RU2777376C1 - Multichannel automated apparatus for countering radar reconnaissance - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: invention relates to the field of radio engineering and can be used to create intermittent noise interference. Claimed apparatus is supplemented by a receiving antenna apparatus consisting of an antenna array of K horn emitters and a beam-forming circuit; a block of L input switches, wherein L is the number of partial patterns of the receiving antenna apparatus; a block of L input high frequency amplifiers (HFA); an input signal adder; a block of shapers consisting of L channels, wherein each channel consists of a detector, a video amplifier, and a control signal generator, connected in series; a block of AND gates, consisting of L channels, wherein each channel has N AND circuits, wherein N is the number of frequency channels; a control unit; a channel key; a frequency channel number decoder; a partial pattern number decoder; a switch; a DOS; a block of K output HFAs; a transmitting antenna array of K horn emitters.

EFFECT: pauses in the noise intermittent interference provide a possibility of creating noise intermittent interference to other radars of means of aerial RLPR, allowing for an increase in the number of suppressed radar stations of means of aerial radio location parametric reconnaissance; increase in the efficiency of the claimed apparatus provided by increasing the number of radio location stations (radars) suppressed by the apparatus, means of aerial radio location parametric reconnaissance (RLPR) due to the creation of noise intermittent interference utilising the specifics of function of the objects of countering.

1 cl, 3 dwg

Description

The invention relates to radio engineering and can be used to improve the efficiency of a multi-channel automated device for counteracting radar reconnaissance by increasing the number of radar stations (RLS) of airborne parametric reconnaissance means (RLPR) suppressed by it by creating intermittent noise interference.

Known radio interference station with automatic tuning to the frequency of the suppressed means (US Patent No. 3431496, 1969 H04K 3/00), which contains a transmit-receive antenna, a receive-transmit switch, a transceiver pulse generator, a high-frequency amplifier (UHF), a receiver mixer, intermediate frequency amplifier (IFA), limiter, discriminator, audio frequency stage, frequency discriminator, modulator, local oscillator, high-frequency circuits, transmitter mixer, intermediate frequency generator, modulator, frequency modulator, in which the receiver and transmitter are switched on alternately, detection using the receiver the frequency of the signals of the enemy station and automatically tunable the frequency of the transmitter to the frequency of the received signal.

The disadvantage of this analogue of the invention is the lack of multichannel, since in conditions when in its antenna pattern (DND) or in the coverage area (outside the DND) there are several objects for suppression operating at different frequencies at the same time, only one of them will be suppressed.

Known system of electronic countermeasures (US Patent No. 4307400, 1981 G01S 13/40), containing a receiving antenna, a receiver, a filter, a continuous signal generator, a video signal detector, a pulse generator, a gating circuit, a transmitting antenna. The antenna provides radiation of a continuous signal at the operating frequency of the suppressed radar. The emission is interrupted synchronously with each repetition period of the radar pulses received by the receiver.

The disadvantage of the second analogue is its single-channel in terms of the number of serviced objects for suppression in conditions when several objects for suppression can be located in the antenna pattern or in the coverage area (outside the bottom).

The closest, in terms of technical essence and technical result to the claimed invention, is a multi-channel automated device for jamming radar stations, adopted as a prototype of the invention (US Patent No. 3896439, 1975 H04K 3/00). This device contains: a receiving antenna, an input switch, a broadband UHF input, which is also a source of a thermal noise signal generated continuously over the entire operating frequency range of the receiver, a signal splitter, a signal combiner, a bandpass filter unit (FFT) and N key frequency channel circuits, each of which consists of a frequency channel detector, a frequency channel video amplifier, a frequency channel control signal generator, as well as a frequency channel switch, a strobe pulse shaper, a switch, an output UHF and a transmitting antenna. Moreover, the output of the input switch, the first input of the high-frequency signal (HF) connected to the output of the receiving antenna and the second input of the control signal, connected to the first output of the strobe pulse shaper, is connected to the input of the broadband input UHF, the output of which is connected to the input of the signal splitter and signal input of the RF switch. The output of the switch is connected to the first input of the HF signal of the output UHF, the output of which is connected to the input of the transmitting antenna, the second input of the control signal of the output UHF is connected to the second output of the strobe pulse shaper. N outputs of the signal splitter are connected to the corresponding inputs of N FFT bandpass filters, the outputs of which are connected to the first inputs of the RF signal of the frequency channel switches corresponding to the frequency channel and the frequency channel detectors, the outputs of which are connected to the inputs of the video amplifiers of the frequency channels of their frequency channels. The outputs of the frequency channel video amplifiers are connected to the inputs of the frequency channel control signal generators of their frequency channels, the outputs of which are connected to the second control signal inputs of the frequency channel switches of their frequency channels. The outputs of the frequency channel switches are connected to the corresponding HF signal inputs of the signal adder, the output of which is connected to the first HF signal input of the output UHF. Known device (prototype of the invention) works as follows. The signals received by the receiving antenna, through the input switch open in the reconnaissance mode, amplified by the input UHF, in accordance with their carrier frequency, fall along with the noise signal into one of the frequency channels, where they are detected, amplified and fed to the frequency channel control signal generator. The frequency channel control signal conditioner incorporates a threshold circuit whose trigger level is set high enough to prevent accidental triggering of the system by noise. In response to the incoming signal, the amplitude of which exceeds a predetermined threshold level in the frequency range of the corresponding frequency channel, the frequency channel switch of this frequency channel is closed. The interference signal is formed by modulating the received signal with thermal noise, then summing the signals in the signal adder and amplifying in the output amplifier. To ensure decoupling between the input and output circuits and to control the operation of the detected targets, the input switch and the output UHF are alternately strobed. If several radar stations are operating, each on its own frequency, then two or more frequency channels can be opened simultaneously. An additional property of such a device is the ability to create barrage interference. In this case, the noise source, which is used as a broadband input UHF, can be connected directly to the output UHF using a switch.

