RU2320084C1 - Data transmission system with multi-access and time division of channels - Google Patents

Abstract

FIELD: communications engineering.

SUBSTANCE: the system consists of transmitting sections of client stations and receiving section of central station, where each transmitting section of client station contains clock impulse generator, timer, information source, information signal generator, encoded signal generator, double frequency manipulation signal generator, modulator, transmitter, transmitting antenna, frequency synthesizer and generator of pseudo-random numbers, and receiving section of central station contains receiving antenna, demodulator, signal selector, block for selecting additional series, first and second two-channel synchronized filters, first and second subtracters, interference compensator, information receiver, frequency synthesizer, generator of pseudo-random numbers and generator of clock impulse.

EFFECT: due to new set of substantial signs, it becomes possible to expand area of application for claimed system, in particular, to increase interference resistance without expansion of frequency resource and reduction of system traffic capacity.

2 cl, 11 dwg, 1 tbl

Description

The invention relates to communication technology and can be used in systems for transmitting and collecting data with multiple access and time division of channels using the propagation of electromagnetic waves in communication channels with unstable signal parameters (phase, amplitude and polarization) of the meter and decameter wavelength ranges with pseudo-random tuning of the working frequency (MFC) when exposed to deliberate impulse noise in the form of a sequence of discrete pulses.

The well-known time-division multiple access system described in the book of Borisov V.A. "Radio engineering information transmission systems." (M .: Radio and communications, 1990, p. 227-232), contains, like the proposed transmission system with multiple access and time division of channels, transmitters of earth stations and a repeater similar to the proposed system. At the same time, in a known system, each correspondent transmits its information signal in a system operating time specially allocated for it.

The disadvantage of this time-division multiple access system is its low noise immunity due to deliberate interference when operating at fixed frequencies and the relatively low reliability in communication channels with unstable signal parameters (phase, amplitude and polarization) of the meter and decameter wavelengths, as well as inefficient use transmitter power, which limits the scope of this system.

Known multiple-access data transmission system with time division of correspondents according to the patent of the Russian Federation No. 2012143, IPC ⁷ Н04В 7/12, decl. 03/29/91, publ. 04/30/94, contains, like the proposed transmission system with multiple access and time division of channels N = 2 ^k (where k≥2 is an integer; j = 1, 2, ..., N is the number of the transmitting part of the subscriber station) transmitting parts of subscriber stations, each of which contains a source of information, a quad-coded sequence generator, a transmitter, a transmitting antenna, a clock, a clock, and a receiving part of a central station that contains a receiving antenna, a block for receiving four-coded radio signals, an inform receiver tion similar to the proposed system. Moreover, in the known system, four-coded sequences (D-codes, Welty codes) are used to transmit information that do not have side outliers in the aperiodic autocorrelation function.

The disadvantage of this multi-access data transmission system with time division of correspondents is the low noise immunity due to deliberate interference when operating at fixed frequencies and the relatively low reliability in radio channels with unstable signal parameters (phase, amplitude and polarization) of the meter and decameter wavelengths, which limits scope of this system.

The closest in technical essence and the functions performed to the claimed data transmission system with multiple access and time division of channels analog (prototype) is a data transmission system with multiple access and time division of channels, see RF patent No. 2240653, IPC ⁷ Н04В 7/12, declared 04/21/03, publ. 11/20/04. The known transmission system with multiple access and time division of channels contains, like the proposed transmission system with multiple access and time division of channels N = 2 ^k transmitting parts of subscriber stations, each of which contains a clock generator, a clock, an information source, an information signal conditioner, coded signal conditioner, double frequency shift signal conditioner, modulator, transmitter, transmitting antenna, frequency synthesizer, pseudo-oscillator aynyh numbers, and the receiving part of the central station, which comprises a receiving antenna, a demodulator, signal selector unit for additional sequences, dual channel matched filter, a subtractor, a data receiver, a frequency synthesizer, the generator of pseudorandom numbers and the clock pulse generator similar to the proposed system.

