RU2507537C2 - Parametric scatterer-marker with nonlinear clock signal generation - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: in order to apply coherent accumulation when detecting single-loop parametric scatterers, with simultaneous radiation of pumping radio pulses at frequency f, the parametric scatterer generates a clock signal at frequency f/2. Frequency selection is facilitated using a method for nonlinear generation of clock signals, wherein clock signals at frequency 0.5f are generated directly in the parametric scatterer as a result of nonlinear conversion. To this end, one or two additional signals at frequencies f₁ and f₂ are emitted in the spectrum of the probing signal besides the signal at pumping frequency f. One of the nonlinear conversion frequencies of the probing signal must be equal to the generation frequency of the parametric scatterer: nf±mf₁±kf₂=0.5f, where n, m, k can assume integer values from 0 to 2. In the disclosed solution, nonlinear conversion is proposed on a nonlinear scatterer included in the design of the parametric scatterer-marker.

EFFECT: eliminating coherent interference with a radio receiver.

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Description

The invention relates to search devices that detect objects previously equipped with non-linear passive radio-reflective markers in the form of a parametric diffuser.

Known by the [Radio search for markers, patent RU 2108596 C1], the radio search for markers. The radio complex allows you to solve the problem of detecting objects, in particular people, marked using passive non-linear markers-transponders, which are used as parametric scatterers. The method consists in the fact that a parametric diffuser is previously placed on the search object. The region of space in which the search object can be located is irradiated with a probing signal at a frequency f, and a signal scattered by the marker at a subharmonic frequency equal to 0.5 f is received. If the detection threshold is exceeded, a decision is made about the presence of a search object in the detection zone.

This device has a significant drawback, namely, not sufficient efficiency, because either it is not possible to use a pulsed probe signal, or coherent reception of the scattered signal is not provided. This is due to the fact that upon excitation of each radio pulse scattered by the signal marker at the subharmonic frequency, two equally probable phase values differing by π are possible [P. Gorbachev. Signal formation by a system of passive subharmonic diffusers // Radio Engineering and Electronics, 1995, v. 40, No. 11, pp. 1606-1610.]. As a result, the signal scattered by the subharmonic is not coherent, even with a coherent probe signal.

These shortcomings are overcome in the detector parametric scatterers, known for [S. Lartsov A probe signal for detecting parametric scatterers // Radio Engineering, 2000, N5, pp. 8-12]. The detector of parametric scatterers allows solving the problem of applying coherent reception when detecting objects marked with the help of markers of parametric scatterers. The operation of the detector of parametric scatterers consists in the fact that a single-circuit parametric scatterer with a parametric generation frequency equal to half the frequency of the probing signal is preliminarily placed on the search object, the region of space in which the search object can be located is irradiated by the probing signal, which forms during the nonlinear scattering from the parametric scatterer a sequence of packs of narrowband coherent radio pulses of the scattered signal, with each radio pulse ls corresponds to the symbol of the selected coding law, which is a binary sequence, the elements of which correspond to the values of the phase of high-frequency filling of radio pulses, differing by π, for this the probing signal includes a sequence of packs of narrow-band coherent rectangular radio pulses of a pump signal with a frequency of high-frequency filling f and duration of radio pulses τ, except the probe signal includes a sequence of narrow-band coherent synchronizing rad IO pulses with a high-frequency filling frequency of 0.5f and a radio pulse duration of τ ₁ , while τ _{1 is} significantly shorter than τ, the high-frequency filling phase of the synchronizing radio pulse corresponds to the current ordinal symbol of the selected manipulation law, and the leading edge of the synchronizing radio pulse coincides with the leading edge of the pumping pulse or is ahead of it by time does not exceed τ _1, the coherent accumulation is done by algorithms that provide the maximum level of the coherent accumulation, with tvetstvuyuschego chosen law manipulation when exceeding the detection threshold decision is taken to the presence of an object obnaruzhebniya search area.

The detector of parametric scatterers allows for coherent accumulation of the signal in the receiving device, however, when implemented, for detecting parametric scatterers, synchronizing radio pulses at a frequency of 0.5f are used, which are coherent interference to the radio reception.

This disadvantage is eliminated in the detector of parametric scatterers with nonlinear generation of clock signals, known from [Babanov N.Yu., Korsakov A.S. et al. A method for detecting single-circuit or dual-circuit parametric scatterers // abstract of patent application RU 2009118092 A, publication date 11/20/2010]. In the detector of parametric scatterers with nonlinear generation of clock signals, synchronizing signals at a frequency of 0.5f are generated directly in the parametric scatterer as a result of nonlinear conversion on the nonlinear capacitance of the parametric scatterer. For this, in the spectrum of the probing signal, in addition to the signal at the pump frequency f, one or two additional signals are emitted at frequencies f ₁ and f ₂ . Moreover, one of the frequencies of the nonlinear transformation of the probe signal should be equal to the frequency of generation of the parametric scatterer: nf ± mf ₁ ± kf ₂ = 0.5f, where n, m, k can take integer values from 0 to 2.

