RU2646602C1 - Broadband transceiver with software programmable resetting for the phase signal - Google Patents

Abstract

FIELD: radio engineering and communications.

SUBSTANCE: invention refers to the field of wireless communication, in particular to digital radio communication, and is intended for use in the information transmission systems by means of interference-proof signals with multiphase manipulation. Broadband transceiver consists of the transmitting and receiving part, in addition to the transmitting part of the device, the phase shift control unit (4) is introduced, the information input of which is connected to the output of the high-frequency switch (3), and the control inputs are connected to the corresponding outputs of the decoder (6). Input of the decoder (6) is connected to the output of the pseudo-random sequence generator (7), the output of the phase shift control unit (4) is connected to the first input of the frequency mixer (5). Phase shift control unit (24), the information input of which is connected to the output of the mixer (23), was additionally introduced in the receiving part of the device, and the control inputs are connected to the corresponding outputs of the decoder (22), the input of which is connected to the output of the pseudo-random sequence generator (18), and the output of the phase shift control unit (24) is connected to the input of the intermediate frequency amplifier (25).

EFFECT: technical result consists in increasing the noise immunity of the generated radio signal under the influence of imitation interference due to the pseudo-random phase change of the signal.

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Description

The claimed device relates to telecommunications, namely to digital radio communications, and can be used in information transmission systems by means of noise-immune signals with software phase adjustment of the signal.

Known broadband transceiver device that transmits messages in the program frequency tunable operating frequency frequency hopping (RFP), RF patent No. 2185029 from 07/10/2002, this device contains on the transmitting side: encoder, synchronization unit, pseudo-random sequence generator (PSP), control unit, frequency synthesizer, modulator, power amplifier, transmitting antenna, bandwidth converter. On the receiving side: a receiving antenna, an input amplifier, a local oscillator, a detector, an automatic gain control unit, a solver, a decoder, a synchronization unit, a PSP generator, a control unit, a pseudo-random sequence converter.

The disadvantage of this analogue is the relatively low noise immunity under the influence of intentional interference imitating the structure of the radio signal.

Known broadband device with frequency hopping, RF patent №2210187 from 08/10/2003, containing: a mixer, a band-pass filter, an amplitude detector, a decision unit, a controlled clock generator, a tunable frequency synthesizer (code generator).

The disadvantage of this analogue is the low noise immunity when exposed to simulation interference.

The closest in technical essence to the claimed device is a broadband transceiver with increased noise immunity, RF patent No. 2296420 of 03/27/2007. This device is selected as a prototype.

The known prototype device contains on the transmitting side an encoder, a first phase manipulator, a second phase manipulator, a first high-frequency key, a second high-frequency key, an “NOT” element, an adder, a mixer, a frequency synthesizer, a controlled key, a pseudo-random sequence generator, a key control generator.

The encoder input is the information input of the device. The encoder output is connected in parallel to the first phase manipulator and the second phase manipulator, and their outputs are connected to the first and second inputs of the adder through the first and second high-frequency keys, respectively. The input of the first channel is connected to the second input of the first high-frequency key and through the element "NOT" to the second input of the second high-frequency key, the output of the adder is connected to the first input of the mixer, the second input of which is connected to the output of the frequency synthesizer, the input of which is connected through the controlled key to the output of the generator pseudo-random sequence. The second (control) input of the controlled key is connected to the output of the key control generator, the input of which is connected to the receiving part, and the mixer output is connected to the transmitting antenna.

In the receiving part, the device contains a mixer, an intermediate frequency amplifier, a demodulator, first and second phase detectors, first and second keys, an “NOT” element, an “OR” element, a decoder, a speed change instruction decoder, a channel quality analyzer, a receipt decoder, a generation unit messages, memory block, delay line, synchronization block, pseudo-random sequence generator, key control generator, controlled key, frequency synthesizer.

The receiving antenna is connected to the first input of the mixer, the output of the latter is connected to the input of the intermediate frequency amplifier, the output of which is connected to the input of the demodulator. The first output of the demodulator is simultaneously connected to the inputs of the element "NOT" of the decoder and the synchronization unit. The second and third outputs of the demodulator are connected respectively to the inputs of the first and second phase detectors, the outputs of which are connected to the first and second inputs of the OR element, through the first and second keys, respectively. The second input of the second key is connected to the output of the element "NOT". The output of the OR element is the information output of the second channel.

