RU2530548C1 - Protection method of surveillance radar station against passive jamming received on side lobes of antenna directivity pattern - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: method is implemented by means of several additional receiving channels (ARC), the antennas of which are located in an antenna curtain of the main channel so that their phase centres do not coincide between themselves as to an angle of a place; besides, levels of the main ADP lobes of ARC are established below the level of the main ADP lobe of the main channel at least by k₁ times, and above the level of maximum ADP side lobe of this channel at least by k₂ times, where k₁ and k₂ - specified values determined with allowable losses in target detection. During a surveillance process, ADP zones of additional receiving channels control so that at any azimuth and elevation position of the main ADP lobe of the main channel in surveillance zone (SZ) the main ADP lobes of ARC can cover as to angle of the place the specified SZ zone in the whole operating range of radar station as to distance, and as to azimuth - SZ zone including position as to azimuth of the main ADP lobe of the main channel. For each increment as to distance, there measured are levels of signals at the output of the main and each of additional receiving channels, and performance of the specified criterion of availability of passive jamming is checked. If this criterion is performed at least for one of ARC, then, a decision is taken on the fact that a signal at the output of the main channel is passive jamming.

EFFECT: increase of suppression of passive jamming.

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Description

The claimed technical solution relates to the field of radar, in particular to the field of protection of survey radar stations (radar) from passive interference in the form of reflections of sounding signals by group reflectors received from the side lobes of the antenna radiation pattern (BOTTOM).

Group reflectors are reflectors located within the pulse volume of the radar. Group reflectors include reflecting fragments of the earth’s surface located within the pulse volume, rain, clouds of dipole reflectors, and in case of super-refraction, multiple atmospheric inhomogeneities near the earth’s surface, etc.

There is a method of protecting the radar from passive interference, including in the form of reflections of the probing signals by group reflectors received along the side lobes of the bottom beam, based on the selection of moving targets (SDC) due to the difference in the radial speed of the target and these reflectors (Theoretical basis of radar. Ed. V.E. Dulevich. M., Sov. Radio, 1978, p. 644-484). In this method, received signals are suppressed, which vary little from period to period (from motionless and slowly moving passive noises in the form of group reflectors), and signals that change more significantly (from moving targets) are extracted.

Since passive interference received on the side lobes of the DND is considered (like any detected signals) to be received by the main lobe of the DND, then when viewing the zone, these interference can be detected at large elevation angles of the main lobe of the DND, that is, these interference can be detected in sufficiently most of the field of view.

The known technical solution allows to provide protection from passive interference, including in the form of reflections of the probing signals by group reflectors received along the side lobes of the DND, however, with respect to the surveillance radars, this technical solution has the disadvantage that in each position of the main lobe of the DND in The field of view requires several probing signals. And since there is no time for the use of SDS in a large part of the field of view in the radars under consideration, protection from such interference is not adequately provided.

Closest to the claimed is a method of protecting the surveillance radar from passive interference received on the side lobes of the BOTTOM, including the emission and reception of sounding signals in a given viewing area of the main channel, the reception of the reflected sounding signals placed in the canvas of the main channel with an additional receiving channel, the level of the main lobe of the BOTTOM which is chosen below the level of the main lobe of the bottom of the bottom of the main channel at least k ₁ times, and above the level of the maximum side lobe of the bottom of the bottom of this channel at least k ₂ times where k ₁ and k ₂ are given values determined by allowable losses in target detection (Fig. 1). In the process of viewing the zones, the position of the bottom of the secondary receiving channel in such a way that, for any azimuthal and elevation position of the main lobe of the bottom of the bottom of the main channel in the viewing area, the main tab of the bottom of the bottom of the secondary receiving channel covers the specified area of the viewing area over the entire working range of the radar and in azimuth - the area of the field of view, including the position in azimuth of the main lobe of the bottom of the main channel. In the process of reviewing the zone, for each discrete in range, the signal levels at the output of the main channel and the additional receiving channel are measured and the specified criteria for the presence of passive interference is checked. If this criterion is met, they decide that the signal at the output of the main channel is a passive interference (Crony D., Wallis P. Systems for suppressing the side lobes of the radiation pattern of the primary radar antenna. Foreign Radio Electronics, 1966, No. 5, pp. 12-30 )

