RU2631464C1 - Broadband transceiver with software operating frequency tuning - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: broadband transceiver with software operating frequency tuning consists on the transmitting part of an encoder (1), phase manipulators (2) and (3), the first (4) and the second (5) high-frequency keys, a HE (6) element, an adder (7), a mixer (8), a synthesizer (9), a controlled key (10), a pseudo-random sequence generator (11), a key generator (12), on the receiving part of a mixer (13), an intermediate frequency amplifier (14), a demodulator (15), phase detectors (16) and (17), a key (18), a NOT element (19), a key (20), a OR element (21), a decoder (22), a speed change decoder (23), a channel quality analyzer (24), a receipt decoder (25), a message forming unit (26), a memory unit (27), a delay line (28), a synchronization unit (29), a pseudo-random sequence generator (30), a key controlling generator (31) managed by the key (32), a frequency synthesizer (33), as well as on the transmit side there is a meter (34), a decoder (35), an attenuator (36), a power amplifier (37) a driven key (38), a delay line (39), a mixer (40), a synthesizer (41), in the receiving part there is a mixer (46), an intermediate frequency amplifier (47), a demodulator (48), an adder (42), a delay line (43), a controlled switch (44), a frequency synthesizer (45), a mixer (46).

EFFECT: development of a broadband interference-resistant transceiver for operation under various signal and interference conditions.

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Description

The claimed device relates to the field of radio communications, in particular to broadband transceiver devices with software (pseudo-random) tuning of the operating frequency (MHF), and can find application in radio channels with fading when transmitting discrete messages.

Known broadband transceiver devices that transmit messages in the frequency hopping mode according to the patent of the Russian Federation No. 2185029. This device contains on the transmitting side: an encoder, a synchronization unit, a pseudo-random sequence generator (GPS), a control unit, a frequency synthesizer, a modulator, a power amplifier, a transmitting antenna, a pseudo-random sequence converter, and on the receiving side: a receiving antenna, an input amplifier, a mixer local oscillator, detector, AGC block, solver, decoder, synchronization block, GPS, control unit, pseudo-random sequence converter.

The disadvantage of this analogue is the low bandwidth due to the single-channel mode of operation.

Known broadband device with frequency hopping according to the patent of the Russian Federation No. 2210187, comprising: a mixer, a bandpass filter, an amplitude detector, a decision unit, a controlled clock, a tunable frequency synthesizer (code generator).

The disadvantages of this analogue are low bandwidth, low noise immunity to response interference (interference after), low noise immunity in channels with fading.

The closest in technical essence to the claimed device is a broadband transceiver device according to the patent of the Russian Federation No. 2296420 dated 03/27/07, operating in the frequency hopping mode with the control of the speed of the software adjustment depending on the quality of communication. This device is selected as a prototype. The claimed broadband transceiver 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 pseudo-random generator 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 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 forming 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.

This radio allows you to send and receive messages in the conditions of interference with a given quality in the conditions of deliberate response interference.

The disadvantage of the prototype is the relatively low noise immunity, which is caused by a decrease in bit energy with an increase in the tuning speed, a decrease in the quality of radio communications when working in channels with fading.

The aim of the invention is to develop a broadband transceiver device that provides increased noise immunity of the radio to intentional response interference by changing the frequency tuning frequency and controlling the frequency and energy resources of the radio line depending on the signal and interference conditions.

