RU2762742C1 - Method for protecting a surveillance radar from passive interference created by clusters of reflectors, and a radar station for its implementation - Google Patents

Abstract

FIELD: radar.

SUBSTANCE: inventions group relates to the field of radar, in particular to the protection of surveillance radar stations from passive interference created by clusters of reflectors. In the claimed method, the marks adjacent in range, elevation, azimuth are combined into a spatial package of marks, in which the standard deviation (SD) of the mark range values ​​relative to their mean value is determined, the decision to blank passive interference is taken within the boundaries of the spatial packet of marks when the above-mentioned SD is exceeded the threshold value of the SD, defined as the maximum admissible SD of the range values ​​for targets.

EFFECT: increase in the accuracy of determining the boundaries of the blanking area of ​​passive interference created by clusters of reflectors, and due to this, an increase in the reliability of the issued radar information.

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Description

The claimed technical solutions relate to the field of radar, in particular, to the field of protection of surveillance radar stations (radar) from passive interference created by clusters of reflectors.

The known method of protection against passive interference, based on the selection of a moving target (SDC) due to the difference in the radial velocity of the target and sources of passive interference. This method suppresses the received signals that move little from period to period (Theoretical foundations of radar. Ed. By VE Dulevich. - M., Sov. Radio, 1978, pp. 464-484).

The known radar, which implements the known method of protection against passive interference, contains an SDC device, which includes an ultrasonic delay line, two amplifiers, a differential automatic gain control circuit, two amplitude detectors, a subtraction circuit, and a video detector. The interconnected first input of the first amplifier and the input of the ultrasonic delay line form the input of the SDC device. The outputs of the first and second amplifiers are connected respectively to the first and second inputs of the differential automatic gain control circuit, the first and second outputs of which are connected to the second inputs of the first and second amplifiers, respectively. The outputs of the first and second amplifiers are also connected to the inputs of the first and second amplitude detectors, respectively, the outputs of which are connected to the corresponding inputs of the subtraction circuit, the output of which is connected to the input of the video detector. The output of the video detector is the output of the SDC device (Theoretical foundations of radar. Edited by V.E.Dulevich. - M., Sov. Radio, 1978, pp. 469-473).

The known technical solutions make it possible to protect the radar from passive interference created by accumulations of reflectors, however, as applied to surveillance radars, they have the following disadvantage.

In each direction of the beam, where the SDC is used, it is required to emit several probing pulses. Since in surveillance radars, the time (the number of soundings) for protection from passive interference using the SDC of the entire zone is usually insufficient, then the SDC is used in them only in the lower part of the zone and at a limited range. Since passive interference created by clusters of reflectors can be observed at different heights and in large quantities, the use of MTS to protect against such interference in the entire field of view in the radars under consideration turns out to be problematic.

The closest to the claimed one is a method of protecting a surveillance radar from passive interference created by clusters of reflectors, including determining the boundaries of blanking areas (excluding marks from the radar information (RI) issued to the consumer) of passive interference by the radar operator in terms of the number and density of marks from reflected radar signals (hereinafter - marks) and the subsequent decision-making on blanking passive interference (Angelsky R.D., Shestov I.V. Domestic anti-aircraft missile systems: Illustrated reference book / R.D. AST ", 2002. - 256 s: ill. - (Military equipment), pp. 150-151).

The closest in technical essence to the claimed one is a radar (Fig. 1), containing a transmitter 1, an antenna switch 2, an antenna 3, a receiver 4, a synchronizer 5, an indicator device 6, a blocking passive interference 7, while the output of the transmitter 1 is connected to the input antenna switch 2, the input / output of which is connected to the antenna 3, the output of the antenna switch 2 is connected to the input of the receiver 4, the output of the receiver 4 and the coordinate output of the antenna 3 are connected, respectively, to the first and second inputs of the indicator device 6, the output of which is connected to the input of the passive blanking unit interference 7, the output of which is the output of the radar, the first and second outputs of the synchronizer 5 are connected, respectively, to the sync inputs of the transmitter 1 and the indicator device 6 (Theoretical foundations of radar. Edited by Ya.D. Shirman. - M., Sov. radio, 1970, p. 221, Fig.5.4).