The disadvantage of the prototype is that it effectively interferes with airborne radars (BRLS) operating at close frequencies (in the same frequency channel). The actual conditions for the use of electronic countermeasures (REW) are characterized by the fact that during operation, both in their AP and in the coverage area (outside the AP), there may be several objects for suppression. If there are several objects for suppression with operating airborne radars in the AP of the REB, where each operates at its own frequency, then two or more frequency channels can be opened simultaneously in the REB and, thus, all objects will be affected by interference. However, the disadvantage in this case will be that, as a result, due to the increase in the width of the interference spectrum, the interference power spectral density decreases, and, as a result, the radar suppression efficiency decreases. For example, if the radiation of two objects is simultaneously received for suppression in different frequency channels, then the spectral density of the interference power created by each of them will decrease by half, and, consequently, the suppression range will decrease by 1.4 times. When there are several objects for suppression with operating airborne radars in the coverage area of the electronic warfare facility, in conditions when it is built single-channel in space, only one of them will be suppressed. In this situation, the number of objects to be suppressed in the zone of action of electronic countermeasures will be equal to the number of electronic countermeasures. Increasing the number of single-channel electronic warfare equipment to suppress several objects is unacceptable, as it leads to an increase in their number.

Features of the claimed invention, coinciding with the features of the prototype: a strobe pulse shaper, a signal splitter, a signal adder, a bandpass filter unit and N key circuits of frequency channels, each of which consists of a frequency channel detector, a frequency channel video amplifier, a frequency channel control signal generator, and also a frequency channel switch. Moreover, the first output of the output of the control signal of the strobe-pulse shaper is connected to the second inputs of the control signal of the input switches of the block of input switches, and the second output of the control signal of the strobe-pulse shaper is connected to the second inputs of the output UHF of the output UHF block. The signal input of the RF signal splitter is connected to the output of the input signal adder, the N outputs of the signal splitter are connected to the corresponding inputs of the N FFT bandpass filters, the outputs of which are connected to the first RF signal inputs of the frequency channel switches corresponding to the frequency channel and the frequency channel detectors, the outputs of which are connected to inputs of video amplifiers of frequency channels of their frequency channels. The outputs of the frequency channel video amplifiers are connected to the inputs of the frequency channel control signal generators of their frequency channels, the outputs of which are connected to the second control signal inputs of the frequency channel switches of their frequency channels. The outputs of the channel switches are connected to the corresponding signal inputs of the RF signal adder, the output of which is connected to the (L+1)-th signal input of the RF switch.

The objective of the present invention is to increase the efficiency of a multi-channel automated device for counteracting radar reconnaissance by increasing the number of radar stations of aerial radar parametric reconnaissance that it suppresses by creating intermittent noise interference using the features of their operation.

The solution of this problem is feasible due to the fact that in a known device containing a receiving antenna, an input switch, a broadband input UHF, which is simultaneously a source of a thermal noise signal generated continuously over the entire operating frequency range of the receiver, a signal splitter, a signal adder, a block of bandpass filters (FFT) and N key frequency channel circuits, each of which consists of a frequency channel detector, a frequency channel video amplifier, a frequency channel control signal generator, as well as a frequency channel switch, a strobe pulse shaper, a switch, an output UHF and a transmitting antenna, a receiving antenna is introduced a device consisting of an antenna array (AR) of a receiving antenna device consisting of K horn radiators and a beam-forming circuit (DOS) of the receiving antenna device, an input switch block consisting of L input switches, where L is the number of partial radiation patterns (RP) of the receiving antenna th device, a block of high-frequency input amplifiers consisting of L input UHF, an input signal adder, a block of shapers consisting of L channels, each of which consists of a detector, a video amplifier and a control signal conditioner connected in series, block diagrams AND, consisting of L channels, each of which has N circuits AND, where N is the number of frequency channels, a control unit, a channel key, a decoder of frequency channel numbers, a decoder of partial pattern numbers, a switch, a DOS, a high-frequency output amplifier unit consisting of K output UHF, a transmitting antenna array, consisting of K horn emitters.

Let us consider in more detail the proposed technical solutions.

The object of interference created by a multi-channel automated device to counter radar reconnaissance is the radar of parametric airborne radar reconnaissance, in which the “k out of m” criterion is implemented in the target trajectory linking (detection) algorithm (k and m are the number of radar survey cycles of airborne radar reconnaissance ).

Onboard radars of airborne radar systems operate in pulse-Doppler mode with a high pulse repetition rate when airborne targets are detected, as well as in a pulsed mode with a low pulse repetition rate when surface targets are detected. Typical characteristics for them are:

The view area in azimuth is circular, with a uniform view over the view period equal to 10 s.

Viewing area in elevation (+5…15 degrees) with multi-beam viewing or scanning with single-beam antenna pattern.

The detection range of low-flying targets with an effective target scattering area σ _c =3...10 m ² is from 300 to 350 km and with σ _c =0.5...1.0 m ^{2 -} from 200 to 250 km.

The range of detection of air over-the-horizon targets with σ _c =30...60 m ² is from 550 to 650 km.

When setting up (detecting) target trajectories, in practice, the algorithms “2 out of 2”, “2 out of 3”, “3 out of 3” and “3 out of 4” are most often used. (B.C. Verba, Aviation complexes of radar surveillance and guidance. - M .: Radiotekhnika, 2008, p. 51, 59, 140).

The operating frequency range of the transmitter lies in the range from 3176 to 3425 MHz (Aviation complexes of radar patrol and guidance of the main capitalist countries. Under the general editorship of Academician E.A. Fedosov. - Scientific Information Center, 1990, p. 11).

The use of the features of the functioning of the radar of means of aerial radar parametric reconnaissance is as follows.

It is known that in the radar of airborne radar parametric reconnaissance in the algorithm for linking (detection) of target trajectories, the criterion "k out of m" is implemented, which in practice is most often used the criterion "2 out of 2", "2 out of 3", "3 out of 3" and “3 out of 4” and that the period of review of the radar area of airborne radar facilities is 10 s. (B.C. Verba, Aviation complexes of radar surveillance and guidance. - M: Radio engineering, 2008, p. 55, 140). Based on the analysis of the above features of the functioning of the radar of air radar means, in order to disrupt the tie-in (detection) of target trajectories in it, it is sufficient to ensure that the quality of detection in z of its surveys drops below the acceptable quality. To achieve such a suppression effect, intermittent noise interference can be used, the duration and repetition period of which is selected from the condition

zТ _obz ≤τ≤Т≤mТ _obz ,

where T _obz - the time of one review of the radar means of air radar, equal to 10 s;

τ, T - duration and period of intermittent noise interference.

Pauses of intermittent noise interference make it possible to create intermittent noise interference to other radar stations of airborne radar, which makes it possible to increase the number of suppressed radar stations of airborne parametric reconnaissance by means of REB.