This goal is achieved by the fact that in the known broadband transceiver device, consisting of a transmitting part, a receiving part and containing an encoder (1) on the transmitting side, the input of which is the information input of the second channel of the device, and the output is connected to the inputs of the first (2) and second ( 3) phase manipulators, the outputs of which are connected to the first inputs of the first (4) and second (5) high-frequency keys, the outputs of which are connected respectively to the first and second inputs of the adder (7), the input of the first channel The device is connected to the second input of the first high-frequency key (4) and the input of the element NOT (6), the output of which is connected to the second input of the high-frequency key (5), the output of the adder (7) is connected to the first input of the mixer (8), the second input of which is connected to the output of the frequency synthesizer (9), the input of which is connected to the output of the controlled key (10), the first and second inputs of which are connected respectively to the outputs of the pseudo-random sequence generator (11) and the key control generator (12), the input of which is connected to the receiving part, in the receiving of the second part, the receiving antenna is connected to the first input of the mixer (13), the output of which is connected to the input of the intermediate frequency amplifier (14), the output of which is connected to the input of the demodulator (15), the second and third outputs of the demodulator (15) are connected respectively to the inputs of the first (17) ) and the second (16) phase detectors, the outputs of which are connected to the first inputs of the corresponding first (18) and second (20) keys, the outputs of which are connected respectively to the first and second inputs of the OR element (21), and the second input of the second key (20) connected to the output element NOT (19), the output of the OR element (21) is the information output of the second channel of the device, the output of the decoder (22) is the output of the first channel of the device and is connected to the inputs of the decoder of the speed change command (23), the channel quality analyzer (24) and the receipt decoder ( 25), the output of the speed change command decoder (23) is connected to the first input of the message generating unit (26) and to the input of the delay line (28), the output of which is connected to the input of the key control generator (12) of the transmitting part, the output of the channel quality analyzer (24) ) connected to the input of the message generation unit (26) and the first input of the memory unit (27), the second input of which is connected to the output of the receipt decoder (25), and the output is connected to the input of the key control generator (31), the output of the key control generator (31) is connected to the control input of the controlled key (32), the frequency input of which is connected to the first output of the demodulator (15) through the pseudo-random sequence generator (30) and the synchronization unit (29), and the output through the frequency synthesizer (33) is connected to the second input of the mixer (13), block output The message (26) is connected to the input of the first channel of the transmitting part of the device, a counter (34) is additionally introduced into the transmitting part of the device, the input of the counter (34) is connected to the input of the key control generator (12), and the output is connected to the input of the decoder (35), outputs 2 ... n-1 of which are 2 ... n-1 inputs of the attenuator (36), and the nth output is connected to the first input of the controlled key (38), the second input of which is connected to the output of the mixer (40).

The output of the controlled key (38) is connected to the input (1) of the attenuator (36), the output of the attenuator (36) is connected to the input of the power amplifier (37), the output of which is connected to the transmitting antenna, the first input of the mixer (40) is connected to the output of the synthesizer (41) ), and the second to the output of the adder (7). The input of the synthesizer (41) through the delay line (39) is connected to the output of the PSP generator (11).

A mixer (46) is additionally introduced into the receiving part of the device, the first input of which is connected to the receiving antenna, and the mixer output (46) is connected to the input of the intermediate frequency amplifier (47), the output of which is connected to the input of the demodulator (48), the output of the demodulator (48) connected to the first input of the adder (42), to the second input of which the output of the demodulator (15) is connected.

The output of the adder (42) is connected to the input of the synchronization unit (29), the second input of the first key (18), the input of the element NOT (19) and the input of the decoder (22), the output of the pseudo-random sequence generator (30) through the delay line (43) is connected to the first input of the controlled key (44), the second input of which is connected to the output of the key control generator (31), and the output is connected to the input of the frequency synthesizer (45), the output of which is connected to the second input of the mixer (46).

Thanks to the new set of essential features, due to the introduction of additional blocks into the transmitting and receiving parts, it becomes possible to increase the energy parameters of the generated signal with an increase in the speed of program tuning, which increases the ratio of the signal level over the noise level and, therefore, increases the noise immunity of radio communications. In addition, with an increase in the speed of program tuning, a serial-parallel signal structure is additionally formed, which allows receiving a signal in radio channels with fading.

The inventive device is illustrated by drawings, which show:

FIG. 1 is a structural diagram of a broadband transceiver device with software tuning of the operating frequency;

FIG. 2 is a block diagram of an attenuator.

The device of FIG. 1 operates as follows. The discrete signals of the second channel are fed to the input of the encoder (1), converted into an information sequence of pulses with additional code redundancy, and simultaneously output from the output of the encoder (1) to the information inputs of the first (2) and second (3) phase manipulators, at the output of which two OFM signal, characterized by carrier frequencies F ₁ and F ₂ shifted relative to each other in frequency by the value _Δ F = F ₂ -F ₁ . The signals of the OFM of the second channel with carriers F ₁ and F ₂ are used as the frequencies of "pressing" (F ₁ ) and "release" (F ₂ ) when transmitting a message on the first channel. Thus, on the second channel, messages are transmitted using OFM signals.