As a specified criterion for the presence of passive interference, for example, the criterion used in the technical solution described in the reference book "Radio-electronic systems, the fundamentals of construction and theory" can be used. Ed. POISON. Shirman. M., 2007, p. 7.5, p. 99-100. For the closest technical solution, this criterion is formulated as follows: the signal at the output of the main channel is taken as passive interference if the ratio of the level of this signal to the signal level at the output of the additional receiving channel does not exceed a predetermined value.

The closest technical solution allows you to provide protection from passive interference in the form of reflections of the probing signals by single reflectors, taken along the side lobes of the bottom of the main channel, that is, reflectors located in different pulsed volumes. The signals reflected by group reflectors received by the main and additional channels are probing signals, to one degree or another distorted due to interference of signals reflected by different reflectors of the group. Moreover, due to the difference in the position of the phase centers of the antennas, the signals received by the primary and secondary channels may have different distortions. As a result, the required excess of the signal level at the output of the additional receiving channel to the signal level at the output of the main channel is not achieved in each discrete in range, that is, the criterion for the presence of passive interference in these discrete samples is not fulfilled and the suppression of passive interference is significantly worsened (Reference "Electronic Systems, Basics of Construction and theory. ”Under the editorship of YD Shirman. M., 2007, p. 157).

Thus, a drawback of the closest technical solution is the insufficient suppression of passive interference in the form of reflections of the probing signals by group reflectors received along the side lobes of the bottom of the main channel.

The problem being solved (technical result), therefore, is to increase the suppression of passive interference in the form of reflections of the probing signals by group reflectors received along the side lobes of the bottom of the main channel.

The technical result is achieved by the fact that in the method of protecting the surveillance radar from passive interference received on the side lobes of the BOTTOM of the main channel, including the emission and reception of sounding signals in a given viewing area by the main channel, receiving reflected sounding signals placed in the antenna sheet of the main channel by an additional receiving channel, the level of the main lobe of the bottom of the bottom of the bottom channel of which is selected below the level of the main lobe of the bottom of the bottom of the main channel at least k ₁ times, and above the level of the maximum side lobe of the bottom of the bottom of this channel not less than k ₂ times, where k ₁ and k ₂ are the specified values determined by permissible losses in target detection, while in the process of reviewing the zone, the bottom position of the additional receiving channel is controlled so that for any azimuthal and elevation position of the main the bottom lobe of the main channel BOTTOM in the field of view the main bottom lobe of the bottom of the additional receiving channel covered the given area of the field of view of the radar over the entire range of the radar in range, and in azimuth the region of the field of view, including the azimuth position g according to the invention, N ≥ 1 additional receiving channels are introduced, while the levels of the main DND petals of these additional channels and the angular field of view covered by them, are introduced according to the invention, checking the specified criterion for the presence of passive interference at the output of the main channel places and in azimuth are chosen similarly to the aforementioned additional receiving channel, the antennas N + 1 of the additional receiving channels are located in the antenna sheet of the main channel so that their phase centers are not fell between themselves in elevation, during the zone survey, for each range, the discrete signals measure the signal levels at the output of the main and each of the N + 1 additional receiving channels and check the mentioned criterion for the presence of passive interference, decide that the signal at the output of the main channel is a passive interference if this criterion is satisfied for at least one of the N + 1 additional receiving channels.

The technical result is also achieved by the fact that the antennas N + 1 of the additional receiving channels are located in the antenna web of the main channel so that their phase centers are located at the same angle from each other in elevation.

The technical result is also achieved by the fact that the signal level at the output of the i-th additional receiving channel, where i = 1, ..., N + 1, is measured on the (j-N + i-1) -th zone survey at the same angular the positions of the main lobe of the bottom of the main channel, where j is the number of the current survey, j≥N + 1.

