RU2265230C2 - Device for measuring non-linear radiolocation characteristics - Google Patents

Abstract

FIELD: radiolocation.

SUBSTANCE: device has set-point generator, band filter, transmitting antenna, receiver antenna and registration device, and also has amplifier, block for stabilization of heterodyne frequency, heterodyne, polarization splitter, two parallel receiver channels, each of which consists of mixer and amplifier, directional branch device and phase detector.

EFFECT: broader functional capabilities, due to measurement of cross-polarization component of reflected signal, phase shift between main and cross-polarization components of reflected signal and calculation on their basis of ellipticity coefficient and slant angle of greater axis of ellipse of polarization of reflected wave.

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Description

The invention relates to the field of radar and is intended to measure the radar characteristics of objects with "non-linear" electromagnetic properties.

Known setup for measuring the "nonlinear" effective scattering area [Steinshleiger VB, Misezhnikov GS The study of the effect of nonlinear scattering of radio waves by metal objects - Radio engineering and electronics - 1994, t.39 - No. 6 - p.902-906], containing in the transmitting channel a series-connected generator, filter and transmitting antenna, and in the receiving channel - antenna, filter, measuring receiver and recorder.

The disadvantage of this setup is the lack of the ability to measure polarization characteristics, which leads to the loss of a significant part of the information about the measurement object.

Of the known devices for measuring the "nonlinear" radar characteristics of objects, the closest in purpose and achievement of a positive effect is the stand for the study of the expanded polarization scattering matrix [Lartsov SV Investigation of the depolarizing properties of nonlinear scatterers using an extended scattering matrix. Radio engineering and electronics, 1998, volume 43, No. 2, pp. 180-184]. The stand contains a series-connected generator, a band-pass filter, a voltmeter, a polarization switch of the transmitting antenna, to the second input of which the first output of the switching device is connected, an output antenna, and a series-connected receiving antenna with a polarization switch, to the second input of which the second output of the switching device, to the output is a notch filter, and also contains an amplifier and an amplifase meter, to the input of which a generator is connected through a frequency doubler.

To assess the shortcomings of the stand, we consider one of the most important characteristics of a signal scattered by a radar target - the polarization scattering matrix.

,

,

,

. Математически матрица рассеяния записывается в виде:It is known (see D.B.Kanareykin et al. Polarization of radar signals. M; Sov. Radio, 1966) that the reflecting and polarizing properties of radar targets are most fully described by the polarization scattering matrix. This matrix relates the polarization of the irradiating wave to the reflected wave using four complex quantities

,

,

,

. Mathematically, the scattering matrix is written as:

where E _xx is the amplitude of the scattering of the target signal for the x-th polarization of the probe signal and the x-th polarization of the received signal;

E _xy is the amplitude of the signal scattered by the target for the xth polarization of the probe signal and the yth polarization of the received signal;

E _uh is the amplitude of the signal scattered by the target for the y-th polarization of the probe signal and the x-th polarization of the received signal;

E _yy is the amplitude of the signal scattered by the target for the y-th polarization of the probe signal and the y-th polarization of the received signal;

φ _xx , φ _xy , φ _yh , φ _yy are the corresponding signals.

The stand under consideration makes it possible to measure two elements of the scattering matrix:

и

and

but it does not allow to measure the cross-polarization component of the reflected signal, which is necessary for solving the problems of radar recognition by polarization characteristics: the cross-polarized component of the reflected signal; the ellipticity coefficient of the reflected signal and the angle of inclination of the larger axis of the polarization ellipse.

The problem to which the claimed device is directed is to expand the functionality of the device by providing for the measurement of the cross-polarization component of the reflected signal and the phase difference between the main and cross-polarization components of the reflected signal.

The problem is solved due to the fact that in the device for measuring the "nonlinear" radar characteristics of objects containing a master oscillator, a bandpass filter, a transmitting antenna, a receiving antenna and a recorder, a series-connected amplifier, a frequency stabilization unit of the local oscillator and local oscillator are inserted into it, inserted between the receiving antenna and the recorder are connected in series with a polarization splitter and two parallel receiving channels, each of which consists of a series-connected mixer and an amplifier, a directional coupler is inserted between the master oscillator and the bandpass filter, an amplifier is connected to the branch output and a phase detector is connected between both receiving channels, the output of which is connected to the recorder, while the transmitting antenna is circularly polarized, and two local oscillator outputs are connected to the mixers corresponding receiving channels, and the third output is to the frequency stabilization unit and the output of the bandpass filter is connected to the transmitting antenna.

,

. За счет введения расщепителя поляризации и двух приемных каналов с общим гетеродином, блоком стабилизации частоты гетеродина и фазового детектора, позволяющего измерять разность фаз между сигналами приемных каналов, и выполнению передающей антенны с круговой поляризацией. Информативность этих элементов выше, чем раздельно измеряемых элементов

,

, потому что позволяет вычислить коэффициент эллиптичности отраженной электромагнитной волны r и угол наклона большой оси эллипса поляризации β по формулам (см. Д.В.Канарейкин и др. Поляризация радиолокационных сигналов. М.: Сов.Радио, 1966 г.):The device allows you to emit electromagnetic waves of circular polarization and measure the main, cross-polarizing components of the reflected signal and the phase difference between them at the harmonics of the probe signal, which corresponds to the measurement of the elements of the scattering matrix (1)

,

. Due to the introduction of a polarization splitter and two receiving channels with a common local oscillator, a local oscillator frequency stabilization unit and a phase detector, which makes it possible to measure the phase difference between the signals of the receiving channels, and the implementation of a circularly polarized transmitting antenna. The information content of these elements is higher than separately measured elements.