The output of the decoder is connected simultaneously to the inputs of the decoder of the speed change command, the channel quality analyzer and the receipt decoder. The output of the decoder of the speed change command is connected to the first input of the message generating unit and to the input of the delay line, the output of which is connected to the input of the transmitter control key generator.

The output of the channel quality analyzer is connected to the second input of the message generating unit and the first input of the memory block, the second input of which is connected to the output of the receipt decoder, and the output is connected to the input of the key control generator, the output of the latter is connected to the control input of the controlled key, the frequency input of which is through the pseudorandom generator sequence and synchronization unit is connected to the first output of the demodulator, and the output through the frequency synthesizer is connected to the second input of the mixer. The output of the message generating unit is connected to the input of the first channel of the transmitting part.

The prototype device allows the transmission and reception of messages in conditions of interference with a given quality in the conditions of intentional response interference. The disadvantage of the prototype is the relatively low noise immunity to the effects of imitation interference.

The aim of the invention is the development of a broadband transceiver device that provides increased noise immunity of the generated radio signal under the influence of simulation noise due to pseudo-random changes in the phase of the signal.

To achieve the specified technical result in the known broadband transceiver device, consisting of a transmitting part, a receiving part and containing on the transmitting side an encoder (1), the input of which is the information input of the device, and the output is connected to a phase manipulator (2). The output of the phase manipulator (2) is connected to the first input of the high-frequency switch (3), and the output of the transmitting part of the device is the output of the frequency mixer (5), the second input of which is connected to the output of the frequency synthesizer (9).

The input of the frequency synthesizer (9) is connected to the output of the high-frequency key (8), the first input of which is connected to the output of the pseudo-random sequence generator (7), and the second input is connected to the key control generator (10), the output of the frequency mixer (5) is connected to the transmitting antenna .

In the receiving part, the receiving antenna is connected to the first input of the mixer (23), the output of the intermediate frequency amplifier (25) is connected to the input of the demodulator (26), the output of which is connected to the inputs of the synchronization unit (17) and the decoder (27), and the output of the decoder (27) ) is the output of the receiving part of the device and is connected to the inputs of the speed change decoder (12), channel quality analyzer (13), receipt decoder (16).

The output of the receipt decoder (16) is connected to the second input of the memory unit (14), the first input of which is connected to the output of the channel quality analyzer (13) and the first input of the message generating unit (11), the second input of which is connected to the decoder output of the speed change command (12 ) and to the input of the delay line (15). Moreover, the output of the message generating unit (11) is connected to the second input of the high-frequency key (3) of the transmitting part, the output of the delay line (15) is connected to the input of the control generator by the key (10) of the transmitting part, and the output of the memory unit (14) is connected to the input of the control generator key (19), the output of which is connected to the second input of the high-frequency key (20).

The first input of the high-frequency key (20) through the pseudo-random sequence generator (18) is connected to the output of the synchronization unit (17), and the output of the high-frequency key (20) is connected to the input of the frequency synthesizer (21), the output of which is connected to the second input of the frequency mixer (23) . In addition, a phase shift control unit (BUFS) (4) is introduced into the transmitting part of the device, the information input of which is connected to the output of the high-frequency key (3), and the control inputs are connected to the corresponding outputs of the decoder (6). The input of the decoder (6) is connected to the output of the pseudo-random sequence generator (7), the output of the BUFS (4) is connected to the first input of the frequency mixer (5).

A BUFS (24) is additionally introduced into the receiving part of the device, the information input of which is connected to the output of the mixer (23), and the control inputs are connected to the corresponding outputs of the decoder (22), the input of which is connected to the output of the pseudo-random sequence generator (18), and the output of the BUFS ( 24) is connected to the input of the intermediate frequency amplifier (25).

BUFS (4 (24)) consists of managed keys (4.1 (24.1)) - (4.N (24.N)), phase shifters (4, m (24.m)) - (4.M (24.M) ), and the first input of the managed key (4.1 (24.1)) and the inputs of the phase shifters (4.m (24.m)) - (4.M (24.M)) are combined and are the information input of the BFS (4 (24)), and the outputs of the phase shifters (4.m (24.m)) - (4.M (24.M)) are connected to the first inputs of the controlled keys (4.2 (24.2)) - (4.N (24.N)), respectively. The second inputs of the managed keys (4.1 (24.1)) - (4.N (24.N)) are the control inputs of the BFS (4 (24)), the outputs of the controlled keys (4.1 (24.1)) - (4.N (24.N )) are combined and are the output of the BUFS (4 (24)). The values of N, m, M are selected based on the number of phase values of the generated signal. The value of N is numerically equal to the number of phase values of the generated signal, m = N + 1, M = 2N-1.

