JPH05252081A - Method for identifying mobile station by radio wave - Google Patents

Abstract

PURPOSE:To simply and accurately recognize an identification code in a small area by identifying an identification code of an ID card being a mobile station carried by a person and entering a reception area of a stationary station by means of the mutual induction system by each resonance circuit of the stationary station and the mobile station. CONSTITUTION:A stationary station 11 allows a transmission reception coil 59 to generate a high frequency electromagnetic field at a prescribed interval through the excitation of an oscillation circuit to form a reception area. When a person carries an ID card 10 being a mobile station and enters the reception area, a voltage is induced in the transmission reception coil 71 of the card 10 through the resonance of a resonance circuit comprising a coil 71 and a capacitor C1 with the high frequency electromagnetic field generated from the stationary station 11. Each circuit of the card 10 is operated by the rectified induced voltage as a power supply to apply amplitude modulation to an identification code specific to the card 10 itself by means of a capacitor C2 and a switching element 69. A coil 59 of the stationary station 11 receives the modulation wave, detects and demodulates the wave and it is processed by a microcomputer. Thus, the card 10 is identified simply and accurately by the mutual induction system.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless mobile station identification method for sending data between a fixed station and an ID card as a mobile station by a mutual guidance method to identify the mobile station. It is about.

[0002]

2. Description of the Related Art Conventionally, in order to transmit data between a fixed station and a mobile station, as described in, for example, Japanese Patent Publication No. 3-25832, the vibration energy of the fixed station is received by the mobile station. When it is received by the device, the AC component of the received vibration energy is appropriately converted to generate a clock signal, data is read by this, the carrier wave is modulated with this data, and the data is transmitted to the outside by the coupler.

[0003]

However, the above-mentioned conventional method is effective when the distance between the fixed station and the mobile station is large and the amount of data transmission is large, but the ID card is used in the fixed station. In case of recognizing and opening and closing the door, the reception area is at most several tens of cm to several meters, and
Since the amount of identification code data on the ID card is extremely small,
A simpler method is preferred.

It is an object of the present invention to provide a method for enabling a person carrying an ID card to recognize the ID card by a simple method based on a mutual guidance system when entering the reception area of a fixed station such as a doorway. To do.

[0005]

According to the present invention, a high frequency electromagnetic field is formed by a resonance circuit connected to a fixed station, and this high frequency electromagnetic field is caused to resonate with a resonance circuit of a mobile station in a reception area. The clock signal synchronized with the frequency is extracted to read the registered identification code in the mobile station, the high frequency signal of the resonant circuit of the fixed station is modulated by this identification code, and the fixed station detects and demodulates the high frequency signal to determine the mobile station. The mobile station identification method by radio is characterized in that the identification is performed.

[0006]

Function: A high frequency current is passed from the fixed station to the coil of the resonance circuit to form an electromagnetic field in the space to form a reception area. When a person with an ID card enters the reception area, I
The resonance circuit built in the D card resonates, a clock signal synchronized with the resonance frequency of the electric energy induced in the coil is extracted, and a unique ID (identification) code is read.

A high frequency signal of the resonance circuit of the fixed station is modulated by the identification code of the ID card, detected and demodulated, and input to the microcomputer. It is determined whether the identification code input by this microcomputer is registered.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. A case where the ID card 10 is of a batteryless type will be described. In FIG.
ID card 1 based on the high frequency electromagnetic field generated by
In the case of 0, a voltage is induced in the built-in transmission / reception coil 71, and its own identification code is transmitted by the so-called mutual induction method. The ID card 10 will be described in detail with reference to FIG. 2, and the fixed station 11 will be described in detail with reference to FIG. In FIG. 3, the fixed station 11 includes a transmission / reception coil 59 that forms a high-frequency electromagnetic field in space, an LC resonance circuit 50 including the transmission / reception coil 59 and a capacitor, and an envelope detection circuit 51 that extracts an envelope signal from a received signal. , An active filter circuit 52 that passes only the data signal, 2 data signals
A comparator circuit 53 for converting the value into a digital signal,
A microcomputer 54 for exchanging signals with the fixed station centralized control unit 40, an oscillation circuit 55 for generating a high frequency signal, a switch circuit 56 for turning on and off in order to output an oscillation signal from the microcomputer 54 at regular time intervals, An amplifier circuit 57 for amplifying the voltage of the high frequency signal and a booster circuit 58 for amplifying the current are included.

In FIG. 2, the ID card 10 comprises a coil 71 and a capacitor 72, an LC resonance circuit 60 which resonates with a high frequency electromagnetic field formed in the space by the coil 59 of the fixed station 11, and energy obtained by the resonance. A rectifier circuit 63 for converting the DC power into DC power for driving internal elements,
A clock extracting circuit 62 for extracting a clock synchronized with the resonance frequency, a frequency dividing circuit 64 for dividing the frequency of the extracted clock,
A first clock generating circuit 65 that divides the clock in the frequency dividing circuit 64 by 64, and the first clock generating circuit 65.
The second clock generation circuit 66 that divides the clock signal of 128 by 128, the inverter circuit 67, the serial ROM 68 that stores the unique identification code data, the switch element 69 such as FET and the capacitor 70, and the data of the serial ROM 68 The fixed station 11 comprises a modulation circuit 61 for AM-modulating the frequencies at both ends of the coil 59.

The operation of the above configuration will be described with reference to the waveform chart. (1) When the fixed station centralized management unit 40 is powered on, the switch circuit 56 is turned on and off by a signal from the microcomputer 54, and a high frequency signal is repeatedly sent to the fixed station 11 at fixed time intervals.