As a prototype, a well-known [Non-linear passive marker - parametric scatterer, patent RU 2336538 C2] parametric diffuser-marker with non-linear generation of clock signals, consisting of a nonlinear parametric scatterer in the form of an antenna system connected to a parametric generator, was selected as a prototype. This parametric diffuser-marker, in particular, can be used for detectors with nonlinear generation of clock signals.

The disadvantage of the prototype is that the antenna system of this parametric scatterer marker with non-linear generation of clock signals must be designed and configured so that in addition to the signal at the pump frequency f and the signal at the frequency of parametric generation 0.5f, one or two signals at frequencies f ₁ and f ₂ , which always leads to a decrease in the efficiency of this antenna system. In addition, the presence of a parametric generator on the nonlinear capacitance, in addition to the signal at the pump frequency f, of one or two more signals at frequencies f ₁ and f ₂ with high intensity can lead to undesirable nonlinear blocking effects and, accordingly, decrease or even disrupt parametric generation. In this case, the conditions for the nonlinear generation of synchronizing signals imply the use of an ineffective nonlinear conversion on the nonlinear capacitance of a parametric generator. As a result, the coefficient of nonlinear conversion will be significantly lower than its potential maximum, which will require the use of additional signals with a high level of intensity, at least the same as the pump signal. In other words, combining on one single nonlinear element two nonlinear processes of different nature: parametric generation of subharmonics and nonlinear generation of clock signals, although physically possible, is likely to make it very difficult to simultaneously ensure their effectiveness.

The invention has the task of developing a design of a parametric scatterer, which would make it possible to realize the advantages of a nonlinear method for generating clock signals, namely, the frequency selection of the response signal from interference when detecting single-circuit parametric scatterers. To this end, it must be ensured that the two non-linear processes taking place simultaneously in the parametric scatterer: the parametric generation of subharmonics and the non-linear generation of clock signals, do not interfere with each other and can be independently optimized.

The disadvantages of the prototype are eliminated in the proposed parametric scatterer marker with non-linear generation of clock signals, consisting of a nonlinear parametric scatterer in the form of an antenna system connected to a parametric generator, while its design includes a nonlinear scatterer consisting of an antenna and a nonlinear element, and the frequency of the nonlinear product, the scattering of which the nonlinear scatterer is intended to equal the frequency of the parametric generation of the parametric generator.

The essence of the invention lies in the fact that provided that the design of the parametric scatterer marker additional nonlinear scatterer and the radiation of the probe signal, in the spectrum of which, in addition to the signal at the pump frequency f, one or two additional signals are emitted at frequencies f ₁ and f ₂ , it becomes possible simultaneous and efficient flow of two nonlinear processes: parametric generation of subharmonics and nonlinear generation of clock signals. At the same time, it is possible to optimally tune the antenna system of the parametric scatterer to the pump frequencies f and parametric generation 0.5f, and the parametric generator can be protected from blocking effects based on frequency selection. At the same time, the nonlinear generation of clock signals will be performed independently on the nonlinear scatterer and can also be performed optimally from the point of view of optimizing the antennas of the nonlinear scatterer, and its nonlinear scattering frequency 0.5f, and the frequencies that are involved in the formation of this nonlinear product.

The proposed parametric diffuser - a marker with non-linear generation of clock signals can be implemented as a marker in the detector of single-circuit parametric scatterers. In this case, an additional signal is emitted at a frequency of 0.25f, that is, four times less than the frequency of the pump signal f. The clock signal is the second harmonic of the auxiliary signal. Accordingly, the frequency at which synchronization occurs is: 0.5f = 2 × 0.25f.

The structural diagram of the detector single-circuit parametric scatterers presented figure 1. Elements: 1 - a sinusoidal signal generator, 2-frequency multiplier four times, 3 - phase modulator. 4 - amplitude modulator, 5 - reference pulse generator, 6 - driver, 7, 8 - high-frequency amplifiers, 9, 10, 11 - antennas, 12 - high-frequency amplifier, 13 - analog-to-digital converter, 14-signal processor and 15 - indicator structurally coupled and - form a detector 16. Elements: 17 - a parametric diffuser and 18 - a nonlinear diffuser are also structurally connected and form a parametric diffuser - a marker with nonlinear synchronization - 19.