At the same time, it is necessary to consider situations when the REB means has information about the criteria for setting (detection) of target trajectories used in the radar of air radar means and when this information is not available.

When there are several radar-emitting radars of airborne radars in the coverage area of the electronic warfare system and there is information about the criteria for setting (detection) of target trajectories used in them (in practice, most often the criteria for setting (detection) of trajectories “2 out of 2”, “3 out of 3”, "2 out of 3", "3 out of 4"), in order to disrupt the tie-up (detection) of trajectories, the REB tool needs to provide a decrease below the acceptable quality of detection for the criteria "2 out of 2", "3 out of 3" in one of m surveys and for criteria "2 out of 3", "3 out of 4" in two out of m reviews. By providing in the REB facility the successive switching of the antenna pattern in space from one radar of the airborne radar equipment to another, it will ensure the failure of the tie-in (detection) of trajectories in one and the deterioration of the quality of detection in the other (detection logic "2 out of 3"), in two (logic detection "2 out of 2" and "3 out of 4") and in three (detection logic "3 out of 3") considered by the radar of air radar. That is, pauses of intermittent noise interference make it possible to create intermittent noise interference in other spatial directions.

At the same time, for the criterion of initiation (detection) of trajectories “2 out of 2”, the duration of intermittent noise interference is T _obz , the period of intermittent noise interference is 2T _obz , for the criterion of initiation (detection) of trajectories “2 out of 3”, the duration of intermittent noise interference is 2T _obz , period of intermittent noise interference is equal to _{3Т obz} , for the criterion of linkage (detection) of trajectories "3 out of 3" the duration of intermittent noise interference is T _obz , the period of intermittent noise interference is _{3Т obz} and for the criterion of linkage (detection) of trajectories "3 out of 4" the duration of the noise intermittent interference is equal to 2T _obz , the period of noise intermittent interference is equal to 4T _obz .

Thus, if the REP tool has information about the criteria for setting (detection) of target trajectories used in the radar of airborne radar tools, it is possible to choose the optimal variant of the suppression algorithm in surveys. When using the “2 out of 3” trajectory initiation (detection) criterion, a decrease below the acceptable detection quality in two out of three surveys will make it possible to suppress one radar of airborne radar and degrade the quality of detection in another radar of airborne radar, operating in different spatial directions. When using the criterion of tying (detection) of trajectories "2 out of 2"("3 out of 4"), a decrease below the acceptable quality of detection in one (two) of two (four) surveys will make it possible to suppress two radars of air radar systems operating in different spatial directions. When using the “3 out of 3” trajectory linkage (detection) logic, a decrease below the acceptable detection quality in one of the three surveys will make it possible to suppress three radars of air radar systems operating in different spatial directions. That is, the implementation of noise intermittent interference, in the presence of information about the applied criteria for the tying (detection) of target trajectories, makes it possible to increase the number of simultaneously suppressed by the radar of airborne radar facilities in the coverage area of the electronic warfare facility, and, consequently, to increase its efficiency (Fig. 1a). In FIG. 1a is marked: S is the number of the review cycle of the radar of airborne radar; f _i - the frequency of the radiated interference of the i-th radar means of air radar.

When there are several radar-emitting radars of airborne radars in the coverage area of the electronic warfare system and there is no information about the criteria used in them for tying (detection) of target trajectories, which gives a guaranteed result in terms of the number of suppressed radars, is an algorithm that provides a decrease below the acceptable quality of detection in one of the two reviews . The duration of intermittent noise interference will be equal to T _obz , and the period of intermittent noise interference - 2T _obz . By providing sequential switching of the antenna radiation pattern in space from one radar of air radar to another, the REB tool will ensure the disruption of the tie (detection) of target trajectories in one and the deterioration of the quality of detection in the other (detection logic "2 out of 3") and in two (detection logic "2 out of 2", "3 out of 3" and "3 out of 4") of the radars of the airborne radar systems under consideration.

Thus, the implementation of intermittent noise interference in the absence of information about the criteria for tying (detection) of target trajectories used in the radar of air radar means, allows you to increase the number of simultaneously suppressed radar means of air radar in the coverage area of the REB, and therefore increase its efficiency (Fig. 1b ). In FIG. 1b is marked: S - the number of the review cycle of the radar of the airborne radar; f _i - the frequency of the radiated interference of the i-th radar means of air radar.

The above arguments show that the use of intermittent noise interference makes it possible to increase the number of simultaneously suppressed radars of airborne radar facilities in the coverage area of the electronic warfare facility in the absence of information on the applied criteria for tying (detection) of trajectories to two and in the presence of information on the applied criteria for tying (detection) of trajectories - up to three.

Since there is practically no information on the criteria for tying (detection) of target trajectories used in the radar of air radar means, it is necessary to use an algorithm on the REB tool that gives a guaranteed result in terms of the number of suppressed radars for detecting and tracking trajectories. This is an algorithm that provides a decrease below the acceptable quality of detection in one of the two surveys. The duration of intermittent noise interference will be equal to T _obz , and the period of intermittent noise interference - 2T _obz .

Thus, the implementation of noise intermittent interference makes it possible to increase the number of simultaneously suppressed by the radar of the air radar in the coverage area of the electronic warfare facility by a factor of two, and, consequently, to increase its efficiency. The result has been achieved: the number of suppressed radars of aerial radar equipment in the coverage area of the electronic warfare equipment has been doubled due to the creation of intermittent noise interference using the features of the operation of suppression objects.

The invention is illustrated by drawings.

In FIG. Figure 1 shows the structure of intermittent noise interference (the frequency distribution f _i of the radiated interference of the i-th radar of air radar facilities) at each radar survey cycle S for various target trajectory linking (detection) logics used in them; in fig. 2 is a block diagram of a multi-channel automated device for counteracting radar reconnaissance; in fig. 3 - a variant of the implemented algorithm in the control unit of a multi-channel automated device for counteracting radar reconnaissance.