(2) When the switch 56 is turned on by the reset pulse from the microcomputer 54 as shown in FIG. 4A, the high frequency signal of the oscillation circuit 55 passes through the amplification circuit 57 and the booster circuit 58 and then the LC resonance circuit. A high-frequency electromagnetic field as shown in FIG. 4B is generated in space by 50 to form a reception area.

(3) Here, it is assumed that the person carrying the ID card 10 has entered the reception area of the high frequency electromagnetic field by the fixed station 11. At this time, even if the ID card 10 is left in the pocket or the like, the electromagnetic field passes through the clothes through the inside and outside. Then, it resonates with the LC resonance circuit 60 of the ID card 10. The energy obtained by the resonance circuit 60 is converted into DC power by the rectification circuit 63, and the frequency dividing circuit 64,
Electric power is supplied to each element in the ID card 10 such as the serial ROM 68. The clock synchronized with the resonance frequency extracted by the clock extracting circuit 62 is sent to the frequency dividing circuit 64, and the clock divided by 64 in the first clock generating circuit 65 is passed through the inverter circuit 67 to the serial ROM 6
8 and the ID code data as shown in FIG. 4C is read. When all ID code data are read,
A signal divided by 128 is output from the second clock generation circuit 66 and reset.

A check digit is added to the identification code data as needed. This serial ROM6
FET of the modulation circuit 61 according to the identification code data from 8
69 is turned on and off to change the impedance, and the modulation circuit 61 performs AM modulation on the frequencies at both ends of the coil 59 of the fixed station 11. More specifically, in FIG. 1 showing an equivalent circuit of the fixed station 11 and the ID card 10, even if the ID card 10 does not exist in the reception area of the fixed station 11 or even if it is in the reception area, the coils 59 and 71 are provided.
When and are orthogonal and do not react, C0 of fixed station 11
And the resonance frequency f of L0 is , And the voltage V0 of the coil 59 is maximized when f = f0 is tuned. Normally, f0 = f is fixed. Here, the switch element 69 of the ID card 10
When is off, the resonance frequency f2 of the ID card 10 is And is tuned to f2 = f0. When the switch element 69 is on Becomes However, when the ID card 10 is in the reception area of the fixed station 11, f2 = f0 when the switch element 69 is off, so that the current i proportional to the strength of the electromagnetic field flows through the coil 71. If the switch element 69 is on, f2 ≠ f0, so the current i changes. This change in the current i is caused by the mutual induction action in L0 of the coil 59.
And the voltage V0 changes. That is, ID
It can be said that the card 10 is a modulator that performs AM (amplitude modulation) on the voltage shown in FIG. 4B of the coil 59 of the fixed station 11 as shown in FIG. 4D. The switch element 69 may be tuned to f2 = f0 when it is on, and may be f2 ≠ f0 when it is off.

(4) The change in voltage as shown in FIG. 4 (d) is detected by the envelope detection circuit 51 as shown in FIG. 4 (e), and the active filter circuit 52 is shown as shown in FIG. 4 (f). As described above, only the necessary frequency component is extracted, converted into a binary value by the comparator circuit 53 as shown in FIG. The microcomputer 54 determines whether the input identification code data is registered.

(5) If registered, the fixed station number of the fixed station 11 is added to the identification code, and a signal is output from the microcomputer 54 to the fixed station centralized management unit 40. (6) The data input to the input / output unit of the fixed station central management unit 40 is output to the control circuit. (7) The controlled machine is controlled by the control signal from the control circuit.

In the above embodiment, the case of the battery-less system, that is, the case where the high frequency electromagnetic field of the fixed station 11 is resonated in the ID card 10 and the voltage induced at that time is used as the internal drive power will be described. did. However, the ID card 10 is not limited to this example, and may have a battery built-in type.

[0017]

As described above, according to the present invention, the identification code of the ID card is recognized by the mutual induction system of the resonance circuits of the fixed station and the mobile station. The recognition is simple and accurate.

[Brief description of drawings]

FIG. 1 is an equivalent circuit diagram of a fixed station and a mobile station for explaining the principle of the method of the present invention.

FIG. 2 is an electric circuit diagram of an ID card for carrying out the method of the present invention.

FIG. 3 is an electric circuit diagram of a fixed station for carrying out the method of the present invention.

FIG. 4 is an output waveform diagram of each unit in FIGS. 2 and 3.

[Explanation of symbols]

10 ... ID card, 11 ... Fixed station, 40 ... Fixed station centralized management unit, 50 ... LC resonance circuit, 51 ... Envelope detection circuit, 5
2 ... Active filter circuit, 53 ... Comparator circuit, 54 ... Microcomputer, 55 ... Oscillation circuit, 56 ... Switch circuit, 57 ... Amplification circuit, 58 ... Booster circuit, 59 ... Transceiver coil, 60 ... LC resonance circuit, 61 ... Modulation circuit , 6
2 ... Clock extraction circuit, 63 ... Rectifier circuit, 64 ... Frequency divider circuit, 65 ... First clock generation circuit, 66 ... Second clock generation circuit, 67 ... Inverter circuit, 68 ... Serial ROM, 69 ... Switch element, 70 ... Capacitor, 71
… Transmit / receive coil, 72… capacitor.

Claims (1)

[Claims] 1. A high frequency electromagnetic field is formed by a resonance circuit connected to a fixed station, and this high frequency electromagnetic field is caused to resonate with a resonance circuit of a mobile station within a reception area, and a clock signal synchronized with this resonance frequency is extracted. Then, the registered identification code in the mobile station is read out, the high frequency signal of the resonance circuit of the fixed station is modulated by this identification code, and the fixed station detects and demodulates this to identify the mobile station. Mobile station identification method by radio.