The technical result is also achieved by the fact that the signals at the outputs N + 1 of the additional receiving channels are measured on the current zone overview.

The essence of the claimed technical solutions is as follows.

In the invention, N> 1 additional receiving channels are introduced, while the antennas of all N + 1 additional receiving channels are located in the antenna sheet of the main channel so that the phase centers of the antennas of the additional receiving channels do not coincide in elevation (claim 1). In particular, the phase centers of the antennas of the additional receiving channels can be located at an equal distance at an elevation angle (claim 2).

The levels of the main lobe of the bottom of the bottom of the N + 1 additional receiving channels are set below the level of the main lobe of the bottom of the bottom of the main channel at least k ₁ times, and above the level of the maximum side lobe of the bottom of the bottom of this channel at least k ₂ times, where k ₁ and k ₂ - predetermined values determined by permissible losses in target detection that occur when the level of the signal received in the additional receiving channel exceeds the level of the signal reflected from the target located in the main lobe of the bottom of the main channel. The values of k ₁ and k _{2 are} set based on the maximum and minimum expected levels of the main bottom lobe of the bottom of the additional channels.

During the zone survey, the position of the antenna patterns of all additional receiving channels is controlled in such a way that, for any azimuthal and elevation position of the main lobe of the main channel bottom of the main channel in the viewing area, the main bottom of the bottom of each additional receiving channel covers the specified area of the field of view over the entire working interval Radar in range, and in azimuth - the area of the field of view, including the position of the main lobe of the bottom of the main channel in azimuth (figure 2). The position of the specified area of the field of view by elevation can be set both constantly for the entire duration of the radar, for example, in the surface part of the field of view to combat passive interference arising from super refraction, and variable, depending on the position of the area of passive interference, determined from the information obtained from previous reviews of the zone.

With the indicated mutual arrangement of the antennas of the additional receiving channels, the distortion of the received signals due to the interference of the probe signals reflected by the group reflectors in each of the additional receiving channels occurs differently. As a result, if the criterion for the presence of passive interference is not fulfilled during the survey of the zone in the range discrete in the region of existence of passive interference received on the side lobes of the BOTTOM for any additional receiving channel, then it will be executed in this range discrete for another additional receiving channel , in which interference distorts the signals differently, or for the third channel and so on up to N + 1 channels. That is, with a sufficiently large number of additional receiving channels in the region of existence of passive interference, there is always an additional receiving channel for which the criterion for the presence of passive interference is fulfilled. Thus, in order to make a decision on detecting interference in a discrete in range at the output of the main channel, it is sufficient that the criterion for the presence of interference is fulfilled for at least one of the N + 1 additional receiving channels.

The invention considers two variants of the method. In the first embodiment, the measurement of signal levels from the outputs of additional receiving channels is carried out in N + 1 consecutive reviews of the zone (paragraph 3 of the claims). In this case, the decision on the presence of interference at the output of the main channel can be made at that review, on which the criterion for the presence of interference was met for the first time.

So, for example, when using two additional receiving channels, the signal from the output of the first additional receiving channel is measured at the previous review of the zone, and the signal from the output of the second additional receiving channel is measured at the current review. The decision on the presence of interference at the output of the main channel can be made at the previous or current review, depending on which review the criterion for the presence of interference was met for the first time.

In this embodiment, it is assumed that the interference is stationary over time, that is, the immutability of their parameters from review to review.

The advantage of this option is that, since the signals from the output antennas of the additional receiving channels arrive alternately in successive surveys, only one information channel is required to transmit these signals to the radar signal processing device for their further processing and deciding on the presence of interference.

This option is advisable to apply when the antennas of the additional receiving channels rotate (together with the antenna of the main channel), and the radar signal processing device is stationary.

In the second variant of the method, the signals from the outputs of all antennas N + 1 of the additional receiving channels are supplied for further processing and deciding on the presence of interference in the current review, that is, at the same time (claim 4).

