RU2513712C2 - Detector for detecting objects with nonlinear elements - Google Patents

Abstract

FIELD: physics, navigation.

SUBSTANCE: invention relates to search devices and is designed for detecting objects based on reception of signals resulting from secondary re-radiation with change in the spectrum of the probing signal. The detector has first and second generators which emit probing signals at close frequencies f₁ and f₂, and a receiver with a receiving antenna which receives signals in a frequency range close to the frequencies f₁ and f₂. To eliminate nonlinear combination-type interference and interference associated with blocking effects, probing signal antennae further include ferrite valves. Between the receiver and the second probing signal generator, there is a compensator for the second probing signal at the input of the receiver, consisting of two directional couplers, a variable attenuator and a variable phase-changer. A decision on detection of an object with nonlinear elements is made if a combination-type component at frequency 2f₁-f₂ or 2f₂-f₁ is detected at the input of the receiver. In another mode, the decision is made if the receiver detects a signal at frequency f₁, which is modulated with frequency F, wherein the probing signal at frequency f₂ is modulated with frequency F.

EFFECT: enabling detection of objects with nonlinear elements which may in turn include narrow-band nonlinear objects.

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Description

The invention relates to search devices that detect an object based on the reception of signals resulting from secondary re-emission with a change in the spectrum of the probe signal.

Known for [Gorbachev AA, Features of sounding by electromagnetic waves of media with non-linear inclusions // Radio Engineering and Electronics, 1996, N2, pp. 16-18] detector of objects containing non-linear scatterers.

The detector of objects containing nonlinear scatterers, consisting of a probe signal generator, the signal output of which is connected to the input of the bandpass filter at frequency f, and the output of the bandpass filter at frequency f is connected to the emitting antenna, in addition, the detector of objects containing nonlinear scatterers is included a receiving antenna, the output of which through a second bandpass filter at a frequency of 2f or 3f is connected to the input of the receiver.

The operation of the detector of objects containing nonlinear scatterers is that in the direction of the intended location of the object containing nonlinear scatterers, a probing signal is emitted at a frequency f and a backscattering signal at a frequency of 2f or 3f is received, upon detection of which a decision is made about the presence of a detection zone an object containing nonlinear scatterers.

The operation of the detector of objects containing nonlinear scatterers is based on the use of the effect of nonlinear scattering of radio waves. In accordance with the indicated effect, the emf of the probe signal is induced on a nonlinear element that is part of a nonlinear scatterer. This EMF causes a probing signal current flowing through the nonlinear element, which is distorted due to the nonlinearity of the current-voltage characteristic of the nonlinear element, while its spectrum is enriched with spectral components at the harmonics frequencies of the probing signal. In this case, the currents at the frequencies of the 2nd and 3rd harmonics are the largest. These currents form on the nonlinear element of the EMF at the harmonic frequency, which is the reason for the appearance of spectral components in the backscattering signal at the harmonic frequencies of the probe signal.

The disadvantage of the analog device is that the nonlinear scatterers that are part of the detection object must have certain frequency properties, namely, to ensure good conversion of the current flowing through the nonlinear element with an electromagnetic wave both at the frequency of the probing signal and at the frequency of the second or third harmonics of the probe signal. The indicated equidistance of the spectrum is rather difficult to ensure even in special devices, and it is unlikely to be expected to be provided a priori.

Partially indicated drawback is overcome in the device for detecting objects containing non-linear elements, known from [Kuznetsov AS, Kutin GI Methods for studying the effect of nonlinear scattering of radio waves // Foreign Electronics, 1985, No. 4, p. 32-36]. This device is selected as a prototype and includes a first probe signal generator, a first bandpass filter of the probe signal at a frequency f ₁ and a first emitter, and, in addition, the detector containing objects with nonlinear elements includes a second probe generator, a second bandpass a probe signal filter at a frequency f ₂ and a second emitter, the detector of objects containing non-linear elements also includes series-connected receivers an antenna, a third bandpass filter with a leakage band tuned to the frequency of one of the combinational components resulting from the nonlinear interaction of the probe signal with a frequency f ₁ and a probe signal with a frequency f ₂ , and a receiver.