Discrete signals of the first channel are simultaneously fed to the second control input of the first high-frequency key (4) and through the “NOT” element (6) to the second control input of the second high-frequency key (5), and the first channel inputs receive the OFM signals of the second channel from the outputs of the first (2) and second (3) phase manipulators, respectively. Moreover, a discrete signal of the first channel carries out the closure (opening) of one of the two high-frequency keys (4) or (5). This will ensure the appearance at one of the inputs and outputs of the adder (7) one of two OFM signals with a carrier frequency of F ₁ or F ₂ . Thus, on the first channel, the message is transmitted using OFM / FSK signals.

This signal from OFM / FMN is fed to the first input of the mixer (8). The reference oscillation of the operating frequency ƒ _pi from the output of the frequency synthesizer (9) controlled by GPSS (11) is fed to the second input of the mixer (8), which is tuned according to a pseudo-random program. In this case, the frequency synthesizer (9) generates a reference oscillation of the working transmission frequency ƒ _pi , according to a pseudo-random program from a set of n 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 controlled key (10), the first (frequency) input of which is connected to the GPS output (11), the second (control) input is connected to the output of the key control generator (12), and the output is connected to the frequency synthesizer input (9).

Changing the switching speed is as follows: GPSP (11) generates a digital code with a frequency w _max , which is fed to the input of a controlled key (10), commuting the output of GPSP (11) with the input of the frequency synthesizer (9). The switching of the GPS output (11) with the input of the frequency synthesizer (9) occurs after the pulse arrives from the output of the key control generator (12) to the second (control) input of the controlled key. The digital code is fed to the input of the frequency synthesizer (9), which generates a frequency corresponding to this code. The formation of this frequency occurs before the next digital code arrives, which will be fed to the input of the frequency synthesizer (9) at the next switching of the GPS output (11) with the input of the frequency synthesizer (9). Thus, the time of formation by the frequency synthesizer of one frequency will vary from the frequency of the supply of control pulses to the second input of the controlled key.

Thus, at the output of the mixer (8), a signal is formed with OFM / FMN at the ith working frequency ƒ _pi , i = 1 ... n, which is emitted by the antenna towards the correspondent. The received OFM / FMN signal - frequency hopping at frequency ƒ _{pi is} fed to the first signal input of the mixer (13), the second input of which is supplied with a pseudo-random program tunable reference oscillation ƒ _i from the output of the frequency synthesizer (33).

As a result of the conversion of the received and reference signals in the mixer (13), OFM / FSK intermediate frequency signals are generated at its output, which are amplified in the IF (14) and fed to the input of the demodulator (15). At the first output of the demodulator (15), a discrete signal of the first channel is generated, along which control commands are transmitted along with information signals. This signal through the adder (42) is fed to the input of the decoder (22) and simultaneously to the synchronization unit (29), which ensures the formation of the next number of the working frequency of the GPS (30) and synchronous tuning of the frequency synthesizer (33), and from the output of the decoder (22) - to the message recipient and simultaneously to the inputs of the channel quality analyzer (24), the receipt decoder (25) and the decoder of the speed change command (23). When the channel is rejected, the output of the channel quality analyzer (24) is supplied with a logical unit signal simultaneously to the first input of the memory unit (27) and to the second input of the message generation unit (26), at the output of which a receipt is generated for changing the speed of program tuning.

Management of the frequency and energy resources of the radio signal generated by changing the frequency hopping frequency is as follows. At the information input of the attenuator (36), a signal is received from the output of the mixer (8), this signal is parallelized to the number of branches of the attenuator (36), corresponding to the number of gradations of the speed control and, accordingly, the number of power adjustments. In each branch of the attenuator (36), the signal enters the input of the “And” element, the second input of which receives a control signal from the output of the decoder (35).

The logical unit can only be on one output of the decoder, and, therefore, the signal from the output of the mixer (8) will pass through only one branch of the attenuator (36). From the output of the element "And" the signal enters the input of the amplifier through the resistance of the branch (see Fig. 2).