The signal outputs 1 and 2 of the sinusoidal signal generator 1 are connected to the input from the frequency multiplier four times 2 and to the signal input 1 of the phase modulator 3. The frequency multiplier four times 2 is connected to the signal input 1 of the amplitude modulator 4. The output of the amplitude modulator 4 is connected to the input of the high-frequency amplifier 7. The output of the high-frequency amplifier 7 is connected to the input of the antenna 10.

The output of the phase modulator 3 is connected to the input of the high-frequency amplifier 8. The output of the high-frequency amplifier 8 is connected by the microwave path to the input of the antenna 9.

The reference pulse generator 5 is connected to the input of the shaper 6.

The output 1 of the shaper 6 is connected to the control input 2 of the amplitude modulator 4, the output 2 of the shaper 6 is connected to the control input 2 of the phase modulator 3. The output 3 of the shaper 6 is connected to the auxiliary input 2 of the signal processor 14.

The antenna 11 is connected to the input of a high-frequency amplifier 12 tuned to a frequency f / 2. The output of the high-frequency amplifier 12 is connected to the input of the analog-to-digital converter 13. The output of the analog-to-digital converter 13 is connected to the signal input 1 of the signal processor 14, the output of the signal processor 14 is connected to the input of the indicator 16.

In the irradiation zone of antennas 9, 10, 11 there is a parametric diffuser-marker with non-linear generation of clock signals 19, consisting of a structurally integrated parametric diffuser 17 and non-linear diffuser 18.

The detector single-circuit parametric scatterers works as follows.

Sine signal generator 1 generates a continuous signal at a frequency f / 4 at its outputs 1 and 2. From output 2, this signal is fed to the input of multiplier 2, where its frequency increases four times. At the output of the multiplier 2, a signal is formed at a frequency f, which is fed to the signal input 1 of the amplitude modulator 4.

At the same time, the signal at a frequency f / 4 from the output 1 of the sinusoidal signal 1 is fed to the signal input 1 of the phase modulator 3.

At the same time, the reference pulse generator 5 generates at its output a clock sequence supplied to the input of the shaper 6. This clock sequence synchronizes the operation of the radiating part of the detector 16, its conditional waveform is shown in figure 2, curve 1.

This clock sequence is converted at the output 1 of the shaper 6 into a sequence of video pulses to control the amplitude modulator 4, and at the output 2 to a sequence of video pulses to control the phase modulator 3.

In Fig. 2, curve 2 is a conditional waveform of one pulse of a sequence of video pulses of control of a phase modulator 3: In Fig. 2, curve 3 is a conditional waveform of a video pulse of a sequence of video pulses of control of a phase modulator 4. In this case, the video pulse of a sequence of video pulses of control of a phase modulator 4 contains information about the beginning and the end of the radiation of the pulses of the pump signal, And the pulse of the sequence of video pulses controlling the phase modulator 3 contains inf Description of the value of the current symbol of the selected binary coding law: positive and negative polarities correspond to opposite symbols. The delay between the edges of the video pulses of the sequence of video pulses of control of the amplitude modulator and the sequence of video pulses of control of the phase modulator is related to the time required for transients.

The control signals of the amplitude modulator 4 are generated at the output 1 of the shaper 6 in the form of video pulses following each other after a certain period of time. All control signals have the same duration and polarity. The position of the leading edge of the video control pulse of the amplitude modulator 4 is somewhat behind the leading edge of the video control pulse of the phase modulator 3. The position of the leading edge of the video control pulse of the amplitude modulator 4 is determined by the position of the leading edge and corresponds to the specified duration τ of the pump pulse.

The control signals of the phase modulator 3 are generated at the output 2 of the shaper 6 and fed to the control input 2 of the phase modulator 3. The phase modulator 3 generates a signal in accordance with the polarity of the control video pulses. As a result, a sequence of narrow-band coherent auxiliary radio pulses following one after another is formed with a high-frequency filling frequency f / 4, with a duration of each of the paired radio pulses τ ₁ , with τ ₁ << τ. The phase of each current radio pulse is determined by the selected coding law. In this case, the symbol “1” corresponds to a zero phase value, and the symbol “0” corresponds to a phase value that differs by π / 2.

Figure 2, curve 4 presents the conditional waveform of one radio pulse sequence of narrow-band coherent next to each other auxiliary radio pulses.

The formed sequence of packets of narrow-band coherent pairs of successive auxiliary radio pulses with a frequency of high-frequency filling f / 4 passes through a high-frequency amplifier 8 and antenna 9, with the help of which it is radiated into space in the direction of a parametric scatterer-marker with non-linear generation of clock signals 19 and irradiates the one entering into it composition nonlinear diffuser 18.