This option is advisable to use when the antennas of the additional receiving channels (together with the antenna of the main channel) are stationary relative to the radar signal processing device (rotate together with the radar signal processing device) or it is possible to use a separate information channel for each additional receiving channel.

The advantage of this option is that it can be used for non-stationary interference, that is, for interference with parameters that vary from review to review.

Thus, the use of several additional receiving channels with different positions at the elevation phase centers of their antennas can increase the suppression of passive interference in the form of reflections of probing signals by group reflectors received along the side lobes of the bottom of the main channel, that is, to provide the claimed technical result.

The invention is illustrated by the following drawings:

Figure 1 is an illustration of the ratio of levels and positions along the elevation angle ε of the bottom of the main channel and the additional receiving channel in the closest technical solution.

Figure 2 - illustration of the ratios of levels and positions along the elevation angle ε of the bottom of the main channel and N + 1 additional receiving channels in the present method. The positions of the main lobe of the main channel in elevation in the field of view are indicated by ε ₁ , ..., ε _n , where n is the number of positions of the main lobe of the bottom of the main channel in the elevation in the field of view. The main lobes of the bottom of N + 1 additional receiving channels cover the earth's surface and the surface part of the viewing area in elevation.

Figure 3 is a functional diagram of a device that implements the inventive method.

A device that implements the inventive method (figure 3) includes an antenna of the main channel 1, N + 1 antennas of additional receiving channels 2, a receiver of the main channel 3, N + 1 receivers of additional receiving channels 4, a decision unit 5 and a block of signal blanking 6, the output of the antenna of the main channel 1 is connected to the input of the receiver of the main channel 3, and the outputs of the antennas N + 1 of the additional receiving channels 2 are connected to the inputs of the corresponding N + 1 receivers of the additional channels 4, N + 1 of the outputs of the receivers 4 are decisively connected of block 5, the output of the receiver of the main channel 3 and the output of the decision block 5 are connected respectively to the first and second inputs of the block of signal blanking 6, the output of which is the output of the device.

A device that implements the inventive method can be performed using the following functional elements.

The antenna of the main channel 1 is a phased antenna array with electronic scanning along one or both angular coordinates and with circular mechanical rotation (Radar Reference. Edited by M. Skolnik, vol. 2. - M., Sov. Radio, 1977, p .132-138).

Antenna for additional receiving channel 2 — a phased antenna array with web sizes smaller than the main antenna’s web, electronically scanned in elevation, located in the main antenna’s cloth (Radar Reference. Edited by M. Skolnik, vol. 2. M ., Sov. Radio, 1977, p.132-138).

The receiver of the main channel 3 - superheterodyne type (Handbook on the basics of radar technology. M., 1967, S. 343-344).

The receiver of the additional channel 4 - superheterodyne type (Handbook on the basics of radar technology. M., 1967, S. 343-344).

The decisive unit 5 is a computer in which the specified criterion for the presence of passive interference at the output of the receiver of the main channel 3 is checked based on the measurement of signal levels at the output of the receiver of the main and each of N + 1 additional receiving channels (Integrated circuits. Reference, edited by B.V. . Tarabrina. M., Radio and communications, 1984).

Signal blanking unit 6 is a computer that performs blanking of a discrete range signal from the output of the receiver of the main channel 3 when an interference signal is received from the output of the decision unit 5 (Integrated circuits. Handbook edited by BV Tarabrin. M. , Radio and Communications, 1984).

A device that implements the inventive method works as follows.

Passive interference in the form of reflection of the probe signal from group reflectors, for example, on the earth's surface, received by the side lobes of the radiation pattern of the receiving antenna of the main channel 1, is fed to the input of the receiver of the main channel 3. The same noise received by the main lobes of the bottom N + 1 of the additional receiving channels 2, arrives at the N + 1 inputs of the receivers of the corresponding additional channels 4. The signal from the output of the receiver of the main channel 3 and N + 1 signals from the outputs of the N + 1 receivers of the additional channels 4 arrive respectively on the first input and on the inputs from the second to N + 2 decision block 5.