Moreover, in the known data transmission system with multiple access and time division of channels, as in the proposed data transmission system with multiple access and time division of channels, in each transmitting part of the subscriber station, an information source, an information signal shaper, an encoded signal shaper, a shaper are connected in series signals of double frequency manipulation, modulator, transmitter and transmitting antenna. The output of the clock generator is jointly connected to the clock inputs of the chronizer, information signal shaper, coded signal shaper, double frequency shift signal shaper, pseudo random number generator and frequency synthesizer. The output of the chronizer is connected to the control input of the driver of the information signal and the clock input of the information source. Moreover, n control outputs of the pseudo-random number generator, where n≥2, are connected to the corresponding n control inputs of the frequency synthesizer, the output of which is connected to the modulating input of the modulator. The receiving part of the central station, like the proposed data transmission system with multiple access and time division of channels, contains a receiving antenna, the output of which is connected to the information input of the demodulator. The output of the demodulator is connected to the input of the signal selector, the first, second, third and fourth information outputs of which are connected respectively to the first, second, third and fourth information inputs of the block for selecting additional sequences. The first and second information outputs of the additional sequences extraction unit are connected respectively to the first and second information inputs of a two-channel matched filter, the first and second information outputs of which are connected respectively to the first and second information inputs of the subtractor. The output of the subtractor is connected to the input of the information receiver. The output of the clock generator is connected to the clock inputs of the frequency synthesizer and the pseudo random number generator. Moreover, the n control outputs of the pseudo random number generator are connected to the corresponding n control inputs of the frequency synthesizer, the output of which is connected to the modulating input of the demodulator. In addition, the known system - the prototype also contains a two-channel matched filter and subtractor.

Data access system with multiple access and time division of channels - the prototype uses four-coded sequences (E-codes, Velty codes) with double frequency shift keying and frequency hopping for transmitting an information signal, where the odd elements of the four-coded sequence are transmitted at frequencies f ₃ + f _hopping or f ₄ + f _{frequency hopping,} and even elements quaternary-coded sequence transmitted on frequencies f ₁ + f ₂ f _{frequency hopping} or _{frequency hopping} + f, i.e. nominal frequency determines the number of additional sequence spine in the quaternary-coded signal.

The disadvantage of this data transmission system with multiple access and time division of channels is low noise immunity when exposed to deliberate impulse noise in the form of a sequence of discrete pulses, which limits the scope of this system. This is due to the fact that during the convolution of the total value of the four-coded radio signal and interference, the impulse noise is not fully decorrelated.

The objective of the invention is to develop a data transmission system with multiple access and time division of channels, ensuring the achievement of a technical result, which consists in expanding the scope by isolating and compensating for intentional impulse noise, provided the use of quad-coded orthogonal in the code structure sequences with frequency hopping, increased noise immunity and reliability in communication channels with unstable signal parameters (phase, amplitude and polarization) meters nth and decameter wave ranges without extending the frequency resource and reducing system capacity, and is intended for data transmission systems with code compression of signals and data transmission systems with multiple access and time division of channels.

A multiple-access, time-division multiple-channel data transmission system contains N = 2 ^k transmitting parts of subscriber stations, each of which contains a clock pulse generator, a clock, an information source, an information signal shaper, a coded signal shaper, a two-frequency frequency shift signal shaper, a modulator, a transmitter , a transmitting antenna, a frequency synthesizer, a pseudo-random number generator, and a receiving part of a central station that contains a receiving antenna, a demodulator , a signal selector, an additional sequence extraction unit, an information receiver, a frequency synthesizer, a pseudo-random number generator, and a clock generator. At the same time, in each transmitting part of the subscriber station, an information source, an information signal shaper, a coded signal shaper, a double frequency shift signal shaper, a modulator, a transmitter and a transmitting antenna are connected in series. The output of the clock generator is jointly connected to the clock inputs of the chronizer, information signal shaper, coded signal shaper, double frequency shift signal shaper, pseudo random number generator and frequency synthesizer. The output of the chronizer is jointly connected to the control inputs of the driver of the information signal and the information source. Moreover, n control outputs of the pseudo-random number generator, where n≥2, are connected to the corresponding n control inputs of the frequency synthesizer, the output of which is connected to the modulating input of the modulator. In the receiving part of the central station, the output of the receiving antenna is connected to the information input of the demodulator. The output of the demodulator is connected to the input of the signal selector, the first, second, third and fourth information outputs of which are connected respectively to the first, second, third and fourth information inputs of the block for selecting additional sequences. The first and second information outputs of the additional sequence extraction unit are connected respectively to the first and second information inputs of the first two-channel matched filter, the first and second information outputs of which are connected respectively to the first and second information inputs of the first subtractor, the information receiver. The output of the clock generator is connected to the clock inputs of the frequency synthesizer and the pseudo random number generator. Moreover, the n control outputs of the pseudo random number generator are connected to the corresponding n control inputs of the frequency synthesizer, the output of which is connected to the modulating input of the demodulator.

The technical result in the implementation of the invention is to increase the noise immunity and reliability when exposed to deliberate impulse noise in the form of a sequence of discrete pulses is achieved by introducing a second dual-channel matched filter, a second subtractor and a noise compensator into the receiving part of the system. In this case, the first and second information outputs of the additional sequence extraction unit are connected respectively to the first and second information inputs of the second two-channel matched filter, the first and second information outputs of which are connected respectively to the first and second information inputs of the second subtractor, and the outputs of the first and second subtractors are connected respectively to the first and second information inputs of the interference canceller, the output of which is connected to the input of the decision unit.