The operation of the detector of objects containing non-linear elements is that in the direction of the intended location of the object containing the non-linear element, a two-frequency probe signal is emitted, the spectrum of which contains spectral components concentrated near the frequencies f ₁ and f ₂ , and a backscattering signal is received, when in this case, when detecting differences in the spectral composition of the backscattering signal from the spectral composition of the probe signal, a decision is made on the presence of an object in the detection zone with holding a nonlinear element.

The operation of the detector of objects containing non-linear elements is also based on the use of the effect of non-linear scattering of radio waves. In this case, additional spectral components also appear as a result of nonlinear distortion of the current flowing through the nonlinear element induced by the probing signal. In this case, the second or third order intermodulation combinational components are a useful scattered signal. This removes the requirement of equidistance for the bandwidth of search objects.

The disadvantage of the prototype is that there are significant problems when trying to detect objects that have only one bandwidth. Such objects can be, for example, elements of an active antenna array, transmitters and receivers.

In [Lartsov S.V. On nonlinear scattering when using multi-frequency and single-frequency sounding signals // Radio Engineering and Electronics, 2001, T.46, No. 7, S.833-838] it is proposed to use the specified detector for the detection of narrow-band nonlinear objects. To do this, it was proposed to use a two-frequency probe signal with close frequencies f ₁ ≈ f ₂ , and as a received signal a third-order nonlinear product with a frequency of 2f ₁ -f ₂ or 2f ₂ -f ₁ , which are close to the frequencies f ₁ and f ₂ . This sensing option allows you to solve the problem of sensing nonlinear objects with a narrow frequency band, however, there are two technical problems due to the fact that the frequency bands of the first, second and third bandpass filters overlap: 1) the probing signal generators become sources of interference at the frequencies of useful signals; 2) the input circuit of the receiver, being a nonlinear element, also become sources of interference at the frequency of the received signal, in addition, the input circuit of the receiver is subject to interference due to the blocking effect.

The task is to more efficiently search for objects containing nonlinear elements.

The technical result is the ability to detect objects containing non-linear elements that may contain narrow-band non-linear objects.

This technical result is achieved due to the fact that a new technical solution is proposed in the form of a detector of objects containing non-linear elements, which includes a first probe signal generator, a first pass filter of the probe signal at a frequency f ₁ and a first emitter, in addition to the detector objects containing nonlinear elements, consistently included a second probe signal generator, a second band-pass probe signal at a frequency f ₂ and a second the emitter, the detector of objects containing non-linear elements also includes a series-connected receiving antenna, a third band-pass filter with a passband tuned to the frequency of one of the third-order combination components, formed by a probing signal with a frequency f ₁ and a probing signal with a frequency f ₂ , and a receiver, in addition, between the output of the first bandpass filter of the probe signal and the input of the first emitter, the first ferrite valve is turned on, in addition, between the output of the second a bandpass filter of the probe signal and the input of the second emitter includes a second ferrite valve, in addition, the detector of objects containing nonlinear elements includes a compensator of the second probe signal at the receiver input, consisting of a series directional first coupler, variable attenuator, variable phase shifter and second directional coupler, wherein the first directional coupler is connected between the second probe signal generator and the second bandpass filter m of a probe signal to a frequency f ₂ so that the input of the first directional illuminator is connected to the output of the second probe signal generator, the first output of the first directional coupler is connected to the input of the second band-pass filter of the probe signal to frequency f ₂ , the second output of the first directional coupler is connected to the input of the variable attenuator and the second directional coupler is connected between the third bandpass filter and the receiver so that the first input of the second directional coupler is connected to the output of the variable phase shifter, the second input of the second directional coupler is connected to the output of the third band-pass filter, and the output of the second directional coupler is connected to the input of the receiver.

