Y) 112, and FIG. Is a graph showing digital output waveforms of the comparison unit (X) 123 and comparison unit (Y) 124 in the microcomputer 12 when the magnetic detection threshold values Vx1, Vx2, Vy1, and Vy2 are used, and (D) is a radio wave. The graph which shows the digital output waveform of the comparison part (X) 123 and the comparison part (Y) 124 in the microcomputer 12 when threshold value for detection Va1, Va2, Vb1, Vb2 is used, (E) is for magnetic detection The area which cannot be processed when only the threshold value is used is shown, and (F) is a graph showing the magnetic detection output by the magnet when the magnetic detection threshold value and the radio wave detection threshold value are used. G) is a graph showing the radio wave detection output when a magnetic detection threshold and wave detection threshold. In all of (A) to (E) in FIG. 9, the horizontal axis indicates time, and the vertical axis indicates voltage value.

  When the magnets 44 are present in the detection region (shaded area in FIG. 5) where the directivities of the magnetic impedance element (X) 111 and the magnetic impedance element (Y) 112 match, the analog output voltage of each magnetic impedance element is They match (become detected at the same time). However, due to the directivity of the magnetic impedance, the analog output voltage of the magneto-impedance element in the matching detection area is the minimum value in the detection area, so the analog voltage of each magneto-impedance element does not saturate and is illegal. It becomes smaller than the analog voltage of the magneto-impedance element that changes due to various radio waves. Focusing on this fact, according to the embodiment of the present invention, the electromagnetic impedance element (X) 111 is provided with illegal radio wave detection thresholds Va1 and Va2, and the magnetic impedance element (Y) 112 is illegal. Threshold values Vb1 and Vb2 for detecting radio waves are provided. The radio wave detection threshold values were set to Va1> Vx1, Va2 <Vx2, Vb1> Vy1, and Vb2 <Vy2. However, the absolute values of Va1, Va2, Vb1, and Vb2 are based on the absolute value of the magnetic detection threshold value and the absolute value of the output voltage of the magnetic impedance element by a general radio device that is not intended for unauthorized use of pachinko gaming machines. It is a large value and a value smaller than the absolute value of the output voltage of the magneto-impedance element by the radio device intended for unauthorized use.

  In (A) of FIG. 9, (2) and (3) are described assuming that the magnet 44 moves from the region (2) to (3) in FIG. Yes. The time t0 is the measurement start time of the output voltage of the magneto-impedance element, the time t1 is the time when the analog output voltage of the magneto-impedance element (X) 111 decreases, and the time t2 coincides with the radio wave detection threshold value Va1, and the time t2 is the magneto-impedance element ( X) The time when the analog output voltage of 111 decreases, and the time t3 coincides with the magnetic detection threshold Vx1 when the analog output voltage of the magnetic impedance element (X) 111 decreases. , Time t4 coincides with the radio wave detection threshold Va2 when the analog output voltage of the magnetic impedance element (X) 111 is lowered, and time t5 is for radio wave detection when the analog output voltage of the magnetic impedance element (X) 111 is increased. At time t6, which coincides with the threshold value Va2, the impedance of the magneto-impedance element (X) 111 is The time when the log output voltage rises coincides with the magnetic detection threshold value Vx2, the time t7 is the time when the analog output voltage of the magneto-impedance element (X) 111 rises due to the reception of unauthorized radio waves, and the time t8 is the time when unauthorized radio waves are transmitted. The time when the analog output voltage of the gas impedance element (X) 111 decreases due to the end of reception, t9 is the time when the analog output voltage of the magnetic impedance element (X) 111 increases due to radio waves from a general radio, and t10 is general This is the time when the analog output voltage of the magnetic impedance element (X) 111 is lowered due to the end of reception of radio waves from the radio.

  In FIG. 9B, time t11 is the time when the analog output voltage of the magnetic impedance element (Y) 112 rises and coincides with the magnetic detection threshold Vy1, and time t12 is the analog output of the magnetic impedance element (Y) 112. Time when the voltage rises coincides with the radio wave detection threshold Vb1, time t13 coincides with the radio wave detection threshold Vb1 when the analog output voltage of the magnetic impedance element (Y) 112 falls, and time t14 coincides with the magnetic impedance. The time coincides with the magnetic detection threshold value Vy1 when the analog output voltage of the element (Y) 112 drops. From time t7 to t10, the output of the magnetic impedance element (Y) 112 moves in the same manner as the output of the magnetic impedance element (X) 111 because it is affected by radio waves.

  In FIG. 9C, the output of the comparison unit (X) 123 when compared with the magnetic detection threshold is H level from time t0 to t2, N (non-detection) from time t2 to t3, L from time t3 to t6, N (not detected) from time t6 to t7, H level from time t7 to t8, N (not detected) from time t8 to t9, H level from t9 to t10, After t10, N (non-detection).