The interference compensator can consist, for example, of the first and second decision blocks, an adder modulo two, a modulator, an adder. In this case, the first information input of the adder and the input of the first decision block are connected together and are the first information input of the interference canceller. The second information modulator and the input of the second decision block are connected together and are the second information input of the interference canceller. The output of the first decision block is connected to the first information input of the adder modulo two, and the output of the second decision block is connected to the second information input of the adder modulo two. The modulator two output of the adder is connected to the control input of the modulator. The output of the modulator is connected to the second information input of the adder, the output of which is the output of the interference canceller.

Thanks to the introduction of the second two-channel matched filter, the second subtractor and the interference compensator, the orthogonality condition is fulfilled according to the code structure of the four-coded sequences (E-codes, Welty codes) and the operation of convolution of the four-coded information sequence in the form of an inter-correlation function (VKF) is implemented. In this case, the VKF without pulse interference is equal to zero (U _VKF = 000000000000000 with N = 8). The fulfillment of the condition of orthogonality in the code structure of the four-coded sequences allows using the second two-channel matched filter and the second subtractor to isolate (implementation of the WKF), and then compensate for the impulse noise in the interference compensator (the implementation of summing the autocorrelation function (ACF) and VKF).

The analysis of the prior art by the applicant, including a search by patent and scientific and technical sources of information, and the identification of sources containing information about analogues of the claimed invention, allowed to establish that the applicant did not find an analogue characterized by features identical to all essential features of the claimed invention. The selection from the list of identified analogues of the prototype, as the closest in the set of essential features of the analogue, allowed us to identify the set of essential distinctive features perceived by the applicant in the claimed device set forth in the claims. Therefore, the claimed invention meets the criterion of "novelty."

To verify the compliance of the claimed invention with the criterion of "inventive step", the applicant conducted an additional search for known solutions to identify signs that match the distinctive features of the claimed device from the prototype. The search results showed that the claimed invention does not follow for a specialist explicitly from the prior art determined by the applicant. The effect of the transformations provided for by the essential features of the claimed invention on the achievement of a technical result is not revealed. In particular, the claimed invention does not provide for the following transformations: the addition of a known product with any known part, attached to it according to known rules, to achieve a technical result in respect of which the effect of such additions is established; the replacement of any part of a known product with another known part to achieve a technical result in respect of which the effect of such a replacement is established; the exclusion of any part of the funds with the simultaneous exclusion of the function due to its presence and the achievement of the usual result for such exclusion; the increase in the same type of elements to enhance the technical result due to the presence in the tool of just such elements; the implementation of a known tool or part of a known material to achieve a technical result due to the known properties of the material; the creation of a tool consisting of known parts, the choice of which and the connection between them are based on known rules, recommendations, and the technical result achieved in this case is due only to the known properties of the parts of this object and the relationships between them; a change in the quantitative features or the relationship of the features, if the fact of the influence of each of them on the technical result and new values of the features or their relationship are known, could be obtained from known dependencies. Therefore, the claimed invention meets the criterion of "inventive step".

The invention is illustrated by graphic materials, which depict: figure 1 - structural diagram of a data transmission system with multiple access and time division of channels; figure 2 is a structural diagram of a noise canceller; figure 3 - diagrams explaining the principle of forming a quaternary-coded radio signals from N transmitting parts of subscriber stations; figure 4 - diagrams explaining the principle of formation of a group radio signal with frequency hopping, consisting of N complex quaternary-encoded radio signals; 5 is a diagram illustrating the principle of the formation of the first and second additional sequences; 6 is a diagram illustrating the principle of convolution of the quaternary-encoded information sequences from N transmitting parts of subscriber stations; Fig.7 is a plot explaining the principle of selection of a quaternary-encoded radio signal when exposed to pulsed noise; Fig.8 is a plot explaining the principle of the formation of the first and second additional sequences when exposed to impulse noise; Fig.9 - diagrams explaining the principle of convolution of the quaternary-encoded information sequences from N transmitting parts of subscriber stations when exposed to pulsed noise; figure 10 - diagrams explaining the principle of decorrelation of impulse noise; 11 - diagrams explaining the principle of compensation of impulse noise.

