RU2778939C1 - Apparatus for distorting the radio location image in a synthetic-aperture radar - Google Patents

Abstract

FIELD: radio location.

SUBSTANCE: invention relates to equipment for creating interference for synthetic aperture radars (SAR) and can be used in the development of SAR-suppression means, in particular, ones installed on a UAV. The claimed apparatus for distorting the radio location image in a synthetic-aperture radar comprises a receiving antenna, a receiving apparatus, and a repeater, connected in series, as well as a modulating function forming unit. The repeater is therein put at a set distance from the object of cover. Series-connected noise band offset distance calculating unit, average noise band offset distance calculating unit, and a noise band width calculating unit, as well as a first and a second memory apparatus and a data input unit are also additionally included in the apparatus. The repeater consists of series-connected modulator, power amplifier, and transmitting antenna.

EFFECT: eliminated dependence of the effectiveness of concealing the mark of the object of cover with a false mark on the current spatial position of the SAR carrier.

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Description

The invention relates to the technique of jamming radar systems with antenna aperture synthesis (RSA) and can be used in the development of SAR suppression tools, in particular, those installed on UAVs.

The closest in technical essence to the claimed invention is a device (prototype) - a device for distorting a radar image in a radar station with antenna aperture synthesis, containing a receiving antenna connected in series, a receiving device and a repeater, as well as a modulating function generation unit (see patent RU 2622904 , C1, IPC G01S 13/90 G01S 7/38, published 06/21/2017, Bull. No. 18).

A disadvantage of the known device is the dependence of the efficiency of hiding the mark from the object of cover with a false mark formed on the radar image in the SAR under the influence of interference, on the current position of the SAR carrier in space.

The technical result of the invention is to eliminate the dependence of the effectiveness of hiding the mark of the cover object with a false mark on the current position of the SAR carrier in space by introducing into the continuous retransmitted signal a modulating function that reflects the value of the frequency modulation deviation, which ensures the formation of a false mark (noise band) of the required dimensions on the radar image, and setting the relay of signals from the remote point located at a given object distance.

The specified technical result is achieved by the fact that in a known device for distorting a radar image in a radar station with antenna aperture synthesis, containing a receiving antenna connected in series, a receiving device and a repeater, as well as a modulating function generation unit, the output of which is connected to the second input of the repeater, according to the invention , the repeater is placed at a predetermined distance from the cover object, according to the invention, a block for calculating the noise band offset distance, a unit for calculating the average noise band offset distance and a unit for calculating the noise band width are additionally connected in series, the output of which is connected to the third input of the modulating function generation unit, and also the first and second storage devices, the data input unit, the output of which is connected to the input of the second storage device, the first, second, third and fourth outputs of the second storage device are connected to the the third, fourth, fifth and sixth inputs of the block for calculating the offset distance of the noise band, the fifth output - with the second input of the block for calculating the width of the noise band, and the sixth output - with the fourth input of the block for generating the modulating function, the first output of the first memory device is connected to the first input of the block for forming modulating function, the second output - with the first input of the noise band offset distance calculation unit and the second input of the modulating function generation unit, and the third output - with the second input of the noise band offset distance calculation unit.

The specified technical result is achieved by the fact that the repeater consists of serially connected modulator, power amplifier, transmitting antenna.

The essence of the invention lies in the fact that before the appearance of the SAR carrier, the initial data is set, the noise band offset distances are calculated for different positions of the SAR carrier, the average distance of the noise band offset, which is at the same time the offset distance of the repeater from the cover object, the repeater is placed at the offset distance in the direction of the intended area appearance of the SAR carrier, the required values of the noise bandwidth and frequency modulation deviation of the retransmitted signal are calculated, and when the SAR appears, the SAR signal is subjected to frequency modulation and re-emission.

In FIG. Figure 1 shows the results of a simulation carried out at the VUNTS Air Force "VVA" (named after prof. N.E. Zhukovsky and Yu.A. Gagarin) (Voronezh), as a result of which it was found that under the influence of incoherent relay interference with a fixed time delay and a frequency shift that changes according to a given law in SAR forms a false mark in the form of a noise band that hides the mark of the cover object (point reflector). In FIG. 1a shows an image with a mark of the cover object before the impact of relay interference, and in Fig. 1b - image with a mark of the cover object, a hidden noise band formed under the influence of relay interference. As can be seen from FIG. 1b, for effective concealment of the cover object, it is necessary, firstly, to ensure the alignment of the noise band and the mark of the cover object, and secondly, the width of the noise band should not be less than the size (length) of the cover object.