The following notations are introduced on the figures:

1 - receiving antenna device;

1-1 - antenna array (AR) of the receiving antenna device, consisting of K horn radiators;

1-2 - beamforming circuit (DOS) of the receiving antenna device;

2 - block of input switches;

(2-i) - i-th input switch block 2, i varies from 1 to L, where L is the number of partial radiation patterns (DN) of the receiving antenna device (beams);

3 - block of high frequency input amplifiers (UHF);

(3-i) - i-th input UHF unit 3, i varies from 1 to L, where L is the number of partial DNs of the receiving antenna device (beams);

18 - input signal adder;

15 - block formers;

(15-1-1), ..., (15-L-1) - detectors of the block of formers 15, where L is the number of partial RPs of the receiving antenna device (beams);

(15-1-2), ..., (15-L-2) - video amplifiers of the block of formers 15, where L is the number of partial RPs of the receiving antenna device (beams);

(15-1-3), ..., (15-1,-3) - control signal generators (FSU) of the generator block 15, where L is the number of partial DNs of the receiving antenna device (beams);

5 - signal splitter;

6 - block of bandpass filters;

7 - frequency channel detector;

8 - frequency channel video amplifier;

9 - frequency channel control signal generator;

10 - frequency channel switch;

11 - strobe pulse shaper;

12 - signal adder;

16 - block diagrams AND, consisting of L channels, where L is the number of partial directional patterns of the receiving antenna device (beams);

(16-1-1), (16-1-2), ..., (16-1-N) - schemes AND of the first channel of the block of schemes AND, where N is the number of frequency channels;

(16-2-1), (16-2-2), ..., (16-2-N) - schemes AND of the second channel of the block of schemes AND, where N is the number of frequency channels;

…

(16-L-l), (16-L-2), (16-L-N) - schemes AND of the Z-th channel of the block of schemes And, where N is the number of frequency channels, L is the number of partial DNs of the receiving antenna device (beams);

17 - control unit;

19 - channel key;

20 - decoder of frequency channel numbers;

21 - decoder of partial DN numbers;

22 - switch;

23 - DOS;

13 - block of high frequency output amplifiers;

(13-i) - i-th output high frequency amplifier block output UHF 13, i varies from 1 to K;

14 - transmitting antenna array, consisting of K horn radiators.

The technical result and the task of the invention is achieved due to the fact that a multi-channel automated device for countering radar reconnaissance is supplemented by a receiving antenna device, consisting of an antenna array (AR) of the receiving antenna device, including K horn emitters and a DOS of the receiving antenna device, a block of input switches, consisting from L input switches, where L is the number of partial RPs of the receiving antenna device, a block of high-frequency input amplifiers, consisting of L input UHF, an input signal combiner, a block of shapers, consisting of L channels, each of which consists of a series-connected detector, video amplifier and shaper control signal, a block of schemes AND, consisting of L channels, each of which has N schemes And, where N is the number of frequency channels, a control unit, a channel key, a frequency channel number decoder, a partial pattern number decoder, a switch, DOS, b a block of high-frequency output amplifiers, consisting of K output UHF, a transmitting antenna array, consisting of K horn radiators.

The receiving antenna device 1 is designed to receive high-frequency (HF) radar signals of the air radar, consists of an antenna array of the receiving antenna device 1-1 and a DOS of the receiving antenna device 1-2. The antenna array of the receiving antenna device 1-1 consists of K horn emitters. To form a multibeam structure, a high-frequency DOS of the receiving antenna device 1-2 is used based on the Rothman lens. Such a lens consists of two parallel metal surfaces separated by a high-frequency dielectric layer, connected to coaxial terminals located on two opposite sides. The leads along one side are connected via HF cables to the corresponding emitters of the antenna array of the receiving antenna device. The leads on the opposite side are located along the focal arc, so that each of them corresponds to the direction of the beam axis in space. The shape of the lens and the length of the cables are the main parameters on which the process of beam formation (focusing) depends. All ray paths from a given focal point to the corresponding point of the wave front have the same electrical length. The location of the focal points is determined solely by the configuration of the DOS of the receiving antenna device. The lens focuses the signals so that only certain outputs are excited. The appearance of signals in the channels corresponding to these outputs makes it possible to determine the direction of the signal arrival.

Block input switches 2 is designed to lock the receiver for the duration of the interference signal and consists of L input switches, which can be performed, for example, on the switch, which is a waveguide section, along the centerline of which diodes are located, has L inputs and L outputs of RF signals and a control signal input.

High-frequency input amplifier block 3 is designed to amplify the RF signals received by the receiving antenna device 1 and consists of L high-frequency input amplifiers, which can be performed, for example, on a traveling wave lamp (TWT) and are at the same time a source of thermal noise signal generated continuously during throughout the operating frequency range of the REB means, has L inputs and L outputs of RF signals.

The input signal adder 18 serves to sum the RF signals, has L inputs and one output of the RF signals and can be performed, for example, on T-bridges.

The block of generators 15 is intended for generating control signals, has L inputs of RF signals and L outputs for issuing control signals, consists of L channels, each of which consists of a detector, a video amplifier and a control signal generator connected in series. The detector is made on a diode, the video amplifier is made on a transistor, the control signal conditioner is made on an amplitude comparator, the operation level of which is set high enough to prevent accidental triggering from noise.

The signal splitter 5 serves to supply the RF signal to the N inputs of the bandpass filter unit 6, has one input and N outputs of the RF signals and can be performed, for example, on T-bridges.

Bandpass filter block 6 is designed to separate the input signals by their carrier frequencies, has N inputs and N outputs of RF signals.

The frequency channel detector 7 is designed to detect signals, is made on a diode, has an input and an output.

Video amplifier frequency channel 8 is designed to amplify the detected signals, made on a transistor, has an input and output.

The frequency channel control signal generator 9 is designed to generate control signals, it is made on an amplitude comparator, the operation level of which is set high enough to prevent accidental triggering from noise, it has a video signal input and a control signal output.

The frequency channel switch 10 is designed to open the frequency channel when a control signal is received from the output of the corresponding frequency channel control signal generator 9, is made similar to the input switches of the input switch block 2, has an input and output of RF signals and an input for supplying a control signal.

The strobe pulse shaper 11 is designed to provide alternate gating of the input switches of the block of input switches 2 and the output UHF of the block of high-frequency output amplifiers 13, providing isolation between their input and output circuits, and can be performed, for example, on a waiting multivibrator generating a control signal and triggering its clock generator, has two outputs for issuing control signals.

The signal adder 12 serves to sum the RF signals, has N inputs and one RF signal output and can be performed, for example, on T-bridges.

The block of circuits And 16 is designed to generate control signals, consists of L channels, each of which has N circuits And, has L inputs for supplying control signals from the output of the block of generators 15 and N inputs for supplying control signals from the outputs of the generators of the control signal of frequency channels 9 and each The L-th channel of the block diagrams And 16 has N outputs for issuing control signals to the control unit 17.