Thanks to the new set of essential features due to the conversion of the circuit and the introduction of new blocks of the receiving and transmitting parts of the device, it becomes possible to simulate the functioning of the radio line with FM-N signals when actually using a more noise-resistant radio signal of on-off FM-2 modulation. The inventive device is illustrated by drawings, which show:

FIG. 1 is a structural diagram of a broadband transceiver with software phase adjustment of the signal;

FIG. 2 is a diagram of a phase shift control unit.

The claimed device shown in figure 1, consists of a transmitting part and a receiving part and contains in the transmitting part an encoder (1), the input of which is the information input of the device, and the output is connected to a phase manipulator (2), the output of which is connected to the first input of the high-frequency key (3).

The output of the high-frequency key (3) is connected to the information input of the BUFS (4), the control inputs of which are connected to the corresponding outputs of the decoder (6), the input of which is connected to the output of the pseudo-random sequence generator (7). The output of the BUFS (4) is connected to the first input of the frequency mixer (5), the output of which is the output of the transmitting part of the device. A transmit antenna is connected to the output of the frequency mixer (5).

The input (2) of the frequency mixer (5) is connected to the output of the frequency synthesizer (9), the input of which is connected to the output of the high-frequency key (8), the first input of which is connected to the output of the pseudo-random sequence generator (7), and the second input is connected to the key control generator (10).

In the receiving part of the device, the receiving antenna is connected to the first input of the frequency mixer (23), the output of which is connected to the information input of the BUFS (24), the control inputs of which are connected to the corresponding outputs of the decoder (22). The input of the decoder (22) is connected to the output of the pseudo-random sequence generator (18).

The output of the BUFS (24) is connected to the input of the intermediate frequency amplifier (25), the output of which is connected to the input of the demodulator (26), the output of which is connected to the inputs of the synchronization block (17) and decoder (27). The output of the decoder (27) is the output of the receiving part of the device and is connected to the inputs of the speed change decoder (12), channel quality analyzer (13), receipt decoder (16).

The output of the receipt decoder (16) is connected to the second input of the memory unit (14), the first input of which is connected to the output of the channel quality analyzer (13) and the first input of the message generating unit (11), the second input of which is connected to the decoder output of the speed change command (12 ) and to the input of the delay line (15). Moreover, the output of the message forming unit (11) is connected to the second input of the high-frequency key (3) of the transmitting part of the device.

The output of the delay line (15) is connected to the input of the key control generator (10) of the transmitting part of the device, and the output of the memory block (14) is connected to the input of the key control generator (19), the output of which is connected to the second input (2) of the high-frequency key (20) . Moreover, the first input of the high-frequency key (20) through the pseudo-random sequence generator (18) is connected to the output of the synchronization unit (17), and the output of the high-frequency key (20) is connected to the input of the frequency synthesizer (21), the output of which is connected to the second input of the frequency mixer (23) )

BUFS (4 (24)) consists of managed keys (4.1 (24.1)) - (4.N (24.N), phase shifters (4.m (24.m)) - (4.M (24.M)) moreover, the first input of the managed key (4.1 (24.1)) and the inputs of the phase shifters (4.m (24.m)) - (4.M (24.M)) are combined and are the information input of the BFS (4 (24)), and the outputs of the phase shifters (4.m (24.m)) - (4.M (24.M)) are connected to the first inputs of the controlled keys (4.2 (24.2)) - (4.N (24.N)), respectively. managed keys (4.1 (24.1)) - (4.N (24.N)) are the control inputs of the BFS (4 (24)), the outputs of the controlled keys (4.1 (24.1)) - (4.N (24.N)) combined and are the output BUFS (4 (24)).

The encoder (1) is designed to convert the input information sequence of pulses into the output sequence with additional code redundancy, which allows the decoder (27), which serves to restore the original information sequence, to correct errors that appear due to interference in the frequency channel. Implementation options for the encoder (1) and decoder (27) are known and are given, for example, in [1], pp. 323-330, Fig. 8.16.

The phase manipulator (2) is designed to form a phase-shifted signal (FM-2). The phase manipulator (2) is known and can be implemented according to the scheme presented in [2], p. 119, Fig. 4.25.