The essence of combining the noise band and the cover object is illustrated in Fig. 2, which shows the dependence of the position of the noise band on the position of the repeater relative to the cover object and SAR. The images in Fig. 2a (in the absence of relay interference) and FIG. 2b (when exposed to relay interference) correspond to the case when the repeater is placed next to the cover object. As can be seen from FIG. 2b, the noise band is formed at a certain offset distance from the repeater. The noise band offset distance reflects the difference in the time of arrival at the input of the SAR receiving antenna of the reflected and re-radiated signals by the repeater.

The delay of the re-radiated signal consists in the presence of hardware delay time required for processing the signal in the process of retransmission. Obviously, to hide the cover object, it is necessary to ensure the alignment of the noise band and the mark of the cover object. To do this, the repeater is preliminarily taken out from the cover object towards the supposed area of the SAR appearance at a distance equal to the distance of the noise band offset. The result of changing the position of the repeater is shown in Fig. 2c, in which the noise strip hides the mark of the cover object.

Thus, the concealment of the cover object by a fixed repeater is ensured, regardless of the position of the SAR carrier in the region of space within which its appearance is expected.

This achieves the technical result specified in the invention.

The scheme of the device providing concealment of the cover object by a fixed repeater is shown in Fig. 3, where it is indicated: 1 - receiving antenna; 2 - receiving device; 3 - data entry block; 4 - storage device; 5 - block for calculating the offset distance of the noise band; 6 - block for calculating the average offset distance of the noise band; 7 - block for calculating the width of the noise band; 8 - block for the formation of the modulating function; 9 - repeater.

The purpose of the elements of the receiving antenna 1, the receiving device 2, the repeater 9 are known from their names.

Data input block 3 is intended for the user to enter the parameters of the area of space in which the SAR carrier is expected to appear (the maximum and minimum values of the slant ranges between the cover object and the SAR carrier, the maximum and minimum values of the elevation angles of the SAR carrier relative to the cover object), the length of the cover object, the value speed of intrapulse frequency tuning. The data input block 3 can be designed as a compact keyboard with a display screen for the input values.

For example, the way the electronic unit is arranged from the set of small-sized navigation equipment for the consumer CNS GLONASS / GPS 14Ts822 ("Grot-M") [orkkniikp.ru/catalog/navigatsionnoe-oborudovanie/14ts822].

The storage device 4.1 is designed to store the values of the speed of light in free space, the hardware delay time and the number π, stored in the memory at the factory (not available to be changed by the user). Memory 4.1 may be implemented on the Microchip AT28C256 Read Only Memory [www.microchip.com/wwwproducts/en/AT28C256] EEPROM.

The storage device 4.2 is designed to store the values entered through the data entry block 2 by the user. Memory 4.2 can be implemented on Microchip 23A512 SRAM random access memory [https://www.microchip.com/wwwproducts/en/23A512].

The noise band offset distance calculation unit 5 is designed to calculate the distances by which the noise band image is shifted relative to the repeater mark, formed on the radar image under the influence of interference, at various positions of the SAR carrier in space. The block for calculating the noise band offset distance 5 can be executed on a low-power 8-bit microcontroller Microchip ATmega8 [www.microchip.com/wwwproducts/en/ATmega8], programmed according to the method

; R_p = R_a - R_ap;

; R_a, r_a - наклонная и горизонтальная дальности от объекта прикрытия до РСА соответственно; R_ap, r_ap - наклонная и горизонтальная дальности от объекта прикрытия в направлении на РСА соответственно, равные расстоянию, которое электромагнитная волна преодолевает в пространстве за время аппаратного времени задержки ретранслятора; R_p - наклонная дальность от РСА до ретранслятора (R_p' = R_p); h_a - высота полета РСА; r_вын - вынос ретранслятора перед объектом прикрытия, с - 3⋅10⁸ м/с - скорость света в свободном пространстве.where r _ap = R _ap cosξ; R _ap = (cτ _ass )/2; X = r _a - (r _ap + r _p ); r _a = R _a cosξ;

; R _p = R _a - R _ap ;

; R _a , r _a - slant and horizontal distances from the cover object to the SAR, respectively; R _ap , r _ap - slant and horizontal distances from the cover object in the direction to the SAR, respectively, equal to the distance that the electromagnetic wave overcomes in space during the hardware delay time of the repeater; R _p is the slant distance from the SAR to the repeater (R _p ' = R _p ); h _a - SAR flight altitude; r _out - transponder offset in front of the cover object, s - 3⋅10 ⁸ m/s - speed of light in free space.

