RU2671247C1 - Method of compensation of interference and radar station for its implementation - Google Patents

Abstract

FIELD: radar ranging and radio navigation.

SUBSTANCE: inventions relate to the field of radar and can be used in radar stations (radar) to protect, inter alia, from impulse and response interference. In the method of compensating interference received from the side direction of the side lobes of the antenna pattern, based on the reception of radiation from the source of interference by two receiving channels – the main and additional, calculating the correlation between the interference signals in these channels and the subsequent compensation of interference using the auto-compensator, when the level of impulse noise is exceeded in the additional receiving channel, the level of impulse noise in the main receiving channel forms a gate, for the duration of which the autocompensator is activated. Radar station for implementing the claimed method for compensating interference contains a primary and secondary antenna, a primary and secondary receiving channels, an autocompensator, comparison circuit of the signals of the main and additional receiving channels, the autocompensator gating device, which are definitely connected to each other.

EFFECT: compensation of the impulse noise received from the side directions by the side lobes of the antenna pattern, and the elimination of the compensation of the reflected signal received by the main beam.

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Description

The claimed technical solutions relate to the field of radar and can be used in radar stations (radar) for protection, including from impulse and response interference.

Big problems to the operation of the radar create intentional active, including pulsed interference [Reference. Radio engineering systems. Fundamentals of construction and theory. Edited by Y.D. Shirman chap. 6.4.1, p. 79] acting on the radar along the main beam and side lobes of the antenna radiation pattern (BOTTOM) [Protection from radio interference, ed. M.V. Maksimova, M. Sov. Radio, 1976, p. 60]. Pulsed interference is energetically more beneficial for the director, since with a small average power the pulsed interference power can be very large. As a result of the action of pulse interference, false detection of targets occurs. With a sufficiently large interference power, it is detected not only in the main beam, but also when receiving from the lateral direction the bottom lobes of the BOTTOM, as a result of which, when the pulse repetition rate is significantly higher than the sounding frequency, a large number of false signals (marks) are random or stationary, in the simplest case or moving at a speed set by the director of the interference, in the case of synchronous response interference. In all cases, interference pulses are perceived as reflected from the targets, so they capture and tie the path along them [S.Z. Kuzmin - Fundamentals of designing systems for digital processing of radar information p. 109] with its subsequent reset, in case of non-synchronous interference, or maintaining a false path, in the case of synchronous interference with a varying delay. As a result, the response interference leads to an overload of the signal processing devices and tracking of the target traces.

A known method of suppressing response impulse noise (RIA), received from the lateral direction by the side lobes of the directivity pattern (LH) of the main radar antenna, which is carried out using the system of suppressing side lobes, which contains the main and additional receiving channels with the directivity pattern of the additional antenna that overlaps the side lobes of the daylight main antenna and video frequency subtraction circuit. The gains of the antenna and the receiver of the auxiliary channel are selected so that for interference received by the side lobes of the antenna beam of the main receiving channel, the condition Uп1> Uп0 is fulfilled,

where Uп1 and Уп0 are the amplitudes of the interference pulses at the output of the additional and main receiving channels. The signals are transmitted to the output of the subtraction circuit only in the case of Uп1> Uп0 and actually block the passage of signals through the main channel. Therefore, the impulse noise received by the side lobes of the main antenna beam will be suppressed [Fundamentals of the construction of radio-technical troops, Ch. 5.7.1 Amplitude spatial selection of impulse noise. The textbook, edited by Ph.D. V.N. Tyapkina. Krasnoyarsk, Siberian Federal University 2011].

A disadvantage of the known method of suppressing impulse noise is that when the signal in the auxiliary channel is higher than the signal of the main channel, the subtraction circuit actually blocks the passage of any signals, including those received from the inspected direction, reflected from the targets and coinciding in time with the impulse noise, since subtracting by video frequency does not take into account phase differences, which is equivalent to a ban, and this reduces the probability of target detection.

Known closest to the proposed method of compensation for continuous noise received on the side lobes [Reference. Radio engineering systems. Fundamentals of construction and theory. Edited by Y.D. Shirman, Ch. 25.4.2, p. 436] based on the reception of the radiation of the interference source by two receiving channels - the main and additional, calculating the correlation between the signals in these channels and the subsequent compensation of active interference using the auto-compensator.

Known closest to the proposed radar (ibid., Chap. 25.4.3 p. 436) (Fig. 1), containing two antennas, the main 1 and additional 2, two receiving channels - the main (OK) 3, additional (DK) 4 and auto-compensator 5, the output of the main antenna 1 is connected to the input OK 3, the output of the additional antenna 2 is connected to the input of the DC 4, the outputs of the DC 4 and OK 3 are connected to the corresponding inputs of the auto-compensator 5.

The method and radar work as follows. Continuous interference received by the main 1 and additional 2 antennas enters through the main 3 and additional 4 channels to the corresponding inputs of the autocompensator 5. In the autocompensator, the ratio of the interference levels, their alignment, and antiphase addition are determined by the correlation method. In this case, the output of the auto-compensator 5 is compensated for interference.

The response time constant of the auto-compensator is chosen to be much larger than the duration of the probe pulse, so that the signal from the target is not suppressed. Therefore, auto-compensators are not used for auto-compensation of impulse noise.

Thus, the technical problem to be solved (technical result) is the compensation of the impulse noise received by the side lobes of the DND and the exclusion of compensation of the reflected signal received by the main beam.

The technical result (solution to the problem) is achieved by the fact that in the method of compensating for interference received from the lateral direction by the side lobes of the antenna radiation pattern, based on the reception of the radiation of the interference source by two receiving channels - the main and additional, calculating the correlation between the signals in these channels and the subsequent interference compensation using the auto-compensator according to the invention when the level of impulse noise in the additional receiving channel exceeds the level of impulse noise in the main receiving space a gate is formed on the side, for the duration of which they include an auto-compensator.