High-frequency key (3), is designed to connect to the transmission path of the information sequence from the message generation unit (11). The implementation scheme of the high-frequency key (3) is known and described, for example, in [9], p. 372-401.

BUFS (4 (24)) consists of managed keys (4.1 (24.1)) - (4.N (24.N)), phase shifters (4.m (24.m)) - (4.M (24.M) ) and is intended to generate a random value of the shift of the current phase of the signal by an amount multiple of the phase shift of the FM-N signal.

Phase shifters (4.m (24.m)) - (4.M (24.M)) BUFS (4 (24)) are designed to shift the phase of the signal by a random multiple of 2π / N. Phase shifters (4.m (24.m)) - (4.M (24.M)) are known, their circuit implementation is presented, for example, in [7], pp. 35-42.

The implementation options for managed keys (4.1 (24.1)) - (4.N (24.N)) are known and presented, for example, in [11], p. 161-162.

As frequency mixers (5) and (23) can be used commercially available mixers used, for example, in radio stations of the complex R-168.

The decoder (6 (22)) is designed to provide a control signal generated on the basis of a random sequence of a pseudo-random sequence generator (7 (18)) to the corresponding control input of the BUFS (4 (24)). The structure of the decoders (6), (22) is known and can be implemented on the basis of the structural scheme [8], p. 19, Fig. 22, using K155ID4 microcircuits.

The pseudo-random sequence generators (7) and (18) are designed to form the sequences of equally probable frequency numbers in the range i = 1,2, ..., I on the transmitting (7) and receiving (18) sides of the radio line. As the PSP generators (7), (18) any PSP generator produced by industry can be used, for example, a PSP generator used in radio stations of the R-168 complex.

High-frequency keys (8) and (20) are intended for switching PSP generators (7) and (18) respectively to the input of frequency synthesizers (9) and (21), respectively, for transmitting a digital sequence, according to which frequency synthesizers (9) and ( 21) generate operating frequencies. The implementation schemes of high-frequency keys (8) and (20) are known and described in [9], p. 372-401.

Frequency synthesizers (9) and (21) are used to form the carrier wave according to the sequence of the pseudo-random sequence generator. An implementation option for frequency synthesizers (9) and (21) is known and presented, for example, in [6], p. 214, Fig. 7.7 (a).

Key control generators (10) and (19) are a pulse generator with an adjustable generation frequency and are used to generate pulses received at the input of high-frequency keys (8) and (20), respectively. The pulse generation frequency can be increased in case of channel rejection. As a key management generator (10), (19), any generator with a changing pulse frequency can be used, for example, described in the patent of the Russian Federation No. 2133076 dated July 10, 1999.

The message generation unit (11) is designed to generate a digital code indicating the change in the frequency switching speed when applying a pulse to the input (1) and to generate a digital code indicating the receipt when applying a pulse to the input (2). The block diagram of the message generation unit (11) is known and described in RF patent No. 2296420 of March 27, 2007.

The decoder of the speed change command (12) is designed to convert the digital code generated in the message generation unit (11) of the “B” correspondent receiving part into a signal for tuning the frequency of generating control pulses in the key control generator (10) of the transmitting part of the device. The decoder circuit (12) is described, for example, in [4], p. 47, Fig. 2.4.

Channel quality analyzer (13) is designed to control the quality of the working channel. The working channel is estimated in relation to the levels of the useful signal and interference. As the channel quality analyzer (13), we can take the channel analyzer used in the R-163-AR equipment [4].

The memory unit (14) is designed to generate, when pulses arrive at the inputs (1) and (2), a control pulse supplied to the input of the key control generator (19). The structural diagram of the memory unit (14) is known and described in the patent of the Russian Federation No. 2296420 dated 03/27/2007.

The delay line (15) is designed to delay the signal to change the speed of the frequency adjustment during the transmission of the message to the correspondent. As the delay line (15), industry-issued delay lines with the required delay time can be used. Schemes of delay lines are presented in [10], p. twenty.

The receipt decoder (16) is designed to decrypt a digital code, which means that the correspondent received a command to change the frequency tuning speed. As the decoder of the receipt (16), you can use a decoder similar to the decoder of the command changes the speed (12).

The synchronization unit (17) serves to form a clock pulse sequence with a period of repetition T / 2, where T is the duration of the radio line at one frequency. An embodiment of the synchronization block (17) is known and described, for example, in [1], p. 193, Fig. 5-19.