The work of the radar closest to the claimed one is as follows. In the process of reviewing the radar zone in the transmitter 1, according to the commands of the synchronizer 5 (synchronization pulses), probing pulses are formed, which are emitted into space with the help of the antenna 3. The reflected signals are received by the antenna 3, enter the receiver 4, where they are detected in the form of marks. The marks from the output of the receiver 4 and the signals from the coordinate output of the antenna 3, proportional to the angular coordinates of the beam of the antenna 3, go respectively to the first and second inputs of the indicator device 6, where they are displayed. The radar operator observes the radar situation on the screen of the indicator device 6, visually determines the areas of accumulation of marks, determines the boundaries of the blanking areas and issues them to the passive interference blanking unit 7, where the marks falling into the blanking area are excluded from the radar image issued to the consumer. Unblanked marks from the output of the blocking blocking interference 7 are issued to the consumer of the radar image as target.

In the closest technical solutions, the boundaries of the blanking areas of passive interference created by clusters of reflectors are determined by the radar operator visually - by the number and density of marks, in connection with which these technical solutions have the following disadvantages.

First, due to the fact that the operator needs time to assess the radar situation and, on the basis of this assessment, determine and set the boundaries of the blanking areas, the blanking area boundaries are set with a delay of 2-3 survey periods. During this time, a false radar image is issued to the consumer from areas with passive interference. In this case, the volume of false radar images can turn out to be extremely large, which, as a rule, is unacceptable.

Secondly, the boundaries of the passive interference blanking areas during visual assessment are determined very approximately, that is, they, as a rule, differ significantly from real ones. This leads to the fact that either targets are missed (when the blanking area exceeds the passive interference area and targets hit it), or a false radar image is issued to the consumer (when the blanking area does not completely cover the passive interference area).

Thus, the disadvantage of the closest technical solutions is the insufficient reliability of the radar image produced due to the low accuracy of determining the boundaries of the blanking region of passive interference created by accumulations of reflectors.

The technical result (the technical problem to be solved), therefore, is to increase the accuracy of determining the boundaries of the blanking region of passive interference created by clusters of reflectors, and thereby increasing the reliability of the radar information being issued.

The specified technical result is achieved by the fact that in the method of protecting the surveillance radar from passive interference created by clusters of reflectors, including determining the boundaries of the blanking area of passive interference by marks from them, making a decision on blanking passive interference, according to the invention, marks adjacent in range, elevation , azimuth, are combined into a spatial package of marks, in which the standard deviation (RMS) of the range values relative to their mean value is determined:

where n is the number of marks in the spatial package of marks;

R _i - range of the i-th mark in the spatial package of marks, i = 1, ..., n;

- среднее арифметическое значений дальности отметок в пространственном пакете,

- the arithmetic mean of the range of marks in the spatial package,

the decision on blanking passive interference is made within the boundaries of the spatial package of marks according to the results of comparing the value of RMS σ _R with the threshold value σ _Rpor , defined as the maximum allowable RMS of range values for targets, while the spatial packet of marks is blanked when the following condition is met:

The specified technical result is achieved by the fact that in a radar containing a transmitter, an antenna switch, an antenna, a receiver, a synchronizer, a blocking block for passive interference, while the transmitter output is connected to the input of the antenna switch, the input / output of which is connected to the antenna, the output of the antenna switch is connected to the input of the receiver, the first output of the synchronizer is connected to the sync input of the transmitter, the output of the passive interference blanking unit is the output of the radar, according to the invention, the memory device of the coordinates of the marks, the block for the formation of spatial packets of marks, the block for making a decision on blanking the spatial packet of marks, with the first and second inputs the memory device of the coordinates of the marks are connected, respectively, to the output of the receiver and the coordinate output of the antenna, the sync input of the memory of the coordinates of the marks is connected to the second output of the synchronizer, the output of the memory of the coordinates of the marks is connected to the input of the block mirrovanie spatial packets of marks, the output of which is connected to the input of the blocking decision on blanking the spatial packet of marks, the output of which is connected to the input of the blocking blocking passive interference.

The essence of the proposed technical solutions is as follows.

A large number of reflectors in the form of meteorological formations, areas of air ionization, etc. may appear in the radar viewing area. Signals reflected from the accumulation of reflectors are passive interference that reduces the reliability of the radar image.

It is known that detection of a target, like any reflector of probing signals, as a rule, occurs in several adjacent samples in range, azimuth, and elevation. To reduce the amount of processed information and increase the accuracy of measuring the coordinates of the target, such marks are combined into spatial packages of marks (Kuzmin S.Z. Fundamentals of the theory of digital processing of radar information, M, "Soviet Radio", 1974, pp. 152-154).

