RU2444751C2 - Active interference compensation device - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: to the known active interference compensation device there additionally introduced is in-series connected first signal filter, phase shifter, the second multiplier, the second adder; the second input of the second multiplier is connected to correlator output; input of the first signal filter is connected to output of compensation antenna and input of the second interference filter the output of which is connected to the first input of the first multiplier and the first input of phase difference metre the output of which is connected through amplifier to the second input of phase shifter, and the second input - to the second input of the first adder and the output of the first interference filter the input of which is connected to output of the main antenna and through the second signal filter - to the second input of the second adder the output of which is the device output.

EFFECT: avoiding the efficiency loss of active interference compensator at simultaneous action of passive interference.

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Description

The invention relates to radar, can be used in equipment for detecting targets against a background of combined interference - active radiation and passive reflection.

A device for compensating for interference with systems of automatic gain control (AGC) and phase-locked loop (PLL) [1, p.232], containing the main and compensation receivers. The main receiver includes an antenna, a mixer, a local oscillator, and an intermediate frequency amplifier (UPCH) with an AGC system, and the main elements of a compensation receiver are an antenna, an amplification amplifier, an AGC system, a mixer, a local oscillator, a controller, and a phase detector. In the adder is the addition of voltages generated in the main and compensation receivers. The disadvantage of this device is the decrease in the effectiveness of the suppression of active interference in the presence of passive reflections.

A heterodyne auto-compensator is also known [2, p. 43], which contains a main channel with a converter and an adder, as well as a compensation channel with correlation feedback implemented using a correlator including a multiplier and a narrow-band integrating filter. The disadvantage of this device is the low coefficient of suppression of active interference in the presence of passive interference.

The closest in technical essence (the prototype to the proposed invention) is a device for the compensation of active interference [3, p. 89], containing a series-connected compensation antenna, a multiplier and an adder, the second input of which is connected to the main antenna, and the output to the first input of the correlator, the second input of which is connected to the output of the compensation antenna, and the output is connected to the second input of the multiplier, the output of the adder is the output of the device.

Active noise interference (ACP) received by the main antenna through the adder is fed to the first input of the correlator, to the second input of which comes the interference received by the compensation antenna. The correlator produces a weighting coefficient for the mutual correlation of interference received by the main and compensation antennas. The interference from the output of the compensation antenna is multiplied in the multiplier by the weight coefficient and fed to the adder, where it is subtracted from the interference received by the main antenna.

The presence of correlation feedback allows the device to tune to the characteristics of active interference and provide its suppression. However, under the combined effects of active noise and passive reflections, the spatially distributed nature of passive reflections destroys the spatial correlation of point active radiation signals, and the wide energy spectrum of the latter destroys the temporal correlation of passive reflections, which complicates the process of setting up adaptive devices for suppressing interfering signals [4, p. 39] .

Thus, the disadvantage of this device is the reduction of the coefficient of suppression of active interference on the background of passive interference.

The problem to which the invention is directed, is to increase the suppression ratio of the active interference compensator in the presence of passive interference.

The technical result consists in eliminating a decrease in the effectiveness of the active interference compensator with simultaneous exposure to passive interference.

The technical result is achieved by the fact that in the known device for the compensation of active interference, containing the main and compensation antennas, the first multiplier and the first adder are connected in series, the output of which is connected to the first input of the correlator, the second input of which is connected to the first input of the first multiplier, the second input of which is connected to the output of the correlator, additionally connected in series are the first signal filter, phase shifter, second multiplier, second adder, second input of the second a multiplier is connected to the output of the correlator, the input of the first signal filter is connected to the output of the compensation antenna and the input of the second interference filter, the output of which is connected to the first input of the first multiplier and the first input of the phase difference meter, the output of which is connected to the second input of the phase shifter through the amplifier, and the second input with the second input of the first adder and the output of the first interference filter, the input of which is connected to the output of the main antenna and through the second signal filter to the second input of the second adder, the output of which is output device.

The essence of the invention is based on the use of frequency differences between active and passive interference, when the width of the spectrum of active noise interference exceeds the width of the spectrum of the echo signal, and setting the active interference compensator at a frequency that does not coincide with the frequency of the echo signal. This eliminates the influence of passive interference on the performance of the auto-compensator while suppressing active interference.

The structural diagram of the proposed device is shown in the figure.

The proposed active interference compensation device consists of a main antenna 1, a first interference filter 2, a phase difference meter 3, a first adder 4, a compensation antenna 5, a second interference filter 6, a first multiplier 7, an amplifier 8, a correlator 9, a first signal filter 10, a phase shifter 11, the second multiplier 12, the second adder 13, the second filter of the signal 14 connected, as shown in the figure.

The first filter of the signal 10 and the second filter of the signal 14 are consistent with the spectrum of the echo signal, including passive interference.

The first interference filter 2 and the second interference filter 6 are detuned relative to the spectrum of the echo signal and allow only active interference to pass through.

The device operates as follows.