The intermediate frequency amplifier (25) is designed to amplify the received radio signal at the intermediate frequency to the value necessary for the operation of subsequent blocks of the receiving path. An embodiment of an intermediate frequency amplifier (25) is known and described, for example, in [5], p. 100, Fig. 3-3.

Demodulator (26) can be implemented according to well-known schemes presented, for example, in [3].

The device of FIG. 1 operates as follows. Discrete signals are fed to the input of the encoder (1), converted to an informational sequence of pulses with additional code redundancy, and output from the encoder (1) to the input of the phase manipulator (2), at the output of which the FM-2 signal is generated.

The generated FM-2 signal through a high-frequency key (3) is fed to the information input of the BUFS (4). In BUFS (4), a random shift of the instantaneous phase of the FM-2 signal is performed by a multiple of 2π / N. To do this, at one of the control inputs of the BUFS (4), the voltage of the logical unit is generated, which, through the corresponding managed key (4.1) - (4.N), the BUFS (4) connects one of the branches of the BUFS. The logical unit signal is generated by the decoder (6) by converting the pseudo-random sequence code coming from the output of the pseudo-random sequence generator (7).

с выхода частотного синтезатора (9), управляемого с помощью генератора псевдослучайной последовательности (7). Код псевдослучайной последовательности переключается на частотный синтезатор (9) через ключ (8). При этом частотный синтезатор (9) формирует опорное колебание рабочей частоты передачи

по псевдослучайной программе из совокупности I частот, выделенных для связи, со скоростью перестройки, которая может быть изменена по команде приемной части. Изменение скорости перестройки частотного синтезатора осуществляется с помощью высокочастотного ключа (8), первый вход которого подключен к выходу генератора псевдослучайной последовательности (7), второй вход подключен к выходу генератора управления ключом (10), а выход подключен к входу частотного синтезатора (9).From the output of the BUFS (4), the generated signal simulating the FM-N signal is fed to the first input of the frequency mixer (5), to the second input of which the reference oscillation of the operating frequency, tunable according to the pseudo-random program, is supplied

from the output of the frequency synthesizer (9) controlled by a pseudo-random sequence generator (7). The pseudo-random sequence code is switched to the frequency synthesizer (9) through the key (8). In this case, the frequency synthesizer (9) generates a reference oscillation of the working frequency of the transmission

according to a pseudo-random program from the set of I frequencies allocated for communication, with the tuning speed, which can be changed by the command of the receiving part. The tuning speed of the frequency synthesizer is changed using a high-frequency key (8), the first input of which is connected to the output of the pseudo-random sequence generator (7), the second input is connected to the output of the key control generator (10), and the output is connected to the input of the frequency synthesizer (9).

, i=1, 2, …, I, который излучается передающей антенной в сторону корреспондента.Thus, at the output of the frequency mixer (5), a broadband signal is generated in the frequency hopping mode with a shift of the instantaneous phase of the signal by a random value that is a multiple of 2π / N, with each change in the operating frequency

, i = 1, 2, ..., I, which is emitted by the transmitting antenna towards the correspondent.

The received broadband signal with a random phase change comes from the antenna output to the first input of the frequency mixer (23), to the second input of which the reference oscillation, tunable by a pseudo-random program, from the output of the frequency synthesizer (21) is supplied.

As a result of the conversion in the frequency mixer (23) of the received and reference signals, an FM-N intermediate frequency signal is generated at its output, which is fed to the information input (1) of the BFS (24), in which, using commands from the decoder (22) to control inputs, compensation is made made on the transmitting part of the random value of the instantaneous phase of the signal.

The operation algorithm of the BFS (24) is similar to the algorithm of the functioning of the BFS (4). From the output of the BUFS (24), the FM-2 signal is fed to the input of an intermediate frequency amplifier (25) and fed to the input of the demodulator (26). A discrete signal is generated at the output of the demodulator (26), which is fed to the input of the decoder (27) and simultaneously to the input of the synchronization block (17), which ensures the formation of the next number of the operating frequency of the pseudorandom sequence generator (18) and synchronous tuning of the frequency synthesizer (21), and from the output of the decoder (27) - to the recipient of the message and simultaneously to the inputs of the channel quality analyzer (13), the receipt decoder (16) and the speed change command decoder (12).

The decoder of the speed change command (12) converts the received digital code of the correspondent receiving part generated in the message generation block (11) into a signal for tuning the control pulse generation frequency, which is transmitted through the delay line (15) to the input of the key control generator (10) of the transmitting part of the device .