The essence of the invention lies in the fact that the sources of interference that interfere with the implementation of the sounding method proposed in [Lartsov SV On nonlinear scattering when using multi-frequency and single-frequency sounding signals // Radio Engineering and Electronics, 2001, T.46, No. 7, S.833-838], namely, ferrite gates are introduced into the design of the radiating antennas that do not allow the second sounding signal to arrive at the input of the generator of the first probe signal and vice versa - the first probe signal to enter the input of the generator of the second probe signal. As a result, the output stages of the probes signal generators cease to be sources of Raman noise at frequencies 2f ₁ -f ₂ and 2f ₂ -f ₁ . To eliminate the appearance of the same interference at the input circuits of the receiver, it is proposed to introduce into the design a compensator for the second probe signal at the input of the receiver. For this, part of the power of the second sounding signal is selected using the first directional coupler and fed to the input of the receiver. A signal at the frequency of the second sounding signal, which appears as a result of re-reflections from surrounding objects, is already arriving at the input of the receiver. This signal is compensated by an antiphase and equal in amplitude signal from the compensator. The amplitude and phase of the compensating signal are selected using a variable attenuator and a variable phase shifter.

In addition, the elimination of the second sounding signal at the input of the receiver allows you to implement another new detection mode of objects containing non-linear elements, which is based on the use of the blocking effect. In this case, the property of a nonlinear element is used to change its impedance under the action of the current flowing through it. As a result, under the action of the spectral component of the probe signal at a frequency f ₂ , which is amplitude-modulated with a frequency F, the effective scattering surface of an object containing a nonlinear element also becomes variable with the same frequency F. The backscattering signal at a frequency f ₁ from such an object will modulated with frequency F. The frequency band that is required for such a sounding method is equal to f ₁ -f ₂ + 2F.

The invention is proposed to be used as part of the search engine shown in figure 1.

Here 1 is a search object containing in its design a nonlinear element and a band-pass filter; 2 - the first generator of the probe signal to the frequency f ₁ , 3 - the first band-pass filter of the probe signal to the frequency f ₁ , 4 - the first emitting antenna, consisting of a ferrite valve 5 and the emitter 6, 7 - the second generator of the probe signal to the frequency f ₂ , 8 - a second band-pass filter of the probing signal at a frequency f ₂ , 9 - a second emitting antenna, consisting of a ferrite gate 10 and a radiator 11, 12 - a receiving antenna, 13 - a third band-pass filter, 14 - a receiver, 15 - a compensator of the second probing signal, consisting of first directional branch Itel 16, variable attenuator 17, variable phase shifter 18, the second directional coupler 19.

The signal output of the first probe signal generator 1 is connected to the input of the first bandpass filter of the probe signal 2, and the output of the first bandpass filter of the probe signal 2 is connected to the input of the ferrite valve 4, the output of which is connected to the input of the emitter 5.

The signal output of the second probe signal generator 7 is connected to the input of the first directional coupler 16, the first output of the first directional coupler 16 is connected to the input of the second band-pass filter 8, the output of which is connected to the input of the ferrite valve 10, the output of which is connected to the input of the emitter 11.

The output of the receiving antenna 12 is connected to the input of the third band-pass filter 13, the output of which is connected to the first input of the second directional coupler 19, and the output of the directional coupler 19 is connected to the input of the receiver 14. The second output of the directional coupler 16 is connected to the input of the variable attenuator 17, the output of which is connected to the input of the variable phase shifter 18, the output of which is connected to the second input of the second directional coupler 19. The emitters 6 and 11, as well as the antenna 12 are directed in the direction of the search object 1, containing its design is a non-linear element and a band-pass filter.

The search engine can operate in one of three modes.

The first mode is called calibration. The purpose of this mode is to provide the ability to receive a useful signal. The task that is being solved is the adjustment of the compensator 15 of the second probe signal to eliminate the blocking effect of the second probe signal on the receiver 14. In this mode, turn on the second probe signal generator 7 to emit a continuous signal with a frequency of 12 and select the settings of the variable attenuator 17 and variable phase shifter 18 so that the signal at a frequency f ₂ at the input of the receiver 14 becomes zero.