The active noise interference received by the main antenna 1 passes through the first interference filter 2 and the first adder 4, and is fed to the first input of the correlator 9, the second input of which is the active noise interference received by the compensation antenna 5 and passed through the second interference filter 6. Correlator 9 produces a weighting coefficient of cross-correlation of active noise interference, adopted by the main 1 and compensation 5 antennas. The interference from the output of the second interference filter 6 is multiplied in the first multiplier 7 by a weight factor and fed to the first input of the first adder 4, where it is subtracted from the active interference that passed through the first interference filter 2, which ensures its suppression. Active noise interference received by the compensation antenna 5 also passes through the first filter of the signal 10, the phase shifter 11 to the first input of the second multiplier 12, where it is multiplied by the weight coefficient formed in the correlator 9, and fed to the first input of the second adder 13. To the second input of the second the adder 13 comes active noise interference received by the main antenna 1 and passed through the second filter of the signal 14. As a result, the second adder 13 provides compensation for active noise interference acting on the frequency of the signal.

Since the autocompensator is tuned at a frequency f _n different from the frequency f _s , the ratio of the active noise suppression coefficient when tuning the autocompensator to a frequency f _p K (f _n ) to the ACB suppression coefficient of the autocompensator at a frequency f _with K (f _c ) is determined expression [5, p.53]

where R _ACP is the power of active noise interference;

P _ext.sh - power of the own noise of the receiving channel

τ = (dsinΘ) / C - signal delay due to the difference in the path of the radio signal to the receiving antennas;

d is the distance between the receiving antennas;

C is the wavefront propagation velocity;

Θ is the angular position of the interference source relative to the normal to the antenna;

those. there are losses in the quality of ACP suppression.

This is due to the difference in the phase shifts of the active noise interference between the main antenna 1 and the compensation antenna 5 at the frequencies of the interference filters f _n Δφ _p = 2d f _n sinΘ / C and the signal f _with Δφ _c = 2d f _n sinΘ / C, which is defined as

To increase the ACW suppression coefficient at the signal frequency, a phase difference meter 3 is used, which produces a voltage proportional to the phase difference of the ACP Δφ _p at the outputs of the first interference filter 2 and the second interference filter 6. The generated voltage in the multiplier 8 is multiplied by a factor equal to (f _p / f _s -1), and enters the phase shifter 11, which changes the phase of the ACP at the output of the first signal filter in accordance with expression (2). This eliminates the difference in phase shifts of active noise interference between the main antenna 1 and the compensation antenna 5 at the frequencies of the noise and signal filters, which leads to an increase in the suppression coefficient of the ACP at the signal frequency. Since the auto-compensator is tuned at frequencies that do not match the signal frequency, this eliminates the influence of passive interference on the quality of the auto-compensator.

Thus, the proposed device allows to increase the suppression coefficient of active interference in the presence of passive interference.

The proposed technical solution is new, because from publicly available information, devices are unknown that provide high efficiency for the suppression of active noise interference in the presence of passive interference.

The proposed technical solution is practically applicable, since standard equipment, devices and materials of widespread technology can be used for its implementation. The device can be technically implemented with both analog and digital signal processing.

Information sources

1. Protection against interference. Ed. Maximova M.V. - M .: Owls. Radio, 1976.- 496 p.

2. Adaptive interference compensation in communication channels. Yu.I. Losev, A.G. Berdnikov, E.Sh. Goykhman, B.D. Sizov; Under. ed. Yu.I. Loseva. - M .: Radio and communications, 1988 .-- 208 p.

3. Bakulev P.A., Sosnovsky A.A. Radar Systems: Laboratory Workshop. Textbook Allowance for students special. "Radio electronic systems." - M .: Radio engineering, 2007. - 160 p.

4. Adaptive radio systems with antenna arrays / Zhuravlev AK, Khlebnikov VA, Rodimov AP et al. - L .: Ed. Leningrad University, 1991 - 544 p.

5. Manzingo R.A., Miller T.U. Adaptive Antenna Arrays: Introduction to Theory: Per. from English - M .: Radio and communications, 1986. - 448 p.

Claims (1)

An active interference compensation device comprising a main and compensation antennas, a first multiplier and a first adder connected in series to the first input of the correlator, the second input of which is connected to the first input of the first multiplier, the second input of which is connected to the output of the correlator, characterized in that the first signal filter, the phase shifter, the second multiplier, the second adder are connected in series, the second input of the second multiplier is connected to the output of the input of the first signal filter is connected to the output of the compensation antenna and the input of the second interference filter, the output of which is connected to the first input of the first multiplier and the first input of the phase difference meter, the output of which is connected through the amplifier to the second input of the phase shifter, and the second input to the second input of the first the adder and the output of the first interference filter, the input of which is connected to the output of the main antenna and through the second signal filter to the second input of the second adder, the output of which is the output of the device, the first and second signal filters are consistent with the spectrum of the echo signal, including passive interference, and the first and second filter interference are upset relative to the spectrum of the echo signal and pass only active interference.