The technical result (solution to the problem) is achieved by the fact that in the radar station to implement a method of compensating for interference, containing the main and additional antennas, the main and additional receiving channels and the auto-compensator, the antenna outputs are connected to the inputs of the corresponding receiving channels, the outputs of the receiving channels are connected to the first and second according to the invention, a circuit for comparing signal levels of the primary and secondary receiving channels, a strobing device is included of the autocompensator, the outputs of the receiving channels are connected to the first and second inputs of the signal level comparison circuit of the main and additional receiving channels, respectively, the output of the comparison circuit is connected to the input of the gating device, the output of which is connected to the third input of the autocompensator.

The essence of the method and radar is as follows (Fig. 2).

The impulse noise is received by the main antenna from the lateral direction due to the side lobes of the beam and an additional antenna, the diagram of which overlaps the side lobes of the main antenna. The received signals arrive respectively in the main and additional channels, and then to the corresponding inputs of the comparison circuit and auto-compensator. From the output of the comparison circuit, the signal, in case of an excess of the interference pulse in the additional channel, is fed to the gating device, the strobe of which includes an auto-compensator. In this case, the auto-compensator only works during the strobe. In the intervals between the gates, the auto-compensator is closed and the noise of the auxiliary channel does not degrade the radar noise figure. In addition, the auto-compensator provides for the storage of its state for a time between the gates. The strobe enters the memory circuit, which stores the parameters of the auto-compensator from the end of the strobe to the beginning of the next strobe. Thus, a sequential, from strobe to strobe, increase in the coefficient of suppression of interference pulses to the maximum possible value occurs. The higher the pulse repetition rate compared to the sensing period, the faster the auto-compensator can reach maximum compensation mode. Moreover, if the impulses of the interference received from the lateral direction are superimposed on the reflected signal from the target received from the inspected direction, then the interference will be compensated, and the signal from the target will be preserved due to phase differences.

The invention is illustrated by drawings:

FIG. 1 is a diagram of a radar for implementing the method of the prototype;

FIG. 2 diagram of a radar for implementing the inventive method.

The claimed radar, for the implementation of the claimed method of noise compensation (Fig. 2) contains the main antenna 1, additional antenna 2, main channel 3 and additional channel 4, auto-compensator 5, signal level comparison circuit 6, gating device 7, outputs of antennas 1 and 2 are connected respectively, to the inputs of the channels OK 3 and DC 4, the output of OK 3 is connected to the first inputs of the comparison circuit 6 and auto-compensator 5, the output of DC 4 is connected to the second inputs of the comparison circuit 6 and auto-compensator 5, the output of the comparison circuit 6 is connected to the input of the strobe device 7, the output of which is connected to the third input of the auto-compensator 5, the output of which is the output of the radar.

Let us consider in more detail the feasibility of the method (Fig. 2) using a specific example. The signals received by the main 1 and additional 2 antennas, respectively, are supplied to the inputs OK 3 and DC 4, the outputs of which are respectively supplied to the inputs 1 and 2 of the comparison circuit 6 and auto-compensator 5. In scheme 6, the signal levels in OK 3 and in the DC are compared 4. If the signal in the recreation center 4 exceeds the signal level in OK 3, then the output of the comparison circuit 6 generates a signal supplied to the gating device 7, where a strobe is formed, equal in duration to the interference pulse, the level of which exceeded the signal level in OK 3. The formed strobe from exit at the gating device 7 is fed to the third input of the auto-compensator 5 and turns it on for the duration of the strobe. In addition, the auto-compensator provides for the storage of its state for a time between the gates. The strobe enters the memory circuit, which stores the parameters (control voltage) of the auto-compensator from the end of the strobe to the beginning of the next strobe, and the auto-compensator 5 is turned off at that moment until the next strobe appears.

The control voltage in the autocompensator is formed in the process of calculating the cross-correlation between the uncompensated interference residues at the output of the autocompensator 5 and the signal in the DC 4. During the operation of the strobe, the interference impulse may not be completely compensated, therefore, the stored control voltage is used as a stage to continue the compensation in the next strobe .

A causal relationship between the problem being solved "... compensation of impulse noise received in the lateral directions and excluding compensation of the reflected signal received by the main beam ..." and the features of the method "... when the signal level in the additional receiving channel is higher than the signal level in the main receiving channel, a strobe is formed during which the autocompensator is turned on ”consists in the fact that the autocompensator is switched on for the duration of the impulse of interference received only from the lateral direction by the side lobes of the beam.

Thus, the claimed technical result is achieved (the problem is solved).

Claims (2)

1. A method of compensating for interference received by the side lobes of the antenna radiation pattern, based on receiving radiation from an interference source by two receiving channels - the primary and secondary, calculating the correlation between the interference signals in these channels and then compensating for interference using the auto-compensator, characterized in that when the level is exceeded pulse interference in the additional receiving channel of the level of pulse interference in the main receiving channel form a strobe, for the duration of which include an auto-compensator. 2. A radar station for implementing a method of compensating for interference, comprising a primary and secondary antenna, a primary and secondary reception channels and an auto-compensator, the outputs of the antennas are connected to the inputs of the respective receiving channels, the outputs of the receiving channels are connected to the first and second inputs of the auto-compensator, characterized in that included a circuit for comparing the signal levels of the primary and secondary receiving channels, a gating device for auto-compensation, the outputs of the receiving channels are connected to the first and second the inputs of the circuit for comparing the signal levels of the main and additional receiving channels, respectively, the output of the comparison circuit is connected to the input of the gating device, the output of which is connected to the third input of the auto-compensator.

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