When the channel is rejected, the output of the channel quality analyzer (13) is supplied with a signal of a logical unit at the same time at the input (1) of the memory unit (14) and at the input (1) of the message generation unit (11). The memory block (14), when pulses from the blocks (13) and (16) arrive at its inputs (1) and (2), generates a control pulse supplied to the key control generator (19), which controls the high-frequency key (20). The message generation unit (11), when applying a pulse to the input (1), generates the necessary digital code to change the switching frequency of the working frequency, and when applying a pulse to the input (2), a digital code indicating the receipt, which is switched using the high-frequency key (3) with a transmission path.

To evaluate the noise immunity properties of a broadband radio signal implemented using the developed device in the MatLAB environment, an experiment was conducted to simulate the transmission of information in digital radio communication lines of an information bit sequence of 10 ⁶ bits. During the experiment, it was assumed that N = 16, and the radio link counteraction system identifies its functioning mode as frequency hopping with multiphase manipulation. A gain in noise immunity of 2 dB was obtained, which confirms the achievement of the objective of the invention.

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Claims (2)

1. Broadband transceiver with software phase adjustment of the signal, consisting of a transmitting part, a receiving part and containing on the transmitting side an encoder (1), the input of which is the information input of the device, and the output is connected to a phase manipulator (2), the output of which is connected to the first the input of the high-frequency key (3), and the output of the transmitting part of the device is the output of the frequency mixer (5), the second input of which is connected to the output of the frequency synthesizer (9), the input of the frequency synthesizer (9) is connected to the output of the high-frequency key (8), to the first input of which the output of the pseudo-random sequence generator (7) is connected, and the second input is connected to the key control generator (10), the output of the frequency mixer (5) is connected to the transmitting antenna, in the receiving part, the receiving antenna is connected to the first input of the mixer (23), the output of the intermediate frequency amplifier (25) is connected to the input of the demodulator (26), the output of which is connected to the inputs of the synchronization unit (17) and the decoder (27), and the output of the decoder (27) is the output of the receiving part of the device and connected the inputs of the speed change decoder (12), channel quality analyzer (13), receipt decoder (16), the output of which is connected to the second input of the memory unit (14), the first input of which is connected to the output of the channel quality analyzer (13) and the first input of the forming unit message (11), the second input of which is connected to the output of the decoder of the speed change command (12) and to the input of the delay line (15), and the output of the message generating unit (11) is connected to the second input of the high-frequency key (3) of the transmitting part, the output of the delay line (15) connected to the generator control key (10) of the transmitting part, and the output of the memory unit (14) is connected to the input of the key control generator (19), the output of which is connected to the second input of the high-frequency key (20), and the first input of the high-frequency key (20) through the pseudo-random generator sequence (18) is connected to the output of the synchronization unit (17), and the output of the high-frequency key (20) is connected to the input of the frequency synthesizer (21), the output of which is connected to the second input of the frequency mixer (23), characterized in that the additional part of the device The phase shift control unit (CFS) (4) has been introduced, the information input of which is connected to the output of the high-frequency key (3), and the control inputs are connected to the corresponding outputs of the decoder (6), the input of which is connected to the output of the pseudo-random sequence generator (7), output BUFS (4) is connected to the first input of the frequency mixer (5), BUFS (24) is additionally introduced into the receiving part of the device, the information input of which is connected to the output of the mixer (23), and the control inputs are connected to the corresponding outputs of the decoder an amplifier (22), the input of which is connected to the output of the pseudo-random sequence generator (18), and the output of the BUFS (24) is connected to the input of the intermediate frequency amplifier (25). 2. The device according to claim 1, characterized in that the BFS (4 (24)) consists of controlled keys (4.1 (24.1)) - (4.N (24.N)), phase shifters (4.m (24.m )) - (4.M (24.M)), and the first input of the managed key (4.1 (24.1)) and the inputs of the phase shifters (4.m (24.m)) - (4.M (24.M)) are combined and are the information input of the BFS (4 (24)), and the outputs of the phase shifters (4.m (24.m)) - (4.М (24.М)) are connected to the first inputs of the controlled keys (4.2 (24.2)) - ( 4.N (24.N)), respectively, the second inputs of the managed keys (4.1 (24.1)) - (4.N (24.N)) are the control inputs of the BFS (4 (24)), the outputs of the controlled keys (4.1 (24.1) )) - (4.N (24.N)) are combined and you are BUFS (4 (24)).

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