  The output of the comparison unit (Y) 124 when compared with the magnetic detection threshold is N (non-detection) from time t0 to t11, H level from t11 to t14, and N (from t14 to t7. (Not detected), and after t7, is the same as the output of the magnetic impedance element (X) 111.

  In FIG. 9D, the output of the comparison unit (X) 123 when compared with the radio wave detection threshold is H level from time t0 to t1, N (non-detection) from time t1 to t4, From t4 to t5 is L level, from t5 to t7 is N (not detected), from t7 to t8 is H level, and after t8 is N (not detected).

  The output of the comparison unit (Y) 124 when compared with the radio wave detection threshold is N (not detected) from time t0 to t12, H level from t12 to t13, and N (from t13 to t7. (Not detected) and after t7 are the same as the output of the comparison unit (X) 123.

  In FIG. 9E, the time zone in which both the output of the comparison unit (X) 123 and the output of the comparison unit (Y) 124 are H level when compared with the magnetic detection threshold value is indicated by hatching. It is. In the illustrated example, between t11 and t2, between t7 and t8, and between t9 and t10, the output of the comparison unit (X) 123 and the output of the comparison unit (Y) 124 when compared with the magnetic detection threshold value. Both of them are at the H level, and in these time periods, the illegal use of the pachinko gaming machine can be detected, but it cannot be determined whether the illegal use is due to the magnet or the radio wave.

  Therefore, for the above-described time period, the second processing unit 127 executes process 2 to determine whether unauthorized use is due to radio waves or magnets.

  As shown in FIG. 9F, from time t0 to time t6, at least one of the outputs of the comparison unit (X) 123 and the comparison unit (Y) 124 by the comparison with the magnetic detection threshold value by the process 1 is Since it is H level or L level, and neither of the outputs of the comparison unit (X) 123 and the comparison unit (Y) 124 by comparison with the radio wave detection threshold value in process 2 is at the H or L level, it is illegal. Use is determined to be by magnet.

Also, as shown in FIG. 9G, between the times t7 and t8, both the comparison unit (X) 123 and the comparison unit (Y) 124 are compared with the magnetic detection threshold value by the process 1. has become H level, since a comparison unit (X) 123 and none of the output of the comparator unit (Y) 124 H by comparison with wave detection threshold by processing 2, by abuse Telecommunications It is determined.

  When the output voltage of the magneto-impedance element due to unauthorized radio waves is lower than the output voltage of the magneto-impedance element due to the magnet, the radio wave detection coil 13 serving as an antenna is connected to the analog output section (X) 113 as shown in FIG. If the absolute value of the output voltage of the magneto-impedance element due to unauthorized radio waves is made higher than the absolute value of the output voltage of the magneto-impedance element due to the magnet by connecting to the line between the A / D converter (X) 121, It is possible to detect unauthorized radio waves.

  FIG. 10 shows processing when the outputs of the comparison unit (X) 123 and the comparison unit (Y) 124 are both in the detection state (both H level or both L level) as shown in FIG. It is a figure which shows 2 (process when it cannot process by the process 1). At this time, both the comparison unit (X) 123 and the comparison unit (Y) 124 are output by unauthorized radio waves when both outputs become H level or both L level with reference to the radio wave detection threshold value. It is determined that the other is due to an illegal magnet. In FIG. 10, a state in which only one of the output of the comparison unit (X) 123 and the output of the comparison unit (Y) 124 is at H level or L level is not possible in radio wave detection, so both outputs are at H level. Or when both outputs are at L level, it is determined that unauthorized use by radio waves has been made. When both outputs are N (non-detection), it is not determined to be unauthorized use.

FIG. 11 is a flowchart for explaining the main processing by the magnetic detection apparatus shown in FIG. In FIG. 11 , in step S111, turning on the power to the magnetic detection device is a start condition of the main process. In step S112 after the power is turned on, a threshold setting process for generating a magnet detection threshold and a radio wave detection threshold and storing them in the storage unit 125 is performed. After each threshold setting is completed normally, in step S113, an analog signal output from the module 11 and comparison and calculation processing in the microcomputer 12 are performed in order to detect an illegal magnet or radio wave. The main process ends when a power supply drop is detected in step S114.

  FIG. 12 is a flowchart for explaining the details of the threshold setting process in step S112 of FIG. In FIG. 12, the analog output signal from the magnetic impedance element (X) 111 is A / D converted by the A / D converter (X) 121 in step S121, and then in step S122, the comparator (X) 123 is converted. Thus, a comparison process is performed to confirm that the magnetic detection device is not affected by magnetism. In this comparison process, a comparison reference (hereinafter referred to as a specified voltage) is set based on a voltage standard when the module 11 is not receiving a magnetic field from an illegal magnet. Next, in step S123, it is determined whether or not the voltage input to the comparison unit (X) 123 is within a specified voltage range. If it is out of the specified voltage range, in step S124, the comparator (X) 123 continuously outputs a pulse to notify the outside that the threshold value could not be normally generated. If it is within the specified voltage, it is considered that the threshold value has been generated normally, the process proceeds to step S125, the threshold value in the comparison unit (X) 123 relating to the magnetic impedance element (X) 111 is updated, and the storage unit The data is saved in 125 and the process is terminated.

