KR920003001B1 - Testing method of metal coin - Google Patents

Abstract

A counter counts clock signals during a time period corresponding to the phase difference for an inserted coin, and the kind of the coin is found based on the counted data. That is, the kind of the coin is determined based on data such as: the sum of data for the interval between m-s and m+s, the time for the same interval, and the peak value (m). Here, "s" represents the standard deviation of the distribution of the values. The method discriminates the kind of coins in an accurate manner even in the case of coins worn out.

Description

Hardening discrimination method

1 is a curing discrimination circuit diagram to which the curing discrimination method of the present invention is applied.

2 is a detailed circuit diagram of FIG.

3 and 4a to e are waveform diagrams of respective parts of FIG.

5 is a graph showing the change of detection data with the passage of time of the Gaussian distribution function to which the hardening discrimination method of the present invention is applied.

6a, b is a signal flow diagram showing a hardening discrimination method of the present invention.

* Explanation of symbols for main parts of the drawings

1: micom 3: hardening

5: counter

The present invention relates to a hardening discrimination method for determining the type of hardening, in a machine into which coins are added, such as a beverage vending machine, subway ticket vending machine and a public telephone.

In the past, the data was detected by the size and diameter of the added curing, and the type of curing was determined by the highest value among the detected data, that is, the amount of the curing applied, and whether or not counterfeiting and normal curing were determined. There was a problem that it is not possible to determine the type of hardening when the wear, if worn for a long period of use of the device. Then, by detecting the data of the hardening using the phase difference of the signal induced from the primary coil to the two secondary coils according to the material of the hardened material, and comparing the detected data with a plurality of previously stored basic data, the type of the hardened material is determined. However, this is because the detected data is changed due to the positional error between the primary coil and the two secondary coils at the point of time when detecting the data according to the material of the inserted coin. There was a problem that the tolerance of the type of hardening was low due to the tolerance value.

Accordingly, it is an object of the present invention to provide a curing discrimination method for accurately determining the type of curing applied by a change in data of curing due to a phase difference of a signal induced from a primary coil to two secondary coils depending on the material of the curing applied.

The curing discrimination method of the present invention having such a purpose uses a Gaussian distribution (also known as a normal distribution) function to detect the curing as it passes between the primary coil and the two secondary coils. From the data to be detected, the sum of the data of a certain band, the time of a certain band to obtain the sum of the data, and the highest value data are detected, and the sum of the detected data, the time and the type of the coin put into the highest value data can be determined. do. In particular, in the present invention, even if there are wear and system errors caused by using the device for a long time, the sum of the data of a predetermined band is always constant at an absolute value, so that the type of hardening applied can be accurately determined.

Hereinafter, a hardening discrimination method of the present invention will be described in detail with reference to the accompanying drawings.

1 is a hardening discrimination circuit diagram to which the hardening discriminating method of the present invention is applied, and FIG. 2 is a detailed circuit diagram, as shown in FIG. A crystal (XT) for supplying a clock preference to the coil, a coil (L), a resistor (R ₁ , R ₂ ), a buffer (BF), a capacitor (C ₁ .C ₃ ), and a transistor (TR) for oscillating and outputting an oscillation signal. ₁ ) the phase difference between the two coils (T ₁₂ , T ₁₃ ) in the primary coil (T ₁₁ ) according to the material of the coin (3) and the oscillation unit (2) and the oscillation signal of the oscillation unit (2). A resistor R for detecting a phase difference between a signal to be induced and a signal induced to the secondary coils T ₁₂ and T ₁₃ of the transformer TA and inputting an interrupt request signal to the microcomputer 1. ₃ , R ₄ , the phase difference detection unit 4 comprising the pulse signals C ₃ , C ₄ , the comparators COMP ₁ and COMP ₂ and the AND gate, and the phase difference detection unit 4. A NAND gate ND for passing the clock signal of the crystal XT during a phase difference detection time, a counter 5 for counting a clock signal output from the NAND gate ND, and inputting it to the microcomputer 1; And a coin storage control unit for storing or returning the program block 6 for storing the basic data of each coin 3 and outputting it to the microcomputer 1 and the coin 30 injected under the control of the microcomputer 1. (7) and the coin storage detector 8 which detects the passage of the coin 3 which the coin storage control part 7 classified-stored, and inputs into the said microcomputer 1, and comprised. When the coin 3 is added in the above, the coin 3 injected is passed between the primary coil T ₁₁ and the secondary coils T ₁₂ and T ₁₃ of the transformer T, and is not described in the drawings. Explanation Code VCC is a power supply terminal.