In the second mode, the first probe signal generator 2 is turned on to generate continuous oscillation with a frequency f ₁ and the second probe signal generator 7 is turned on to generate a signal with a frequency f ₂ and with amplitude modulation with a frequency F. After that, the receiver 14 is tuned to receive signals at a frequency f ₁ and demodulating a received signal to determine whether or not the modulated signal is amplitude modulated with the frequency F. When a signal at the frequency f ₁ with amplitude modulation with a frequency F decide about the presence of LP e irradiation search object containing in its structure a nonlinear element and a bandpass filter.

In the third mode, the first probe signal generator 2 is turned on to emit a continuous signal with a frequency of f ₁ , and the second probe signal generator 7 is turned on to emit a continuous signal with a frequency of f ₂ . After that, the receiver 14 is tuned to receive signals at a frequency of 2f ₁ -f ₂ and at a frequency of 2f ₂ -f ₁ . When a signal is detected at a frequency of 2f ₁ -f ₂ or at a frequency of 2f ₂ -f ₁ , a decision is made whether there is a search object in the irradiation zone that contains a nonlinear element and a bandpass filter in its design.

As the first and second probing signal generators 2 and 7, measuring generators G4-159 can be used. As the emitters 6, 11 and the receiving antenna 12 can be used measuring antennas P6-33. As the receiver 14 can be used measuring receiver type SMV-8.5.

As valves 5, 10, standard valves of the FPVN3-71 type manufactured by the Magneton plant can be used.

The first band-pass filter 3, the second band-pass filter 8 and the third band-pass filter 13 can be manufactured according to [V.P. Leonchenko, A.L. Feldstein, L.A. Shelyapinsky. Calculation of strip filters on oncoming rods. M .: Communication, 1975].

As the first and second directional couplers 16 and 19, standard directional couplers of the type HO-15 manufactured by the Radial plant can be used.

As a variable attenuator 17, a standard variable attenuator of type 2.260.280 manufactured by FSUE NNIPI Quartz can be used.

The variable phase shifter 18 can be manufactured according to G.S. Hija. I.B. Vidak. V.L. Serebryakova. Microwave phase shifters and switches. M .: Radio and communications, 1984.

Thus, the proposed technical solution will allow for a more efficient search for objects containing non-linear elements that may contain narrow-band non-linear objects.

Claims (1)

A detector of objects containing non-linear elements, consisting of a series-connected first probe signal generator, a first band-pass filter of the probe signal at a frequency f ₁ and a first emitter, in addition, a detector of objects containing non-linear elements includes a second probe signal generator, a second bandpass filter sounding signal on frequency f ₂ and a second emitter, and a part of the detector of objects containing nonlinear elements are consecutively flax included a receiving antenna, a third bandpass filter with a passband tuned to the frequency of one of the third-order Raman components formed probing signal with frequency f ₁ and a probe signal with a frequency f _2, and a receiver, characterized in that between the output of the first bandpass filter probe of the signal and the input of the first radiator, the first ferrite valve is turned on, in addition, between the output of the second band-pass filter of the probing signal and the input of the second radiator, a second ferrite valve is turned on b, in addition, the detector of objects containing non-linear elements includes a compensator for the second probe signal at the input of the receiver, consisting of a series-connected first directional coupler, variable attenuator, variable phase shifter and second directional coupler, while the first directional coupler is connected between the second generator the probe signal and the second bandpass filter of the probe signal at a frequency f ₂ so that the input of the first directional coupler is connected to the output the second probe signal generator, the first output of the first directional coupler is connected to the input of the second bandpass filter of the probe signal at a frequency f ₂ , the second output of the first directional coupler is connected to the input of the variable attenuator, and the second directional coupler is connected between the third bandpass filter and the receiver so that the first input the second directional coupler is connected to the output of the variable phase shifter, the second input of the second directional coupler is connected to the output of the third strip filter, and the output of the second directional coupler is connected to the input of the receiver.