  For the output of the magneto-impedance element (Y) 112, the same processing is performed in steps S126 to S129 to set a threshold value.

  FIG. 13 is a flowchart for explaining threshold setting processing in the magnetic detection apparatus shown in FIG. 13, basically the same processing as that shown in FIGS. 11 and 12 is performed. In FIG. 13, after turning on the power in step S1301, in step S1302, the switching output unit 221 in the microcomputer 22 outputs an H signal to the switching unit 211 so that only the magnetic impedance element X can be used. In step S1303, the analog output signal of the module 21 is A / D converted. In step S1304, a comparison process is performed. In step S1305, it is determined whether the input voltage of the comparison unit 223 is within the specified voltage. If the input voltage is outside the specified voltage, in order to notify that the threshold value cannot be normally set in step S1306, Generate a pulse. If the voltage is within the specified voltage, the threshold value for the magnetic impedance element (X) 111 is updated and stored in the storage unit 224 in step S1307. Next, the same processing is performed for the magnetic impedance element (Y) 112 in steps S1308 to S1313.

  FIG. 14 is a flowchart for explaining the operation of the microcomputer 12 in the magnetic detection apparatus shown in FIG. In FIG. 14, the output of the magnetic impedance element (X) 111 is converted into a digital signal by the A / D conversion unit (X) 121 in step S141, and the A / D conversion unit is converted by the comparison unit (X) 123 in step S142. (X) The voltage of the digital signal from 121 is compared with the magnetic detection threshold value stored in the storage unit 125. At the same time, the output of the magnetic impedance element (Y) 112 is converted into a digital signal by the A / D converter (Y) 122 in step S143, and the A / D converter (Y) is converted by the comparator (Y) 124 in step S144. ) The voltage of the digital signal from 122 is compared with the threshold value for magnetic detection stored in the storage unit 125.

  Next, in step S145, the process 1 described with reference to FIG. 8 is performed by the first processing unit 126, and in step S146, using the magnetic detection threshold value, the comparison unit (X) 123 and the comparison unit (Y). It is determined whether the output of 124 is at the H level or the L level at the same time. If the determination result is the H level or the L level at the same time, the process 2 described with reference to FIG. 10 is performed by the second processing unit 127 in step S147. If the determination result in step S146 is No, the detection result of unauthorized use by the magnet or the detection result of unauthorized use by the radio wave in step S147 is output in step S148.

  FIG. 15 is a flowchart for explaining the operation of the microcomputer 22 in the magnetic detection apparatus shown in FIG. In FIG. 15, an H level signal is output from the switching output unit 221 to the switching unit 211 in step S151. Next, in step S152, the output of the magnetic impedance element (X) 111 is converted into a digital signal by the A / D conversion unit 222, and in step S153, the voltage of the digital signal from the A / D conversion unit 222 is converted by the comparison unit 223. It compares with the threshold value for magnetic detection memorize | stored in the memory | storage part 224. FIG. In step S154, the switching output unit 221 outputs an L level signal to the switching unit 211. In step S155, the output of the magnetic impedance element (Y) 112 is converted into a digital signal by the A / D converter 222, and the voltage of the digital signal from the A / D converter 222 is stored in the comparator 223 in step S156. It compares with the threshold value for magnetic detection memorize | stored in the part 224. FIG.

  Next, in step S157, the process 1 described with reference to FIG. 8 is performed by the first processing unit 126. In step S158, the magnetic impedance element (X) 111 and the magnetic impedance element ( Y) It is determined whether the output of 112 is converted to a digital signal at the same time as H level or L level. If the determination result is the H level or the L level at the same time, the process 2 described with reference to FIG. 10 is performed by the second processing unit 127 in step S159. If the determination result in step S158 is No, the detection result of unauthorized use by the magnet or the detection result of unauthorized use by the radio wave in step S159 is output in step S160.