,

, because it allows you to calculate the ellipticity coefficient of the reflected electromagnetic wave r and the angle of inclination of the major axis of the polarization ellipse β according to the formulas (see D.V. Kanareykin et al. Polarization of radar signals. M: Sov. Radio, 1966):

where β is the angle of inclination of the major axis of the polarization ellipse;

E _x is the amplitude of the horizontal component of the reflected signal;

E _y - the vertical component of the reflected signal;

F is the phase difference of the components E _x and E _{y of the} reflected signal.

The measured values are used in the construction of a recognition system for radar objects.

The drawing shows a structural diagram of a device for measuring the "nonlinear" radar characteristics of objects.

A device for measuring the "nonlinear" radar characteristics of objects contains (Fig. 1) a master oscillator 1, a directional coupler 2, a bandpass filter 3, a transmitting antenna 4, receiving channels 5.1, 5.2, a receiving antenna 6, a polarization splitter 7, two mixers 8.1 and 8.2 , two amplifiers 9.1, 9.2 of the receiving channels, amplifier 10, the stabilization unit of the local oscillator 11, the local oscillator 12, the phase detector 13, the recorder 14, the measurement object 15. In this case, the master oscillator 1, directional coupler 2, band-pass filter 3, transmitting antenna 4 circular polarization The equations are connected in series and connected to the measurement object 15 by means of radiated electromagnetic waves. The receiving antenna 6 is connected to a polarization splitter 7, the two outputs of which are connected to two parallel receiving channels 5.1, 5.2, each of which consists of series-connected mixers 8.1, 8.2 and amplifiers 9.1, 9.2, the outputs of which are connected to the corresponding inputs of the recorder 14, a branch output the directional coupler 2 is connected in series with the amplifier 10, the frequency stabilization unit of the local oscillator 11 and the local oscillator 12, two outputs of which are connected to the mixers 8.1, 8.2, the corresponding receiving channels, and the third output d is connected to the frequency stabilization unit 11, the second amplifier outputs 9.1, 9.2 are connected to the phase detector 13, whose output is connected to the logger 14, formed on the basis of IBM PC.

The device operates as follows.

The generator 1 generates monochromatic oscillations at a frequency f ₀ , which through a directional coupler 2 and a band-pass filter 3 pass to a transmitting antenna 4 with circular polarization, which emits them in the direction of the measurement object 15. The elliptical polarized signal at the harmonic frequency converted by the object 15 is fed to the receiving antenna 6 and onwards to a polarization splitter 7 operating in the mode of orthogonally linear decomposition of the received signal. From the outputs of the polarization splitter 7, the signals are fed to the corresponding mixers 8.1 and 8.2 of the receiving channels, then to the amplifiers 9.1 and 9.2 and then to the inputs of the recorder 14. From the branch output of the directional coupler 2, the signal at the harmonic frequency is fed to the amplifier 10 and the local oscillator frequency stabilization unit 11 and further to the local oscillator 12. The local oscillator 12 operates at a frequency nf ₀ + f _pr , where n is the harmonic number, and gives signals to the mixers 8.1 and 8.2, and from the third output of the local oscillator 12, the signal enters the frequency stabilization unit of the local oscillator 11 and is used To maintain the intermediate frequency of the receiving channels at a constant level. A phase detector 13 connected to both additional outputs of the amplifiers 9.1 and 9.2 generates a signal proportional to the phase difference Φ of the signals of both channels and transmits it to the recorder 14.

The possibility of achieving a positive effect is determined by the fact that the device contains a polarization splitter and two receive-amplifier channels, respectively, for the main and cross-polarization components of the reflected signal, which makes it possible to measure these components and the phase difference between them, and based on them to calculate the ellipticity coefficient of the reflected signal and the angle of inclination of the major axis of the polarization ellipse and, thus, to obtain additional data for calculating the recognition system of radar objects due to maintaining a polarization splitter, a phase detector, a local oscillator frequency stabilization unit, a local oscillator, a directional coupler, and a circularly polarized transmit antenna.

Claims (1)

A device for measuring the "nonlinear" radar characteristics of objects, containing a master oscillator, a bandpass filter and a transmitting antenna, a receiving antenna and a registrar, characterized in that a series-connected amplifier, a frequency stabilization unit of the local oscillator and local oscillator are inserted into it, and are inserted in series between the receiving antenna and the registrar connected polarization splitter and two parallel receiving channels, each of which consists of a series-connected mixer and receiving channel amplifier Alas, the outputs of the amplifiers of the receiving channels are connected to the corresponding inputs of the recorder, and their second outputs are connected to a phase detector, the output of which is connected to the registrar, a directional coupler is inserted between the master oscillator and the bandpass filter, the amplifier and the local oscillator frequency stabilization unit are connected to its branch output, while the transmitting antenna is circularly polarized, with two local oscillator outputs connected to the mixers of the respective receiving channels, and the third stroke - to the frequency stabilization unit and the output of the bandpass filter is connected to the transmitting antenna.