According to the present invention configured as described above, the crystal (XT) is oscillated while the operating power is applied to the power supply terminal (VCC) to supply the clock signal to the microcomputer (1), and the oscillator (2) is the coil (L) and the condenser ( The oscillation is performed according to the time constant of C _{1 and} C ₂ ), and the oscillation signal causes the transistor TR ₁ to be repeatedly turned on and off to apply an oscillation signal to the primary coil T ₁₁ of the transformer TA. Here, the oscillation signal frequency F of the oscillator 2 is expressed by the following equation.

)에 인가되어 카운터(5)는 클럭신호를 카운트하고 출력포트를 출력하여 마이콤(1)의 입력포트가 인가된다.When the hardening 3 is not added in such a state, the comparator of the phase difference detection unit 5 does not have a phase difference of the signal induced from the primary coil T ₁₁ of the transformer TA to the secondary coils T ₁₂ and T ₁₃ . Since the signals Va and Vb applied to the inverting input terminals (-) and (-) of (COMP ₁ ) and (COMP ₂ ) respectively have phase differences of 180 ° as shown in FIG. 3A, the comparator COMP ₁ (COMP ₂ ) repeatedly outputs low and high potential pulse signals alternately as shown in FIGS. 3b and 3c, and the AND gate AD is shown in FIG. 3d. The low potential is continuously output so that the NAND gate ND does not output the clock signal of the crystal XT and continuously outputs the high potential as shown in FIG. 3E. In addition, when the curing (3) fmf is injected, the injected curing (3) passes between the primary coil (T ₁₁ ) and the secondary coils (T ₁₂ , T ₁₃ ) of the transformer (TA), Depending on the material, the signals induced by the secondary coils T ₁₂ and T ₁₃ have a mutual phase difference, and the inverting input terminals (-) (-) of the comparator COMP ₁ and COMP ₂ are shown in FIG. As shown in FIG. 4B and FIG. 4C, the comparators COMP ₁ and COMP ₂ output pulse signals as shown in FIGS. 4B and 4C. AD) outputs a high-potential phase difference detection signal shown in FIG. 4D and is applied to one side input terminal of the NAND gate ND. Therefore, the NAND geat ND inverts the clock signal to the crystal XT input to the other input terminal while the end rate AD outputs the phase difference detection signal of high potential and outputs the signal as shown in FIG. 4E. The clock signal outputted from the clock terminal of the counter 5

), The counter 5 counts the clock signal and outputs an output port to which the input port of the microcomputer 1 is applied.

)로 저전위 인터럽트 요청신호가 입력되고, 앤드게이트(AD)에서 저전위가 출력되면, 낸드게이트(ND)는 더 이상의 클럭신호를 출력시키지 않게 되어 카운터(5)의 클럭신호 카운트동작이 정지되고, 마이콤(1)은 인터럽트 요청신호가 안가됨에 따라 카운터(5)가 연재까지 카운트한 클럭신호의 수 즉, 투입된 경화(3)에 따른 검출 데이터를 입력하게 돤다. 그리고, 마이콤(1)은 일정대역내의 데이터를 모두 가산함과 아울러 데이터를 가산하는 일정대역의 시간과, 데이터 중에서 최고값의 데이터를 검출하고, 그 검출한 데이터의 합, 시간 및 최고값 데이터와 프로그래머블롬(6)에 저장되어 있는 기본 데이터들을 비교하여 투입된 경화(3)의 종류를 판별 즉, 경화(3)의 위조 및 정상여부와, 경화(3)의 금액을 판별하고, 위조로 판별되었을 경우에는 반납하고, 정상으로 판별되었을 경우에는 경화 수압 제어부(7)를 제어하여 수납하고, 경화 수납 검출부(8)의 출력신호로 경화(3)가 수납되었는지를 판별한다. 즉, 본 발명은 경화(3)가 투입되었을 경우에 투입된 경화(3)가 일차코일(T₁₁)과 두 개의 이차 코일(T₁₂,T₁₃)사이로 특어감에 따라 데이터의 값이 점차 증가하고, 중앙에 위치되었으 경우에 데이터의 값이 가장 크며, 중앙을 벗어나 밖으로 나옴에 따라 데이터의 값이 점차 감소하여 제5도에 도시된 바와 같이 가우스 분포함수의 곡선으로 나타나게 되므로 데이터의 전면적은,In this state, the low potential is output from the comparator COMP ₁ so that the interrupt request terminal of the microcomputer 1 (