When changing the speed of software tuning from the output of the decoder (35), a command is received to connect the output of the managed key (38) to the first input of the attenuator (36). Moreover, the connection frequency is proportional to the speed of software tuning. At the other input of the controlled key (38), a high-frequency signal in the frequency hopping mode is generated by blocks (7), (11), (39) - (41). The functioning of blocks (39) - (41) is similar to the operation of blocks (8) - (12), with the exception of the additional inclusion of a delay line (39) in order to generate a mismatched memory bandwidth code.

Thus, the output of the inventive device provides the formation of a series-parallel signal structure with frequency hopping. This signal design provides increased noise immunity of the reception of the signal element in the channels with fading due to the formation of a series-parallel signal structure.

On the receiving side, the processing of the generated signal structure with frequency hopping occurs as follows. When transmitting a parallel signal with frequency hopping in addition to the main signal processing circuit generated by blocks (13) - (15), (29) - (33), the signal processing circuit formed by blocks (43) - (48), which are combined through the block, is connected (42).

The functioning of blocks (43) - (48) is similar to the operation of blocks (13) - (15), (29) - (33), with the exception of the introduction of a delay line (43) to generate a PSP code similar to the code on the transmitting side. Addition of the processed signals during parallel transmission at two frequencies is carried out in the adder (42) in front of the demodulator input.

The encoder (1) is used to convert the input information sequence of pulses to the output sequence with additional code redundancy, which allows the decoder (22), which serves to restore the original information sequence, to correct errors that appear due to interference in switched frequency channels. Implementation options for the encoder (1) and decoder (22) are known and are given, for example, in [5], pp. 323-330, Fig. 8.9, 8.11, 8.16.

In the claimed device, phase manipulators (2) and (3) are intended for the formation of two phase-modulated signals (OFM) shifted relative to each other in the carrier frequency. Phase manipulators (2) and (3) are known and, in particular, can be implemented according to the scheme of the relative phase modulator described in [6], p. 119 in Fig. 4.25.

High-frequency keys (4) and (5) are intended for alternately connecting one of the independent paths (outputs of the phase manipulators (2) and (3)) to the adder (7) according to the law of changing the information signal in the first channel.

The element "NOT" (6) is designed to invert the signal of the first information channel in order to provide antiphase control of keys (4) and (5), respectively.

Adders (7) and (42) are designed to combine the signals of two independent paths. It can be implemented in the simplest case on a conventional resistive adder and is described in the patent for invention No. 2157051 of 09/27/2000.

As the mixer (8), (13), (40), (46) any mixers manufactured by the industry can be used.

Demodulators (15) and (48) are designed to isolate the FSK signals of the first channel and to separate the OFM signals of the second channel into two independent paths. It can be implemented according to well-known schemes, in particular according to the scheme of a frequency detector with two detuned circuits. The implementation of the demodulator is known and described in [9].

The first and second phase detectors (17) and (16) are designed to detect phase-shifted signals corresponding to the first and second paths of the second channel. The implementation of phase detectors is known and described in [9].

The keys (18) and (20) are used to select the path for receiving demodulated signals from phase detectors (17) and (16) to the corresponding inputs of the OR element (21). They can be made on the basis of the transistor, in the key mode presented in [6] in Fig. 3.4.9, p. 93.

The element "NOT" (19) is designed to invert the signal of the first information channel in order to provide antiphase control of the keys (18) and (20), respectively, it is similar to the element "NOT" (6).

The OR element (21) is intended to form a single sequence of information symbols of the second channel.

Used in the claimed device elements and their circuits are described in the following sources of information:

- high-frequency keys (4) and (5) in [1] on page 376;

- elements NOT (6) and (19) in [1] on page 59;

- the OR element (21) in [1] on page 74.

The controlled keys (10), (32), (38) and (44) are intended for switching the GPS and frequency synthesizer for transmitting a digital sequence to the frequency synthesizer, according to which the frequency synthesizer generates a working frequency number. As a managed key, you can use the element "And" which is implemented in the chips of the KR 1533 series.

