RU2032223C1 - Antitheft signalling device with detection of marks - Google Patents

Abstract

FIELD: alarm signalling. SUBSTANCE: antitheft signalling device has two aerials - radiating 5 and receiving 8, high-frequency amplifier 9, generator 3 of rectangular pulses, synchronous detector 11, integrator 12, threshold detector 13 and indicator 14 connected in series. Frequency-modulated generator 1 is linked to output of generator 3. Antitheft device is inserted with directional coupler 4, delay line 6, multiplier 7 and band-pass filter 10 connected to input of synchronous detector 11. Multiplier 7 is coupled to output of high- frequency amplifier 9, directional coupler 4 is linked to input of radiating aerial 5 and to output of frequency-modulated generator. Insertion of directional coupler 4 and multiplier 7 enables tuning of radiating signal and of receiver to be ensured. EFFECT: increased authenticity and range of detection of marks. 1 dwg

Description

 The invention relates to electronic means of burglar alarm, and in particular to devices that impede the movement of items with a tag outside the protected area.

 A tag detection device is known (PCT patent WO 85/04975, CL G 08 B 13/24, 1985). The device consists of a generator with a step change in frequency, the output of which is connected to the input of the antenna. The modulation input of the generator is connected to the output of the digital-to-analog converter connected to the microcomputer. The antenna output is connected to the input of the microcomputer via an analog-to-digital converter.

 The electromagnetic oscillation from the output of the generator changes in frequency under the action of the step voltage of the digital-to-analog converter and enters the antenna. In the absence of a label, which is an electric resonant circuit, the electric current in the antenna circuit changes only slightly from the oscillation frequency. If the mark is in the protected area due to energy absorption by the resonant circuit of the mark, the current level in the antenna decreases at the frequencies of the irradiating signal corresponding to the natural frequency of the mark. The current values in the antenna are converted by an analog-to-digital converter and recorded in the memory of the microcomputer. Thus, the presence of a tag in the protected area is recorded. Information about the value of the natural frequency of the label is used to select the range of the frequency of the irradiating signal.

 The disadvantage of this device is the high level of noise and external noise at the input of the analog-to-digital converter, caused by the absence of filter elements, which leads to a decrease in the detection range of the mark.

 The closest in technical essence to the proposed one is a device consisting of a frequency-modulated generator, the input of which is connected to a low-frequency generator. The output of the high-frequency generator through a power amplifier and a decoupling device is connected to the antenna. A selective receiver amplifier is connected to the second output of the decoupling device, the output of which is connected to a demodulator. The output of the demodulator is connected to the input of the synchronous detector, and its second input is connected to the second output of the low-frequency generator. The output of the synchronous detector through the integrator is connected to the input of the threshold detector, loaded on the indicator.

 The frequency-modulated signal from the output of the generator through the power amplifier and the decoupling device enters the antenna and is radiated. If there is no mark in the protection zone, then this signal does not change in amplitude and, passing from the antenna through the decoupling device and a selective amplifier, enters the demodulator. The output signal of the demodulator in this case is a constant voltage. If there is a mark in the guard zone, the irradiating signal acquires amplitude modulation in accordance with the amplitude-frequency characteristic of resonant energy absorption. Thus, an alternating voltage occurs at the output of the demodulator. The frequency of these oscillations will correspond to the frequency of the sound generator. The output signal of the demodulator is fed to the first input of the synchronous detector, to the second input of which the voltage of the low-frequency generator is supplied. The signal from the output of the synchronous detector is accumulated in the integrator. The excess of the output voltage of the integrator over the set level of the threshold detector leads to the inclusion of an indicator that reports the presence of a tag in the protection zone.

 However, the frequency band of the receiver selective amplifier cannot be less than twice the frequency deviation of the irradiating signal. This makes it impossible to reduce external noise and noise in the linear part of the receiver by reducing its bandwidth. In addition, the input of the demodulator along with the tag signal receives an irradiating signal superior to it in level, which is also an obstacle. For these reasons, the tag detection range is reduced.

 The aim of the invention is to increase the reliability and detection range of the label.

 To do this, the detection of the label signal is carried out by introducing a second correlation circuit formed using the delay line.

 The block diagram of the detection device is shown in the drawing. The device comprises a frequency-modulated generator 1, to the inputs of which a sawtooth voltage generator 2 and a first output of a rectangular pulse generator 3 are connected. The output of the generator 1 through the directional coupler 4 is connected to the irradiating antenna 5. The second output of the directional coupler 4 through the delay line is connected to the multiplier 7, which is connected to the receiving antenna 8 through the high-frequency amplifier 9. The output of the multiplier 7 is connected to a band-pass filter 10, which is connected to the first input of the synchronous detector 11. The second input of the synchronous detector 11 and the second output of the generator 3 are connected. The output of the synchronous detector 11 through the integrator 12 is connected to a threshold detector 13, which is connected to the indicator 14.

 The irradiating signal from the generator 1, which varies linearly in frequency under the action of the voltage of the generator 2, has a frequency manipulation caused by the pulse signal from the generator 3. The irradiating signal from the generator 1 through the directional coupler 4 enters the antenna 5 and is emitted. Part of the power of the irradiating signal branches off in the directional coupler 4 and enters through the delay line 6 to the multiplier 7. The irradiating signal is received by the antenna 8 and also through the high-frequency amplifier 9 to the multiplier 7. The delay time value in line 6 is selected so that in the absence of a resonant mark the output of multiplier 7 was zero. If there is a mark between the antennas 5 and 8, as a result of the resonant absorption of the energy of the irradiating signal, the input signals of the multiplier 7 coming from the antenna 8 and the delay line 6 will be different. In this case, pulses will come from the output of the multiplier 7 at the moment the frequency of the irradiating signal coincides with the natural frequency of the mark. The pulse repetition rate is determined by the parameters of the sawtooth voltage generator 2, and the filling frequency coincides with the pulse generator repetition frequency 3. The signal from the output of the multiplier 7 passes through a bandpass filter 10 tuned to the filling frequency and is transmitted to the synchronous detector 11. The output pulses of the synchronous detector 11 are accumulated in the integrator 12. If the output signal of the integrator 12 exceeds a predetermined level of the threshold detector 13, then the indicator 14 is turned on, registering the presence of the label.

 Thus, the introduction of a directional coupler 4 and a multiplier 7 in the circuit of the detection device allows for synchronous reconstruction of the irradiating signal and the receiver. In this case, the receiver bandwidth is determined by the time constant of the integrator 12 and is units of hertz. The suppression of interference due to its own irradiating signal is achieved by switching on the delay line 6 between the directional coupler 4 and the multiplier 7.

Claims (1)

 SECURITY ALARM DEVICE FOR LABEL DETECTION, containing a square-wave pulse generator, the output of which is connected to the first inputs of a frequency-modulated generator and a synchronous detector, an irradiating antenna and a receiving antenna, the output of which is connected to the input of a high-frequency amplifier, the output of a synchronous detector is connected to the integrator input, the output which is connected to the information input of the threshold block, the output of which is connected to an indicator, characterized in that a sawtooth voltage generator is introduced into it , directional coupler, delay line, multiplier, band-pass filter, sawtooth generator output connected to the second input of the frequency-modulated generator, the output of which is connected to the input of the directional coupler, the first output of which is connected to the irradiating antenna, and the second output through the delay line to the first the input of the multiplier, the output of the high-frequency amplifier is connected to the second input of the multiplier, the output of which is connected through the bandpass filter to the input of the synchronous detector.