The control unit 17 is made on the basis of a computer Baguette-23 V or Baguette-53 based on a processor 1 V578 for real-time control, has an input for supplying a control signal from the output of the strobe pulse shaper 11, N inputs for supplying control signals from the output of each L- th channel of the block diagrams And 16, the first and second outputs for issuing control signals, respectively, to the decoder of frequency channel numbers 20 and the decoder of partial DN numbers 21.

The channel key 19 is designed to open the frequency channel when a control signal is received from the corresponding output of the frequency channel number decoder 20, it is made similar to the frequency channel switch 10.

The frequency channel number decoder 20 is designed to recognize the code combination and issue a control signal from the corresponding output to the channel key 19 corresponding to the code combination and open it, is made on the basis of triggers, has a control signal input and N control signal outputs.

The decoder of partial DN numbers 21 is designed to recognize the code combination and issue a control signal from the corresponding output to the input of the switch 22 corresponding to the code combination, is made on the basis of triggers, has a control signal input and L control signal outputs.

The switch 22 is designed to supply an RF signal (interference signal) to the corresponding input of the DOS 23, has an input and L high-frequency signal outputs, L control signal inputs, and can be, for example, a high-speed multi-arm Teeter switch based on a hybrid directional coupler.

DOS 23 is designed to form a multi-beam radiation structure, is made similar to the DOS of the receiving antenna device 1-2 of the receiving antenna device 1, has L inputs and K high-frequency signal outputs.

High-frequency output amplifier block 13 is designed to amplify RF signals, consists of K output high-frequency amplifiers, which can be performed, for example, on a traveling wave tube (TWT), has K inputs and K outputs of RF signals.

The transmitting antenna array 14 is made similar to the AR of the receiving antenna device 1-1 of the receiving antenna device 1, has K RF signal inputs.

L outputs of the receiving antenna device 1 are connected to the corresponding L signal inputs of the RF block of the input switches 2. To the signal outputs of the RF antenna array of the receiving antenna device 1-1 of the receiving antenna device 1 are connected to the corresponding K inputs of the RF signal supply of the beamforming circuit of the receiving antenna device 1 -2, the outputs of which are the outputs of the receiving antenna device 1.

The L outputs of the block of input switches 2 are connected to the corresponding L inputs of the RF signals of the block of input high-frequency amplifiers 3, its control signal input, which is the input of the input switches, each of which has an input and output of a high-frequency signal and whose input and output are corresponding input and output of the block of input switches 2, is connected to the first output of the output of the control signal of the strobe-pulse shaper 11, which excludes the reception of signals for the time of the formation of interference.

L outputs of the high frequency input amplifier block 3 are connected to the corresponding L inputs of the RF signal supply of the shaper block 15 and the corresponding L inputs of the RF signal input of the input signal adder 18. The inputs and outputs of the RF input high frequency amplifier signals are the corresponding inputs and outputs of the high frequency input amplifier block 3.

L outputs for issuing control signals of the block of generators 15 are connected to the corresponding inputs for supplying control signals of the block of circuits And 16, in which they are input control signals of all circuits And of the corresponding channels. L outputs for the output of signals of the detectors of the block of shapers 15, the inputs of which are the corresponding inputs of the block of formers 15, are connected to the corresponding inputs for the supply of video signals of the video amplifiers of the block of formers 15, the outputs for the output of video signals of the video amplifiers are connected to the corresponding inputs for the supply of video signals of the generators of the control signal of the block of formers 15. Outputs for the output of control signals shapers of the control signal of the block of formers 15 are the corresponding outputs of the block of formers 15.

The output of the input signal adder 18 is connected to the input of the high-frequency signal of the signal splitter 5, the N outputs of which are connected to the corresponding N inputs of the block 6 bandpass filters.

N outputs of the band pass filter unit 6 are connected to the first inputs of the RF signal of the frequency channel switch 10 and the frequency channel detector 7 corresponding to the frequency channel, the outputs of which are connected to the corresponding video signal inputs of the frequency channel 8 video amplifiers, the video outputs of the frequency channel 8 video amplifiers are connected to the corresponding inputs the outputs of the control signals of the frequency channel control signal generators 9. The outputs of the control signals output of the frequency channel control signal generators 9 are connected to the second inputs of the control signal supply of the corresponding switch frequency channel 10, and the input of the control signal supply of the block diagrams And 16, in which it is the input control signal of the corresponding schemes AND all channels. The outputs of the frequency channel switches 10 are connected to the first inputs of the corresponding channel keys 19.

The first output for issuing a control signal of the strobe pulse shaper 11 is connected to the (L+1)-th input of the control signal supply of the control unit 17 and the input of the control signal supply of the input switch unit 2, in which it is fed to the second inputs of the control signal supply of the input switches of the input switch unit switches 2, the second output of the output of the control signal of the strobe pulse shaper 11 is connected to the input of the control signal of the block of output amplifiers of high frequency 13, in which it is fed to the second inputs of the control signal of the output amplifiers of high frequency of the block of output UHF 13.

The inputs of the RF channel keys 19 are connected to the corresponding outputs of the frequency channel switches 10, the outputs of the channel keys 19 are connected to the corresponding signal inputs of the RF signal adder 12, the output of which is connected to the (L+1)-th signal input of the RF switch 22.

N outputs for issuing control signals of each of the L channels of the block diagrams And 16 are connected to the corresponding inputs of the control unit 17. The first and second outputs for issuing control signals of the control unit 17 are connected to the inputs for supplying control signals, respectively, of the decoder of numbers of frequency channels 20 and the decoder of numbers of partial DN 21, The (L+1)th input of the control signal supply of the control unit 17 is connected to the first output of the strobe pulse shaper 11.

N outputs for issuing control signals of the decoder of numbers of frequency channels 20 are connected to the corresponding second inputs for supplying control signals of channel keys 19. L outputs for issuing control signals of the decoder of numbers of partial DNs 21 are connected to the corresponding inputs for supplying control signals of switch 22.

The L outputs of the RF switch 22 are connected to the corresponding inputs of the RF DOS 23, the outputs of which are connected to the corresponding inputs of the RF signals of the high-frequency output amplifier unit 13, in which they are fed to the corresponding first inputs of the RF output signals of the high-frequency output amplifiers of the block weekend UHF 13.