In the invention, the protection of a surveillance radar station from passive interference created by clusters of reflectors is carried out by analyzing spatial packages of marks and, on the basis of this analysis, making a decision on their blanking. The analysis uses the following feature of spatial packets of marks for the target and for passive interference formed by the accumulation of reflectors.

Since the target is a rigid structure concentrated in a small volume, in all positions of the beam of its spatial package, the marks are at the same range. The number of beam positions, in which a different number of reflected signals are detected, and, consequently, the spread of the range values of the marks in different beam positions, are small.

Reflectors of passive interference formed by clusters of reflectors are randomly distributed in space and in a larger volume than the target, therefore, in its spatial package of marks, there is a greater spread of mark range values than along the target.

In the invention, the spread of the values of the range of marks in the spatial package is estimated by the value of the standard deviation (RMS) of the values of the range of marks relative to the average value. In this case, the mathematical formula (1) is used.

FIG. 2 shows an example of the RMS σ _R values of the range of marks (in meters) relative to their average value in the spatial packet when the target moves (T is the time (in seconds) of reaching the target, from the moment it is detected in the radar's viewing area) and during its subsequent destruction. The example is taken from experimental measurements. It follows from the figure that the RMS of the values of the range of marks in spatial packets in the area of destruction of the target, i.e. in the area of passive interference created by the accumulation of reflectors, much more than in the target.

The decision to blank the spatial packet of marks is taken when the RMSE of the ranges of marks in the packet σ _R exceeds the threshold value of the RMS σ _Rpor , i.e. under condition (2).

The threshold value of the _standard deviation σ Rpor is determined in advance as the largest standard deviation of the values of the range of reflectors, admissible for targets. So, for example, if the maximum target that must be detected by the surveillance radar is an aircraft with the dimensions of a bomber, then the threshold value of σ _Rpor is determined based on the RMS deviation of the ranges in the spatial package for an aircraft of this type. The threshold value of the _standard deviation σ Rpor is determined by calculation or using mathematical modeling.

Since in the claimed technical solutions the determination of the RMS value of the range of marks in the spatial packet of marks (1) and the verification of condition (2) is carried out at each formation of the packet, there is no delay in making a decision on blanking passive interference. The boundaries of the blanking area are determined by the boundaries of the spatial package of marks, that is, with the highest possible accuracy for the surveillance radar, which ensures high reliability of the radar image. Thus, the claimed technical result is achieved.

The invention is illustrated in the following drawings.

FIG. 1 is a block diagram of the radar closest to the claimed radar.

FIG. 2 - an example of the experimental dependence of the value of the RMSD σ _R in the package for the target and in the package for passive interference created by clusters of reflectors on time.

FIG. 3 is a block diagram of the inventive radar.

The inventive method is carried out in the radar depicted in FIG. 3 and containing a transmitter 1, an antenna switch 2, an antenna 3, a receiver 4, a synchronizer 5, a blocking passive interference 7, a memory of coordinates of marks 8, a block for forming spatial packets of marks 9, a block for making a decision on blanking a spatial packet of marks 10, while the output of the transmitter 1 is connected to the input of the antenna switch 2, the input / output of which is connected to the antenna 3, the output of the antenna switch 2 is connected to the input of the receiver 4, the output of the receiver 4 and the coordinate output of the antenna 3 are connected, respectively, to the first and second inputs of the memory device of the coordinates of the marks 8, the first and second outputs of the synchronizer 5 are connected, respectively, to the sync input of the transmitter 1 and the sync input of the memory coordinates of the marks 8, the output of which is connected to the input of the block for forming spatial packets of marks 9, the output of which is connected to the input of the block for making a decision on blanking the spatial packet of marks 10, the output of which is th is connected to the input of the blocking passive interference 7, the output of the blocking passive interference 7 is the output of the radar.

A radar station can be made using the following functional elements.

Transmitter 1 - pulse type (Handbook of the basics of radar technology. - M., 1967, p. 278).

Antenna switch 2 - made on a circulator (Handbook of the basics of radar technology. - M., 1967, pp. 146-147).

Antenna 3 is a phased array antenna with electronic scanning along one or both angular coordinates and with circular mechanical rotation (Handbook of radar. Edited by M. Skolnik, vol. 2 - M., Sov. Radio, 1977, p. 132- 138).

Receiver 4 - superheterodyne type (Handbook of the basics of radar technology. - M., 1967, pp. 343-344).