It is a block diagram which shows the structure of the magnetic detection apparatus mounted in the pachinko game machine by the 1st Embodiment of this invention. It is a block diagram which shows the structure of the magnetic detection apparatus mounted in the pachinko game machine by the 2nd Embodiment of this invention. It is a disassembled perspective view of the module which integrated the magnetic detection apparatus shown in FIG. 1 or FIG. (A) is a front view of a pachinko gaming machine to which a magnetic detection device according to the present invention is attached, and (B) is an enlarged sectional view taken along line AA of (A) of FIG. It is a figure which shows the image of the detection area | region of the magnetism from the magnet 44 in the surface of the windshield 42 of a pachinko machine when the magnetic detection apparatus 1 is attached as shown in FIG. FIG. 6 is a graph showing the relationship between the output of the magneto-impedance element and the output of the comparison unit when the magnet 44 moves along the locus (1) to (5) in the detection region on the windshield as shown in FIG. It is a graph which shows the relationship between the output of a magnetic impedance element when an electromagnetic wave arrives at a magnetic detection apparatus, and the output of a comparison part. It is a figure explaining operation | movement of the comparison part (X) 123 and the comparison part (Y) 124 at the time of using only the threshold value for magnet detection. It is a graph which shows the relationship between the state obtained from a magnetic impedance element, a magnetic detection output, and a radio wave detection output in the case of providing a radio wave detection threshold in addition to a magnetic detection threshold. It is a figure which shows the process 2 (process when it cannot process by the process 1). It is a flowchart explaining the main process by the magnetic detection apparatus shown in FIG. 12 is a flowchart illustrating details of threshold setting processing in step S112 of FIG. It is a flowchart explaining the threshold value setting process in the magnetic detection apparatus shown in FIG. It is a flowchart explaining the operation | movement of the microcomputer 12 in the magnetic detection apparatus shown in FIG. It is a flowchart explaining the operation | movement of the microcomputer 22 in the magnetic detection apparatus shown in FIG.

Explanation of symbols

1 Magnetic detector 111 Magnetic impedance element (X)
112 Magnetic impedance element (Y)
121 A / D converter (X)
122 A / D converter (Y)
123 Comparison part (X)
124 Comparison part (Y)
125 storage unit 126 first processing unit 127 second processing unit 128 output unit 41 pachinko machine 42 windshield 44 magnet

Claims (4)

At least two magnetic impedance elements for detecting magnetism on the front side of the windshield of a pachinko machine, an analog output unit that amplifies and outputs an analog signal obtained from the magnetic impedance element, and an output of the analog output unit An A / D converter for converting to a digital signal, and the analog output unit connected to a line between the analog output unit and the A / D converter, detects the arrival of radio waves, and changes upon arrival of the radio waves A coil for increasing the amplitude of the output signal, a comparator for comparing the output signal from the A / D converter with a predetermined threshold, a storage for storing the predetermined threshold, and the comparator A processing unit that calculates the presence or absence of unauthorized use of the pachinko gaming machine based on a comparison result, and an output unit that outputs a calculation result by the processing unit,
The storage unit stores a magnetic detection threshold value for detecting magnetism and a radio wave detection threshold value for detecting radio waves, and is mounted on the pachinko gaming machine, Magnetic detection device. At least two magnetic impedance elements for detecting magnetism on the front side of the windshield of a pachinko machine, an analog output unit that amplifies and outputs an analog signal obtained from the magnetic impedance element, and an output of the analog output unit An A / D converter for converting to a digital signal, a comparator for comparing an output signal from the A / D converter with a predetermined threshold, a storage for storing the predetermined threshold, and the comparator A processing unit that calculates the presence or absence of unauthorized use of the pachinko gaming machine based on the comparison result by, and an output unit that outputs a calculation result by the processing unit,
The storage unit stores a magnetic detection threshold value for detecting magnetism and a radio wave detection threshold value for detecting radio waves ,
The processing unit indicates that the output from the comparison unit indicates that the A / D conversion values of the output signals of the at least two magnetoimpedance elements are all greater than the magnetic detection threshold value. Or when the A / D conversion values of the output signals of the at least two magneto-impedance elements by the A / D converter are all smaller than the magnetic detection threshold, the radio wave detection threshold Is used to discriminate between unauthorized use by magnets and unauthorized use by radio waves, and one of the A / D conversion values of the output signals of the at least two magnetic impedance elements by the A / D conversion unit is used for the magnetic detection. When it indicates that the other is larger than the threshold value and smaller than the magnetic detection threshold value, it is determined whether or not the magnet is illegally used by using the magnetic detection threshold value. Characterized in that the manner,
A magnetic detection device mounted on the pachinko gaming machine.   The magnetic detection device according to claim 1, wherein the magneto-impedance element is installed in parallel to a windshield surface of the pachinko gaming machine.   The absolute value of the radio wave detection threshold value is based on the absolute value of the magnetic detection threshold value and the absolute value of the output voltage of the magnetic impedance element by a general radio that is not intended for unauthorized use of the pachinko gaming machine. 3. The magnetic detection device according to claim 1, wherein the magnetic detection device is a value that is large and smaller than an absolute value of output power of the magnetic impedance element by a radio device intended for unauthorized use of the pachinko gaming machine.

Images