To the outputs of the RF signals of the high-frequency output amplifier block 13, which are the outputs of the high-frequency amplifiers of the high-frequency output amplifier block 13, are connected to the corresponding inputs of the RF signal supply of the transmitting antenna array 14.

The inventive multi-channel automated device for counteracting radar reconnaissance is implemented according to the block diagram of Fig. 2. The following standard elements were used as functional elements: horn feeds AR of the receiving antenna device 1-1 and transmitting AR 13 (G.B. Belotserkovsky. Antennas. - M .: State Publishing House of the Defense Industry, 1956, S. 408 ); DOS of the receiving antenna device 1-2 and DOS 23 (Radioelectronic Technologies of Russia. Almanac "Russia: Union of Technologies." - M: NO Association "League for Assistance to Defense Enterprises", 2012, p. 66; G.B. Belotserkovsky. Antennas. - M .: State Publishing House of the Defense Industry, 1956, S. 392); frequency channel number decoder 20, partial DN number decoder 21 (Handbook of radio electronics. Volume 3. Edited by A.A. Kulikovsky. - M .: Energia Publishing House, 1970, S. 337; Handbook on the basics of radar technology. Under the editorship of V. V. Druzhinin. - M.: Military publishing house, 1967, S. 654); control unit 17 (Catalogue of products of KB "Korund" "Baguette-family of computers for special applications." - Moscow, PO Box 10, 2000, pp. 12, 13; http://wwwp.rpkb.ru official website of Ramensky Instrument Design Bureau); input switches of the block of input switches 2, frequency channel switch 10, channel key 19 (G. Watson “Microwave semiconductor devices and their application”. Translation from English, edited by B.C. Atkin. - M .: Mir Publishing House, 1972, C 344, 352; Handbook of elements of radio electronic devices. Edited by V. N. Dulin, M. S. Zhuk. - M.: Energia Publishing House, 1977, p. 472); switch 22 (A.F. Harvey. Microwave Technique. Volume 1. Translation from English, edited by V.I. Sushkevich. - M .: Soviet Radio Publishing House, 1965, S. 188); high-frequency amplifiers of the input UHF block 2, signal splitter 5, signal adder 12, input signal adder 18, high-frequency amplifiers of the output UHF block 13 (A.F. Harvey. Microwave Technique. Volume 1. Translation from English, edited by V.I. Sushkevich. - M.: Publishing house "Soviet radio", 1965, S. 636, 290; Handbook on the elements of radio electronic devices. Edited by V. N. Dulin, M. S. Zhuk. - M.: Publishing house "Energy ", 1977, S. 69, 468; block of bandpass filters 6 (A.F. Harvey. Microwave technique. Volume 1. Translation from English, edited by V.I. Sushkevich. - M .: Publishing house "Soviet radio" , 1965, S. 281); clock pulse generator of the strobe pulse shaper 11 (G.Ya. Mirsky. Electronic measurements. - M.: "Radio and communication", 1986, S. 385); detector 7 and detectors of the block of formers 15 (G. Watson “Microwave semiconductor devices and their application”. Translation from English, edited by B.C. Atkin. - M .: Mir Publishing House, 1972, p. 415; A. F. Harvey. Microwave technology. Volume 1. Translation from English, edited by V.I. Sushkevich. - M .: Publishing house "Soviet radio", 1965, S. 203); the waiting multivibrator of the strobe-pulse shaper 11, the frequency channel control signal shaper 9, the shapers of the shaper block 15, the circuits And the block circuits And 16 (V.I. Kuzmich, N.S. Spiridonov, I.K. Tregub. Fundamentals of pulse technology. - Kyiv: KVIRTU PVO, 1973, S. 247, 405, 372).

The newly introduced elements make it possible to ensure, when in the coverage area of a multi-channel automated device to counteract several radars of airborne radar, their consistent suppression by intermittent noise interference.

At the same time, the positive effect is to increase the efficiency of a multi-channel automated device to counter radar reconnaissance by increasing the number of aerial radar equipment suppressed by it, which are simultaneously in the coverage area of a multi-channel automated device to counter radar reconnaissance through the use of all distinctive features. The specified set of distinguishing features is new, since it has not been cited in the well-known literature on the issues of electronic suppression of airborne radars.

The technical result of the invention consists in doubling the number of suppressed by radar means of air radar in the coverage area of a multi-channel automated device for jamming radar stations, which is achieved by creating intermittent noise interference to radar stations using the features of the operation of suppression objects and for given initial data about this system specifying the number of views to be subjected to interference.

Multi-channel automated device to counter radar reconnaissance operates as follows.

The shaper of the strobe pulse 11 determines the mode of operation ("intelligence", "suppression"). The signals of the strobe pulse shaper 11, arriving at the input switches 2-1 ... 2-L of the block of input switches 2 and the output UHF 13-1 ... output circuits.

The high-frequency signals of the radar-emitting means of the air radar are received by the emitters of the antenna array 1-1 of the receiving antenna device 1, pass through the lens of the beam-forming circuit of the receiving antenna device 1-2 of the receiving antenna device 1, which focuses them so that only certain of its outputs are excited, pass through the corresponding input switches of the block of input switches 2, open in the reconnaissance mode, for amplification to the corresponding high-frequency input amplifiers of the block of high-frequency input amplifiers 3, which are simultaneously sources of thermal noise signals generated in the entire operating frequency range and further, to the corresponding channels of the block of formers 15 , each of which consists of a series-connected detector, a video amplifier, a control signal shaper and the corresponding inputs of the input signal adder 18.

From the output of the input signal adder 18, the RF signals pass to the signal splitter 5, from the outputs of which, in accordance with their carrier frequency, through the corresponding band-pass filter of the band-pass filter unit 6, together with the noise signal, they enter one of the frequency channels, where they are detected by the frequency channel detector 7, are amplified by the frequency channel video amplifier 8, and then fed to the frequency channel control signal generator 9, which, like the channel control signal generators of the generator block 15, incorporates an amplitude comparator, the response level of which is set high enough to prevent accidental start-up of the system from noise and which, in response to the received signal to the frequency channel control signal generator 9, the amplitude of which exceeds a certain level in the frequency range of the corresponding channel, closes the switch of this frequency channel 10.