Synchronizer 5 - is made on the basis of a master precision generator and a series of frequency dividers connected to it (Radar devices (theory and principles of construction). Edited by V.V. Grigorin-Ryabov. - M., Sov. Radio, 1970, p. 602-603).

Block blanking passive interference 7 - a digital processor that performs blanking of spatial packets of marks, i.e. exclusion of packets from RLI issued to the consumer (Integrated microcircuits. Handbook edited by BV Tarabrin. - M., Radio and communication, 1984).

The memory device of coordinates of marks 8 is a memory device made on standard microcircuits (Integrated microcircuits. Handbook edited by BV Tarabrin. - M., Radio and communication, 1984).

The block for forming spatial packages of marks 9 is a digital processor that checks the criterion of proximity of marks in all coordinates, and combining the distance, azimuth, and elevation of marks adjacent in coordinates into a spatial package (Integrated microcircuits. Handbook edited by B.V. Tarabrin. - M ., Radio and communication, 1984).

The block for making a decision on blanking the spatial package of marks 10 is a digital processor (Integrated microcircuits. Handbook edited by B.V. Tarabrin. - M., Radio i svyaz, 1984), which calculates the value of σ _R according to formula (1) and compares it with the threshold value σ _Rpor . A signal is issued to blank the spatial packet of marks when condition (2) is met.

The operation of the claimed radar is as follows. In the process of reviewing the radar zone in the transmitter 1, according to the commands of the synchronizer 5 (synchronization pulses), probing pulses are formed, which are emitted into space with the help of the antenna 3. The reflected signals are received by the antenna 3, enter the receiver 4, where they are detected in the form of marks. The marks from the output of the receiver 4 and the signals proportional to the angular coordinates of the beam of the antenna 3 are fed, respectively, to the first and second inputs of the memory device of the coordinates of marks 8, where, as the radar zone is surveyed, their coordinates are stored. The coordinates of the marks from the memory of the coordinates of marks 8 by commands from the synchronizer 5 are fed to the input of the block for forming spatial packets of marks 9, where the marks adjacent in range, elevation, azimuth are combined into spatial packets. The coordinates of the marks included in the spatial packet are transmitted to the blanking decision block 10, where the _{standard deviation σ R} is determined using formula (1), and after comparing it with the threshold value σ Rpor (2), a decision is made to blank the packet. If condition (2) is fulfilled, then it is considered that the spatial packet consists of marks from interference, and it must be blanked, while the output of block 10 gives a corresponding signal, according to which the packet is excluded from the radar image issued to the consumer in blocking block 7 of passive interference ... If condition (2) is not met, then the packet is considered target and is issued to the RLI consumer from the output of block 7.

Thus, the claimed technical result is achieved and the technical problem is solved.

Claims (8)

1. A method of protecting a survey radar station from passive interference created by clusters of reflectors, including determining the boundaries of the blanking area of passive interference by marks from them, making a decision on blanking passive interference, characterized in that the marks adjacent in range, elevation, azimuth are combined into a spatial package of marks, in which the standard deviation (RMS) of the range values relative to their mean value is determined:

where n is the number of marks in the spatial package of marks; R _i - range of the i-th mark in the spatial package of marks, i = 1, ..., n;

- the arithmetic mean of the range of marks in the spatial package, the decision on blanking passive interference is made within the boundaries of the spatial package of marks according to the results of comparing the value of RMS σ _R with the threshold value σ _Rpor , defined as the maximum allowable RMS of range values for targets, while the spatial packet of marks is blanked when the following condition is met:

2. A radar station (radar) for implementing a method of protecting a surveillance radar from passive interference created by clusters of reflectors, containing a transmitter, an antenna switch, an antenna, a receiver, a synchronizer, a blocking passive interference, while the transmitter output is connected to the input of the antenna switch, input / the output of which is connected to the antenna, the output of the antenna switch is connected to the input of the receiver, the first output of the synchronizer is connected to the sync input of the transmitter, the output of the passive interference blanking unit is the output of the radar, characterized in that a memory device for the coordinates of marks, a unit for forming spatial packets of marks, a decision-making unit about blanking the spatial package of marks, while the first and second inputs of the memory device of coordinates of marks are connected respectively to the output of the receiver and the coordinate output of the antenna, the sync input of the memory of coordinates of marks is connected to the second output of the synchronizer, you the stroke of the memory device of the coordinates of the marks is connected to the input of the block for forming the spatial packages of marks, the output of which is connected to the input of the block for making a decision on blanking the spatial packet of marks, the output of which is connected to the input of the blocking blanking of passive interference.

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