When the low potential interrupt request signal is inputted and the low potential is output from the AND gate AD, the NAND gate ND does not output any more clock signals, and the clock signal counting operation of the counter 5 is stopped. The microcomputer 1 inputs the number of clock signals counted by the counter 5 until the interrupt request signal goes out, that is, the detection data according to the input coin 3. Then, the microcomputer 1 adds all the data in the predetermined band, detects the time of the predetermined band to add the data, and the data of the highest value among the data, and adds the sum of the detected data, the time and the maximum data. By comparing the basic data stored in the programmable block 6, the type of the coin 3 is determined, that is, the forgery and normality of the coin 3 and the amount of the coin 3 are determined. In the case of returning, if it is determined that it is normal, the curing hydraulic pressure control unit 7 is controlled and stored, and it is determined whether the curing 3 is stored by the output signal of the curing storage detection unit 8. That is, according to the present invention, when the coin 3 is added, the value of the data gradually increases as the coin 3 added between the primary coil T ₁₁ and the two secondary coils T ₁₂ and T ₁₃ . When the data is located at the center, the value of the data is the largest, and as the data is moved out of the center, the value of the data decreases gradually and appears as a curve of the Gaussian distribution function as shown in FIG.

)에 인터럽트 요청신호가 인가되는 시간이며, m은 최고값 데이터이며 σ는 분포의 표준편차로서

이다. 이고, m-σ부터 m+σ까지의 면적의 합으로 투입된 경화(3)의 종류를 판별하며, 이때 기기의 마모 및 오차가 있어도 의 값으로 항상 일정하므로

(데이터) dt의 값을 항상 절대적인 값으로 나타나게 되어 경화(3)의 종류 정확히 판별할 수 있다.Here, T is a change time of data, and dt is a unit time for inputting data.

Is the time when the interrupt request signal is applied, m is the highest value data, and σ is the standard deviation of the distribution.

to be. And determine the type of hardening (3) injected by the sum of the areas from m-σ to m + σ, and at this time, even if there is wear or error of the equipment,

(Data) The value of dt always appears as an absolute value, so that the type of hardening (3) can be accurately determined.

)로 저전위의 인터럽트 요청신호가 인가됨에 따라 마이콤(1)은 단계(10)에서 카운터(5)가 출력하는 데이터를 체크하고, 데이터가 있을 경우에 단계(11)에서 데이터를 입력하여 저장하게 된다. 그리고, 제6b도에 도시된 바와 같이 단계(20)에서 초기화동작을 수행하고, 단계(21)에서 프로그래머블롬(6)에 저장되어 있는 경화(3)의 기본 데이터를 입력한 후 단계(22)에서 샘플링 시간 즉,투입된 경화(3)의 종류를 판별하는 시간이 되었는지를 판별한다.6A and 6B are signal flow charts showing the hardening discrimination method of the present invention. In the present invention, such as Ewha, as shown in FIG.

As the low-potential interrupt request signal is applied, the microcomputer 1 checks the data output by the counter 5 in step 10, and inputs and stores the data in step 11 if there is data. do. Then, as shown in FIG. 6B, an initialization operation is performed in step 20, and after inputting basic data of the coin 3 stored in the programmable block 6 in step 21, step 22 is performed. It is determined whether the time has come to determine the sampling time, that is, the type of the inserted coin 3.

In this state, when the sampling time is reached, it is determined in step 23 whether the variable SEQ is zero, and if it is 0, in step 24 it is determined whether the data is greater than or equal to the m-σ band, and in step 25 It is determined whether the data is in the m + σ band or less, and in the case of data between the m-σ and m + σ bands, the time T ₁ is counted in step 26, and in step 27, the data immediately before the current data is counted. If the current data is larger than the previous data by comparing the magnitude of the atta, the current data is stored as the highest data m in step 28, and then all the data are added in step 29, i.e. m-σ to m The data between the + σ bands is added and the process is repeated from step 22, and if the data is not between the m-σ and m + σ bands, the variable SEQ is set to 1 in step 30.

When the variable SE is set to 1 in this manner, the set of variables SE is determined in step 31 and the time T _{1 in the} band m + σ at m-σ counted in steps 32-34. , The hardening (3) is determined by comparing the sum of the data between the highest value data (m) and the m-σ to m + σ bands with the basic data input in the programblom (6), and in step 35 (32-34) In the case of forging and finally discriminated by the determination result, it is determined that the hardening 3 introduced in step 36 is forging, and if not, the hardening 3 injected in step 37 is normal. After determining and determining the amount, the next operation is performed.

As described in detail above, the present invention uses the Gaussian distribution function among the data detected according to the material of the coin (3) to be used as the sum of the data of a certain band, the highest value data, and the time of the certain band (3). Since the type of hardening 3 can be accurately determined, the hardening 3 can be accurately determined even if there is wear and error caused by using the device for a long time.

Claims (1)

In the coin discrimination method, in which the counter counts the clock signal during the phase difference time according to the coin input, the coin type discrimination method, wherein the sum of the data between m-σ and m + σ bands and m-? A hardening discrimination method characterized by detecting the time of the m + σ band and the highest value data (m) and comparing it with the basic data to determine the type of hardening. Where σ is the standard deviation of the distribution

being.

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