In the decisive unit 5, the levels of the received signals are measured, and in each discrete in range the fulfillment of the specified criterion for the presence of passive interference is checked.

If in any discrete in range the criterion for the presence of passive interference is fulfilled, then in decision block 5 a decision is made that the signal at the output of the receiver of the main channel 3 is an interference received from the side lobes of the bottom of the main channel 1 and from the output of the decision block 5 a signal is output to the input of signal blanking unit 6, according to which the signal from the output of the receiver of the main channel 3 is blanked for this range discrete.

If in the discrete in range the specified criterion for the presence of passive interference is not satisfied in any of the N + 1 additional channels, then in decision block 5 a decision is made that the signal at the output of the receiver of the main channel 3 is not an obstacle, and it is passed to the output of the device .

Since the positions of the phase centers of the antennas N + 1 of the additional receiving channels 2 are different, the distortions of the signals received by the additional receiving channels due to the interference of the probe signals reflected by the reflector group in each of the N + 1 additional receiving channels occur differently. This allows for a sufficiently large number of additional receiving channels in the area of existence of passive interference to always find an additional receiving channel, the signal level at the output of which exceeds the signal level at the output of the main channel, that is, to ensure that the criterion for the presence of passive interference is met.

Thus, in a device that implements the claimed method, the use of several additional receiving channels with different positions in the elevation angle of the phase centers of their antennas can increase the suppression of passive interference in the form of reflections of sounding signals by group reflectors received along the side lobes of the bottom of the main channel, that is, to achieve the claimed technical result.

Claims (4)

1. A method of protecting a survey radar station (radar) from passive interference received from the side lobes of the radiation pattern (BOTTOM) of the main channel, which includes emitting and receiving sounding signals in a given viewing area of the main channel, receiving reflected sounding signals placed in the antenna sheet of the main channel with an additional receiving channel, the level of the main lobe beam is selected below the level of the main lobe main beam channel is not less than k ₁ times, and higher level of the maximum sidelobe beam the channel is not less than k _2, where k ₁ and k ₂ - setpoints defined allowable losses in the detection of targets, while in the process of viewing zones control the position of beam further reception channel so that at any azimuth and elevation position the main lobe of the bottom of the main channel in the field of view of the main channel of the bottom of the bottom of the additional receiving channel covered in elevation the specified area of the viewing area near the earth's surface over the entire working range of the radar in range, and in azimuth - the area of the review area a, including the azimuthal position of the main lobe of the main beam of the main channel, checking the specified criterion for the presence of passive interference at the output of the main channel for each discrete in range, characterized in that N≥1 additional receiving channels are introduced, while the levels of the main lobe of the bottom of these additional channels and the coverage areas of the viewing area in elevation and azimuth are chosen similarly to the aforementioned additional receiving channel, antennas N + 1 of additional receiving channels are located in the antenna sheet of the main channel so that their phase centers do not coincide with each other in elevation, during the zone survey for each discrete in range, measure the signal levels at the output of the main channel and each of the N + 1 additional receiving channels and check the mentioned criterion for the presence of passive interference, make a decision that the signal at the output of the main channel is passive interference if this criterion is satisfied for at least one of the N + 1 additional receiving channels. 2. The method according to claim 1, characterized in that the antennas N + 1 of the additional receiving channels are located in the canvas of the antenna of the main channel so that their phase centers are located at the same angle from each other at an elevation angle. 3. The method according to claim 1, characterized in that the signal level at the output of the i-th additional receiving channel, where i = 1, ..., N + 1, is measured on the (j-N + i-1) -th zone overview at the same angular positions of the main lobe of the bottom of the main channel, where j is the number of the current survey, j≥N + 1. 4. The method according to claim 1, characterized in that the signals at the outputs N + 1 of the additional receiving channels are measured in the current zone overview.

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