The decoders of the speed change command (23) are designed to convert the digital code generated in the message forming unit of the correspondent “B” receiving part into a signal for tuning the frequency of generating control pulses in the key generator of the transmitting part key. The decoder circuit (23) is described, for example, in [8], p. 47, Fig. 2.4.

The synchronization unit (29) serves to form a clock pulse sequence with a period of T / 2, where T is the duration of the radio line at one frequency. An embodiment of the synchronization block (29) is known and described, for example, in [1], p. 193, Fig. 5-19.

The pseudo-random sequence generators (GPSS) (11) and (30) are designed to form the sequences of equally probable frequency numbers in the range i = 1, ..., N on the transmitting (11) and receiving (30) sides of the radio line, and any GPSSP can be used as a GPSS produced by industry, for example, GPS, used in radio stations of the complex R-168.

Frequency synthesizers (9), (33), (41), (45) are used to form the carrier wave at each next pseudo-random tunable frequency. The implementation of the frequency synthesizer (9), (33), (41), (45) is known and presented, for example, in [7], p. 214, Fig. 7.7 (a).

The intermediate frequency amplifier (14) and (47) is designed to amplify the received radio signal at an intermediate frequency to the value necessary for the operation of subsequent blocks of the receiving path. An embodiment of an intermediate-frequency amplifier (14) and (47) is known and described, for example, in [1], p. 100, Fig. 3-3.

Channel quality analyzer (24) 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 analyzer of the working channel, we can take the channel analyzer used in the R-163-AR equipment [8].

The receipt decoder (25) is designed to decrypt a digital code, which means that the correspondent received a command to change the frequency tuning speed. As a decoder of the receipt, you can use a decoder similar to the decoder of the command changes the speed.

Delay lines (12), (39), (43) are designed to delay the signal by increasing the frequency tuning rate while the message is being sent to the correspondent. As a delay line, industry-issued delay lines with a desired delay time can be used.

The key management generator (12), (31) is a pulse generator with an adjustable generation frequency and is used to generate pulses arriving at the input of a controlled key. The pulse generation frequency can be increased in case of channel rejection. As a key management generator, you can use any generator with a changing pulse frequency.

The message generating unit (26) is designed to generate a digital code indicating an increase in the frequency switching speed when applying a pulse to the first input, and to generate a digital code indicating a receipt when applying a pulse to the second input. The block diagram of the message generation unit is known and described in RF patent No. 2296420.

The memory block (27) is designed to form a control pulse supplied to the input of the block (31), when pulses arrive at the first and second inputs. The structural diagram of the memory block is known and described in the patent of the Russian Federation No. 2296420.

The counter (34) is designed to read the number of pulses per unit time from the block (23) through the delay line (28). The block diagram of the counter (34) is known and is given in [11], p. 98, Fig. 5.16.

The decoder (35) is designed to provide a signal of a logical unit to the attenuator (36) depending on the number of pulses from the counter (34). The structural diagram of the decoder is known and is given in [11], p. 73, Fig. 4.12.

The attenuator (36) represents n parallel branches (see Fig. 2), where n is the number of power gradations corresponding to the number of gradations of the change in the tuning rate of the radio link with frequency hopping. Each attenuator branch contains an “I” element connected in series with resistance R. The resistance value is selected based on the condition R _n = kR _n-1 , where k = V _n-1 / V _n is the coefficient of gradation of the frequency hopping frequency, V is the frequency frequency hopping frequency.

The power amplifier (37) is designed to enhance the level of the generated signal. The block diagram of a power amplifier is given, for example, in [12], p. 96, Fig. 4.3.

Compared with the prototype, the proposed technical solution allows to increase the noise immunity of a broadband transceiver device with software tuning of the operating frequency under the influence of response interference when transmitting discrete messages. This is due to the fact that with an increase in the frequency hopping frequency in order to preserve the information speed of the transmitted message, the duration of one bit transmitted at one frequency decreases. Therefore, the energy per bit of the generated signal is reduced.

In this case, to increase the signal power in the control unit, a lower resistance of the branch R _{n is} connected, and R _n = kR _n-1 , where k = V _n-1 / V _{n is the} gradation coefficient of the frequency hopping frequency, V is the frequency hopping speed.