From the outputs of the channel shapers of the block of shapers 15, the signals are fed to the first inputs of all circuits AND of the corresponding channels of the block of circuits AND 16, from the outputs of the shapers of the control signal of the frequency channels 9, the signals are fed to the second inputs of the corresponding circuits AND of all channels of the block of circuits AND 16. The signal is at the output of the circuit AND is a sign of the presence of a signal emitting radar means of air radar in a specific partial radiation pattern and a specific frequency channel. Information about the presence in the partial DNs and in the frequency channels of the radar-emitting radar means of the air radar L(i, j) from the output of the circuits AND channels of the circuit block AND 16 is fed to the corresponding inputs of the control unit 17, which, based on the information received, develops a decision (one of the options implemented algorithm in the control unit 17 is shown in Fig. 3) about the numbers of targets (q), the numbers of partial radiation patterns (ga) and the numbers of frequency channels (k) on which interference will be placed, the order of jamming in partial DNs (frequency channels) and parameters interference (duration - τ _P , period - T _P ) and in accordance with which, upon receipt from the strobe pulse shaper 11, the signal establishing the jamming mode, the control unit 17 will issue sequentially in time with a cycle equal to the survey period of the radar of the air radar, in the form digital parallel codes information about the numbers of partial patterns and the numbers of frequency channels on which interference will be placed on the decoders numbers of partial DN 21 and numbers of frequency channels 20, respectively.

The decoder of numbers of partial DN 21, having recognized the code combination, outputs from the corresponding output a control signal to the input of the switch 22 corresponding to the code combination, which provides the RF signal (interference signal) to the corresponding input of the DOS 23, the decoder of numbers of frequency channels 20, having recognized the code combination, issues from the corresponding output, the control signal to the channel key 19 corresponding to the code combination and opens it. The duration of each control signal determines the duration of the interference signal determined by the control unit 17. Thus, the switch 22 and the corresponding channel key 19 will open for a time equal to the duration and with the repetition period of the interference in a particular partial pattern and a particular frequency channel.

The interference signal is formed by modulating the received radar signal with thermal noise, passing through the input signal adder 18 and then through the corresponding bandpass filters of the bandpass filter block 6, then through the open frequency channel switches 10, through which the signals are received, channel keys 19, which received the control signal from the frequency channel number decoder 20, subsequent summation of the signals in the signal adder 12, passing through the switch 22 to the corresponding input of the DOS 23, amplification by the high frequency amplifiers of the high frequency output amplifier block 13 and radiation by the horn radiators of the transmitting antenna array 14.

Distinctive features of the invention

A receiving antenna device is introduced, consisting of an antenna array of a receiving antenna device, consisting of K horn radiators and a beam-forming circuit of the receiving antenna device, an input switch block consisting of L input switches, where L is the number of partial radiation patterns of the receiving antenna device, a block of input amplifiers of high frequency consisting of L input UHF, input adder of signals, a block of shapers, consisting of L channels, each of which consists of a series-connected detector, a video amplifier and a control signal conditioner, block circuits AND, consisting of L channels, each of which has N circuits AND , where N is the number of frequency channels, a control unit, a channel key, a frequency channel number decoder, a partial pattern number decoder, a switch, a DOS, a high-frequency output amplifier unit consisting of K output UHF, a transmitting antenna array consisting of K horn radiators.

Thus, the task of the present invention, which consists in increasing the efficiency of a multi-channel automated device for countering radar reconnaissance by increasing the number of radar stations of aerial radar parametric reconnaissance suppressed by it by creating noise intermittent interference using the features of their functioning, has been solved. The number of suppressed radar means of RPR in the coverage area of a multi-channel automated device to counter radar reconnaissance has been doubled.

The technical result and the task of the invention are achieved due to the fact that the multi-channel automated device for countering radar reconnaissance is supplemented by a receiving antenna device, consisting of an antenna array of the receiving antenna device, including K horn emitters and a beam-forming circuit of the receiving antenna device, with an input switch unit consisting of L input switches, where L is the number of partial radiation patterns of the receiving antenna device, a block of high-frequency input amplifiers, consisting of L input UHF, an input signal adder, a block of shapers, consisting of L channels, each of which consists of a series-connected detector, video amplifier and shaper control signal, a block of circuits AND, consisting of L channels, each of which has N circuits And, where N is the number of frequency channels, a control unit, a channel key, a decoder of frequency channel numbers, a decoder number ov partial DN, a switch, a DOS, a block of high-frequency output amplifiers, consisting of K output UHF, a transmitting antenna array, consisting of K horn radiators.

Claims (1)