The block for calculating the average noise band offset distance 6 is designed to calculate the noise band offset distance, the average of those calculated in the noise band offset distance calculation unit 5. This distance is at the same time the distance of the repeater from the cover object on which it is installed by the user before the SAR carrier appears. The unit for calculating the average noise band offset distance 6 can be implemented, for example, on a low-power 8-bit microcontroller Microchip ATmega8 [www.microchip.com/wwwproducts/en/ATmega8], programmed according to the method

The noise band width calculation unit 7 is designed to calculate the required noise band width required to hide the mark of the cover object on the radar image when the repeater is located at the offset distance calculated in the noise band offset distance calculation unit 5. The noise band width calculation unit 7 can be executed on low-power 8-bit microcontroller Microchip ATmega8 [www.microchip.com/wwwproducts/en/ATmega8], programmed according to the method

The block for generating the modulating function 8 is designed to calculate the value of the deviation of frequency modulation (the modulating function) introduced into the retransmitted signal in the repeater 9, which ensures the formation of a noise band of the required width on the radar image, calculated in the block for calculating the width of the noise band 7. The block for generating the modulating function 8 can be executed on a low-power 8-bit microcontroller Microchip ATmega8 [www.microchip.com/wwwproducts/en/ATmega8], programmed according to the method

where b = 2πΔf _c /T is the rate of intra-pulse frequency tuning,

ψ = arctan (R _a / h _a ) - angle of incidence of the probing radiation.

The device operates in two modes:

"Preparation" mode;

radiation mode.

The operating modes of the device differ in that in the "Preparation" mode, it is used to determine the optimal distance at which the repeater is previously taken out from the cover object, and in the "Radiation" mode, the enemy's SAR is suppressed.

The initial data for calculating the optimal distance of the transponder are constant and variable values. The constant values stored in the storage device 4.1 include: the speed of light in free space; hardware delay time; number pi. Variable values entered through the data input block 3 and stored in the memory device 4.2 include: parameters of the area of space in which the SAR carrier is expected to appear (the maximum and minimum values of the slant ranges between the cover object and the SAR carrier, the maximum and minimum values of the carrier elevation angles SAR regarding the cover object); length of the cover object; the value of the rate of intra-pulse frequency tuning. Data for variable values (except for the extent of the cover object) can be obtained from the results of reconnaissance of SAR characteristics. The length of the cover object is determined by measuring the distance between the two extreme points of the cover object in the direction of the area of the expected occurrence of the SAR.

Constant and variable values from the storage device 4 are used in the block for calculating the offset distance of the noise band 5, where the transponder offset distance is calculated for various positions of the SAR carrier in space according to the formula (1). The calculation results are used in the block for calculating the average offset distance of the noise band 6, in which the average distance of the transponder is calculated according to the formula (2). The repeater is installed in the area of the cover object at an average distance of the repeater removal in the direction of the expected area for the appearance of the SAR carrier.

The calculation result is used in the noise band width calculation block 7, where the noise band width value is calculated according to the formula (3). Further, in the block for the formation of the modulating function 8, the value of the frequency modulation deviation is calculated according to the formula (4). From the output of the block for the formation of the modulating function 8, the calculation result is fed to the second input of the repeater 9. At this stage, "Preparation" ends.

At the “Emission” stage, the probing SAR signal through the receiving antenna 1 and the receiving device 2 enters the first input of the repeater 9, where, according to the modulating function previously received from the modulating function formation unit 8, it is endowed with an interference component (modeled), amplified and radiated in the direction RSA.

The signal retransmitted in this way is fed to the input of the SAR receiving antenna, processed and displayed on the radar image in the form of a noise band. This ensures effective concealment of the mark of the cover object, regardless of the current position of the SAR carrier in space, which ensures the achievement of the technical result.

The proposed device is practically applicable, since elements widely used in the field of electronics and electrical engineering can be used for its implementation.

Claims (2)

1. A device for distorting a radar image in a radar station with synthesizing the antenna aperture, containing a receiving antenna, a receiving device and a repeater connected in series, as well as a modulating function generation unit, the output of which is connected to the second input of the repeater, characterized in that the repeater is placed at a predetermined distance from the cover object, additionally introduced are serially connected unit for calculating the noise band offset distance, a unit for calculating the average noise band offset distance and a unit for calculating the noise band width, the output of which is connected to the third input of the modulating function generation unit, as well as the first and second memory devices, the input unit data, the output of which is connected to the input of the second storage device, the first, second, third and fourth outputs of the second storage device are connected to the third, fourth, fifth and sixth inputs of the block for calculating the offset distance of the noise bands, the fifth output - with the second input of the block for calculating the width of the noise band, and the sixth output - with the fourth input of the block for generating the modulating function, the first output of the first memory device is connected to the first input of the block for generating the modulating function, the second output - with the first input of the block for calculating the displacement distance noise band and the second input of the block for forming the modulating function, and the third output is with the second input of the block for calculating the offset distance of the noise band. 2. The device according to claim 1, characterized in that the repeater consists of serially connected modulator, power amplifier, transmitting antenna.

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