Thus, an increase in signal power is provided, and therefore, an increase in noise immunity of its reception. In addition, part of the signal elements is transmitted simultaneously at two frequencies. This ensures the implementation of dual reception in order to further increase the noise immunity of signal reception, allows signal processing in channels with fading.

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Claims (1)

A broadband transceiver with software tuning of the operating frequency, consisting of a transmitting part, a receiving part and containing an encoder (1) on the transmitting side, the input of which is the information input of the second channel of the device, and the output is connected to the inputs of the first (2) and second (3) phase manipulators, the outputs of which are connected to the first inputs of the first (4) and second (5) high-frequency keys, the outputs of which are connected respectively to the first and second inputs of the adder (7), the input of the first channel of devices and connected to the second input of the first high-frequency key (4) and the input of the element NOT (6), the output of which is connected to the second input of the high-frequency key (5), the output of the adder (7) is connected to the first input of the mixer (8), the second input of which is connected to the output of the frequency synthesizer (9), the input of which is connected to the output of the controlled key (10), the first and second inputs of which are connected respectively to the outputs of the pseudo-random sequence generator (11) and the key control generator (12), the input of which is connected to the receiving part, in the receiving parts the receiving antenna is connected to the first input of the mixer (13), the output of which is connected to the input of the intermediate frequency amplifier (14), the output of which is connected to the input of the demodulator (15), the second and third outputs of the demodulator (15) are connected respectively to the inputs of the first (17) and second (16) phase detectors, the outputs of which are connected to the first inputs of the first (18) and second (20) keys, respectively, the outputs of which are connected respectively to the first and second inputs of the OR element (21), the second input of the second key (20) connected to the output of the element is NOT (19), you the path of the OR element (21) is the information output of the second channel of the device, the output of the decoder (22) is the output of the first channel of the device and is connected to the inputs of the decoder of the speed change command (23), the channel quality analyzer (24) and the receipt decoder (25), the decoder output speed change commands (23) are connected to the first input of the message generating unit (26) and to the input of the delay line (28), the output of which is connected to the input of the transmitter control key generator (12), the output of the channel quality analyzer (24) is connected to the second input to the message generating unit (26) and the first input of the memory unit (27), the second input of which is connected to the output of the receipt decoder (25), and the output is connected to the input of the key control generator (31), the output of the key control generator (31) is connected to the control the input of the controlled key (32), the frequency input of which is connected to the first output of the demodulator (15) through the pseudo-random sequence generator (30) and the synchronization unit (29), and the output through the frequency synthesizer (33) is connected to the second input of the mixer (13), the output message forming unit (26) is connected to the input of the first channel of the transmitting part of the device, characterized in that a counter (34) is added to the transmitting part of the device, the input of which is connected to the input of the key control generator (12), and the output is connected to the input of the decoder (35), outputs 2 ... n-1 of which are 2 ... n-1 inputs of the attenuator (36), and the nth output is connected to the first input of the controlled key (38), the second input of which is connected to the output of the mixer (40), the output of the controlled key (38) ) is connected to the input (1) of the attenuator (36), the output of the attenuator (36) is connected to the input of the amplifier For power (37), the output of which is connected to the transmitting antenna, the first input of the mixer (40) is connected to the output of the synthesizer (41), and the second to the output of the adder (7), the input of the synthesizer (41) is connected to the output through the delay line (39) PSP generator (11), and a mixer (46) is added to the receiving part of the device, the first input of which is connected to the receiving antenna, and the output of the mixer (46) is connected to the input of the intermediate frequency amplifier (47), the output of which is connected to the input of the demodulator (48 ), the output of the demodulator (48) is connected to the first input of the adder (42), to W whose rum input is connected to the output of the demodulator (15), the output of the adder (42) is connected to the input of the synchronization block (29), the second input of the first key (18), the input of the element NOT (19) and the input of the decoder (22), the output of the pseudo-random sequence generator ( 30) is connected through a delay line (43) to the first input of the controlled key (44), the second input of which is connected to the output of the key control generator (31), and the output is connected to the input of the frequency synthesizer (45), the output of which is connected to the second input of the mixer ( 46).

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