On the nonlinear scatterer 18, the sequence of narrow-band coherent auxiliary pulses following one after another is re-emitted in the form of a sequence of clock pulses with a frequency f / 2, which irradiate the parametric scatterer 17. The conditional waveform of one radio pulse of this clock sequence is shown in Fig. 2, curve 5.

Simultaneously, the control signals of the amplitude modulator 4 are fed to the control input 2 of the amplitude modulator 4. The amplitude modulator 4 in accordance with the control signal at the input 2 forms a sequence of rectangular radio pulses with a high-frequency filling frequency f.

As a result, a sequence of packs of narrow-band coherent rectangular radio pulses of a pump signal with a high-frequency filling frequency / and a duration of radio pulses τ is formed. This signal is amplified by amplifier 7 and emitted by antenna 10 in the direction of the parametric scatterer - marker with non-linear generation of clock signals 19 and irradiates the parametric scatterer 17 included in it. The conditional waveform of one pulse of this sequence is shown in Fig. 2, curve 6.

On the parametric scatterer 17, the radio pulses of the pump signal at a frequency f are induced, while at this point a synchronizing radio pulse at a frequency f / 2 has already been induced on it. Under these conditions, the process of generating a signal at a frequency f / 2 ceases to be random and a sequence of packs of narrow-band coherent radio pulses of the response signal is formed on the parametric diffuser 17. Each radio pulse of this sequence corresponds to the symbol of the selected coding law, and the phase of each pulse of this sequence coincides with the phase of the synchronizing radio pulse. Figure 2, curve 7 presents the conditional waveform of one pulse of the sequence of the response signal.

The radio pulses of the scattered signal are received by the antenna 11, amplified by a high-frequency amplifier 12 and fed to the input of an analog-to-digital converter 13, where the input signal is digitized. The digitized signal is fed to the signal processor 14, where coherent accumulation is performed according to an algorithm that provides the maximum level of coherent accumulation of the received signal corresponding to the selected coding law. The result of coherent accumulation is compared with a threshold, when exceeded, a signal is sent to indicator 15 about target detection.

As the generator of the sinusoidal signal 1, a standard generator G4-164 can be used. Multiplier 2 can be manufactured according to [S.A. Drobov, S.I. Bychkov. Radio transmitting devices // Sov. Radio, M., 1968, pp. 117-123]. Phase modulator 3 can be implemented according to [S.A. Drobov, S.I. Bychkov Radio transmitting devices // Sov. Radio, M.1968, pp. 299-335]. Amplitude modulator 4 can be implemented according to [S.A. Drobov, S.I. Bychkov. Radio transmitting devices // Sov. Radio, M., 1968, pp. 240-277]. As a generator of reference pulses 5, a standard generator G5-28 can be used, 6 - the shaper can be implemented according to [V.G. Gusev, Yu.M. Gusev. Electronics // M. Higher School, 1991, 2nd edition revised and expanded, pp. 489-585]. As high-frequency amplifiers 7, 8, amplifiers from a standard generator G4-128 can be used. As antennas 9, 10, 11, antennas P6-33 can be used. As a high-frequency amplifier 12, a standard low-noise amplifier MAX 2640 can be used. As an analog-to-digital converter 13, an ZET 230 ADC can be used. As a signal processor 14, a TMS 320 C 2000 signal processor can be used. The operation algorithm can be generated on basis [V.I. Tikhonov. Optimum signal reception. M. Radio and Communications, 1983, pp. 37-60]. As an indicator 15, a Pentium 4 computer can be used.

Parametric diffuser-17 can be made on the basis of the prototype according to [Non-linear passive marker - parametric diffuser, patent RU 2336538 C2]. Non-linear diffuser-18 can be based on [N.Yu. Babanov, S.V. Lartsov On the characteristics necessary to describe the spatial properties of simple nonlinear scatterers. Radio engineering, 2009, No. 5, pp. 34-39].

Thus, the proposed technical solution will allow for a more efficient search for parametric scatterers-markers, as it allows for the simultaneous and efficient occurrence of two non-linear processes in the inventive device: parametric generation and non-linear generation of clock signals at the frequency of parametric generation.

Claims (1)

A parametric scatterer is a marker with nonlinear generation of clock signals, consisting of a nonlinear parametric scatterer in the form of an antenna system connected to a parametric generator, characterized in that its design includes a nonlinear scatterer consisting of an antenna and a nonlinear element, the frequency of the nonlinear product for which designed non-linear diffuser, equal to the frequency of parametric generation of a parametric generator.

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