A multi-channel automated device for countering radar reconnaissance, containing a receiving antenna, an input switch, a broadband high-frequency input amplifier (UHF), a signal splitter, a signal adder, a band-pass filter (FFT) and N key circuits of frequency channels, a strobe pulse shaper, a switch, an output UHF and a transmitting antenna, characterized in that a receiving antenna device is introduced, consisting of an antenna array (AR) of the receiving antenna device, including K horn radiators, and a beam-forming circuit (DOS) of the receiving antenna device, an input switch unit consisting of L input switches , where L is the number of partial radiation patterns (DN) of the receiving antenna device, the input UHF block, consisting of L input UHF, the input signal adder, the block of shapers, consisting of L channels, each of which consists of a detector, a video amplifier and a signal conditioner connected in series managed iya, block diagrams AND, consisting of L channels, each of which has N circuits AND, where N is the number of frequency channels, control unit, channel key, frequency channel number decoder, partial pattern number decoder, switch, DOS, UHF output block, consisting of K output UHF, a transmitting antenna array consisting of K horn radiators, in addition, the receiving antenna device has L HF signal outputs, the antenna array of the receiving antenna device has K HF signal outputs, the DOS of the receiving antenna device has K inputs and L signal outputs RF, the DOS outputs of the receiving antenna device are the corresponding outputs of the receiving antenna device, the block of input switches has L inputs and L outputs of RF signals and a control signal input, which is connected to the second input of the input switches of the block of input switches, the inputs of the RF signals of the block of input switches are connected to the first inputs of the RF signals of the corresponding input switches of the block input of the input commutators and the RF signal outputs of the input commutator block are the RF signal outputs of the corresponding input commutators of the input commutator block, the high frequency input amplifier block has L inputs and L outputs of the RF signals, the high frequency signal inputs and outputs of the high frequency input amplifiers are the corresponding signal inputs and outputs RF block of high-frequency input amplifiers, the input summator of signals has L inputs and one output of RF signals, the block of shapers has L inputs of RF signals and L outputs for the output of control signals, the detectors of the channels of the block of shapers have an input of the RF signal and a video signal output, the video amplifiers of the channels of the block of formers have input and output of video signals, the shapers of the control signal of the block of shapers have an input for supplying video signals and an output for issuing a control signal, the inputs of the block of shapers are the inputs of the corresponding detectors of the channels of the block of shapers, the outputs of the shapers of the control signal of the block fo conditioners are the corresponding outputs of the shaper block, the signal splitter has one input and N outputs of RF signals, the FFT has N inputs and N outputs of RF signals, the frequency channel detector has an RF signal input and a video signal output, the frequency channel video amplifier has a video signal input and output, a signal conditioner the frequency channel control has a video signal input and a control signal output, the frequency channel switch has an RF signal input and output and a control signal input, the strobe pulse shaper has two control signal outputs, the signal adder has N inputs and one RF signal output, block diagram AND has L inputs for supplying control signals from the output of the block of generators, in which they are input control signals of all circuits AND of the corresponding channels of the block of diagrams AND, and N inputs for supplying control signals from the outputs of the generators of the control signal of frequency channels, in which they are input controlssignals of the corresponding circuits AND of all channels of the block of circuits AND, and each L-th channel of the block of circuits AND has N outputs for issuing control signals to the control unit, the control unit has (L + 1)-th input for supplying a control signal from the output of the strobe pulse shaper, N inputs for supplying control signals from the output of each L-th channel of the block of circuits AND, the first and second outputs for issuing control signals, respectively, to the decoder of frequency channel numbers and the decoder of partial pattern numbers, the channel key has an input and output of RF signals and an input for supplying a control signal, a decoder number of frequency channels has a control signal input and N control signal outputs, the decoder of partial pattern numbers has a control signal input and L control signal outputs, the switch has an input and L high-frequency signal outputs, L control signal inputs, DOS has L inputs and K high-frequency signal outputs, the block of high-frequency output amplifiers has K inputs and K RF signal outputs and a control signal input, which is connected to the second inputs of the UHF output high-frequency output amplifier unit, the RF signal inputs and outputs of the high-frequency output amplifier unit are the inputs and outputs of the RF signals of the corresponding UHF output high-frequency output amplifier unit, the transmitting antenna array has K inputs of RF signals, and L outputs of the receiving antenna device are connected to the corresponding L inputs of the RF signals of the block of input switches, K outputs of the RF signals of the antenna array of the receiving antenna device are connected to the corresponding K inputs of the RF signals of the beamforming circuit of the receiving antenna device, L outputs which are the corresponding outputs of the receiving antenna device, L outputs of the input switch unit are connected to the corresponding L inputs of the RF signal supply of the high-frequency input amplifier unit, its control signal input, which is the second input of the input th switches, each of which has an input and output of a high-frequency signal, and for which the input and output of the RF signals is the corresponding input and output of the RF signals of the block of input switches, is connected to the first output of the output of the control signal of the strobe pulse shaper, which excludes the reception of signals on interference generation time, L outputs of the high-frequency input amplifier unit are connected to the corresponding L inputs of the RF signal supply of the shaper unit and the corresponding L inputs of the RF signal supply of the input signal adder, the inputs and outputs of the high-frequency signals of the high-frequency input amplifiers are the corresponding inputs and outputs of the RF unit signals high-frequency input amplifiers, L outputs for issuing control signals of the shaper block are connected to the corresponding inputs for supplying control signals of the block of circuits AND, in which they are input control signals of all circuits AND of the corresponding channels, the outputs for issuing video signals of the detectors block and the shapers, the inputs of which are the corresponding inputs of the shaper unit, are connected to the corresponding inputs of the video signals of the video amplifiers of the shaper unit, the outputs of the output of video signals of the video amplifiers of the shaper unit are connected to the corresponding inputs of the video signal feed of the shapers of the control signal of the unit of shapers, the outputs of the output of control signals of the shapers of the control signal of the unit of control are corresponding outputs of the shaper block, the output of the input signal adder is connected to the high-frequency signal input of the signal splitter, N outputs of which are connected to the corresponding N inputs of the band-pass filter unit, N outputs of the band-pass filter unit are connected to the first inputs of the RF signal supply of the frequency channel switch and the detector corresponding to the frequency channel frequency channel, the outputs of which are connected to the corresponding inputs for the supply of video signals of the video amplifiers of the frequency channel, the outputs for issuing video signals of the video amplifiers of the frequency channel are connected to the corresponding inputs of the video signals of the frequency channel control signal generators, the outputs of the control signals of the frequency channel control signal generators are connected to the second inputs of the control signal supply of the corresponding frequency channel switch and the input of the control signal supply of the block of circuits AND, in which it is the input control signal of the corresponding circuits AND all channels, the outputs of the frequency channel switches are connected to the first inputs of the corresponding channel switches, the first output of the control signal output of the strobe pulse shaper is connected to the (L + 1)-th input of the control signal supply of the control unit and the input of the control signal supply of the unit input switches, in which it is fed to the second inputs of the control signal supply of the input switches of the block of input switches, the second output of the output of the control signal of the strobe pulse shaper is connected to the supply input and the control signal of the block of high-frequency output amplifiers, in which it is fed to the second inputs of the control signal of the output amplifiers of the high frequency of the output UHF block, the outputs of the channel keys are connected to the corresponding inputs of the RF signals of the signal adder, the output of which is connected to (L + 1) - m input of the RF switch, N outputs for issuing control signals of each of the L channels of the block diagrams And are connected to the corresponding inputs of the control unit, the first and second outputs for issuing control signals of the control unit are connected to the inputs for supplying control signals, respectively, of the frequency channel number decoder and the partial number decoder DN, (L+1)-th input of the control signal supply of the control unit is connected to the first output of the strobe pulse shaper, N outputs of the output of control signals of the frequency channel number decoder are connected to the corresponding second inputs of the control signal supply of the channel keys, L outputs of the output of signals y the boards of the decoder of partial DN numbers are connected to the corresponding inputs for supplying control signals of the switch, L outputs for issuing signals of the RF switch are connected to the corresponding inputs for supplying signals of the RF DOS, the outputs of which are connected to the corresponding inputs for supplying RF signals of the high-frequency output amplifier unit, in which they are fed to the first RF signal inputs of the corresponding high frequency output amplifiers of the output UHF block, K of the RF signal outputs of the high frequency output amplifier block, which are the outputs of the high frequency amplifiers of the high frequency output amplifier block, are connected to the corresponding RF signal inputs of the transmitting antenna array.

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