The data transmission system with multiple access and time division of channels, presented in figure 1, consists of N = 2 ^k transmitting parts of subscriber stations and the receiving part of the central station. Moreover, each transmitting part of the subscriber station contains a clock 1, a clock 2, an information source 3, an information signal shaper 4, a coded signal shaper 5, a double frequency shift signal shaper 6, a modulator 7, a transmitter 8, a transmitting antenna 9, a frequency synthesizer 10 and pseudo random number generator 11. In each transmitting part of the subscriber station, an information source 3, an information signal shaper 4, an encoded signal shaper are connected in series la 5, dual-frequency shift signal driver 6, modulator 7, transmitter 8 and transmitting antenna 9. The output of clock generator 1 is connected to the clock inputs of the clock 2, information signal generator 4, coded signal generator 5, double-frequency signal driver 6, generator pseudo-random numbers 11 and a frequency synthesizer 10. The output of the chronizer 2 is jointly connected to the control inputs of the driver of the information signal 4 and the source of information 3. In this case, n control moves of the pseudo-random number generator 11, where n≥2, are connected to the corresponding n control inputs of the frequency synthesizer 10, the output of which is connected to the modulating input of the modulator 7. The receiving part of the central station contains a receiving antenna 12, a demodulator 13, a signal selector 14, an additional sequence allocation unit 15, interference canceller 16, information receiver 17, frequency synthesizer 18, pseudo-random number generator 19, clock generator 20. The output of the receiving antenna 12 is connected to the information input of the demodulator 13 The output of the demodulator 13 is connected to the input of the signal selector 14, the first, second, third and fourth information outputs of which are connected respectively to the first, second, third and fourth information inputs of the additional sequences extraction unit 15. The first information output of the additional sequences extraction unit 15 is jointly connected to the first information input of the first 16.1 and second 16.2 two-channel matched filters. The second information output of the additional sequences extraction unit 15 is jointly connected to the second information input of the first 16.1 and second 16.2 two-channel matched filters. The first and second information outputs of the first two-channel matched filter 16.1 are connected respectively to the first and second information inputs of the first subtractor 17.1. The first and second information outputs of the second two-channel matched filter 16.2 are connected respectively to the first and second information inputs of the second subtractor 17.2. The outputs of the first 17.1 and second 17.2 subtractors are connected respectively to the first and second information inputs of the interference canceller 18, the output of which is connected to the input of the information receiver 19. The output of the clock generator 22 is connected to the clock inputs of the frequency synthesizer 20 and the pseudo random number generator 21. At the same time, n control the outputs of the pseudo-random number generator 21 are connected to the corresponding n control inputs of the frequency synthesizer 20, the output of which is connected to the modulating input of the demodulator 13.

Clock generators 1 in the transmitting part and 22 in the receiving part are identical and are designed to generate clock pulses with the required frequency f _tg = V (where B is the transmission speed of the sequence of E-code elements (technical speed), it is expressed by the number of packages transmitted per unit time, measured in bits / s). They can be implemented, as described in the book of L.M. Goldenberg, Yu.T. Butylsky, M.Kh. Polyak "Digital devices on integrated circuits in communication technology" (M .: Communication, 1979, p. 72-76, fig. 3.14).

работы системы (где N - число элементов в четверично-кодированной последовательности). В качестве хронизатора может быть использована комбинация элементов, состоящая из последовательно соединенного двоичного счетчика и дешифратора. При этом q-й выход дешифратора (где q=1, 2, ..., N) является выходом хронизатора j-й передающей части абонентской станции в соответствии с равенством q=j. Данная схема может быть реализована, как описано в книге П.Г.Королева, Л.Д.Стащук «Нелинейные радиотехнические устройства. Часть 2» (М.: Воениздат, 1984, с.267-270, рис.9.12 г).Chronizer 2 is designed to generate enabling pulses in a given time interval for each specific j-th transmitting part of the subscriber station per cycle

system operation (where N is the number of elements in a quaternary-encoded sequence). A combination of elements consisting of a series-connected binary counter and a decoder can be used as a chronizer. In this case, the qth output of the decoder (where q = 1, 2, ..., N) is the output of the chronizer of the jth transmitting part of the subscriber station in accordance with the equality q = j. This scheme can be implemented, as described in the book by P.G. Korolev, L.D. Stashchuk "Non-linear radio engineering devices. Part 2 ”(Moscow: Military Publishing House, 1984, p. 267-270, Fig. 9.12 g).

в отведенный интервал времени за цикл работы системы. В качестве источника информации может быть использована аппаратура передачи дискретной информации с постоянной технической скоростью передачи.Information source 3 is designed to generate an information signal with a duration of

in the allotted time interval for the system cycle. As a source of information, discrete information transmission equipment with a constant technical transmission rate can be used.

Shaper information signal 4 is designed to generate an elongated information signal of duration Nτ. Its scheme is known and described in RF patent No. 2240653, IPC ⁷ H04B 7/12, decl. 04/21/03, publ. 11/20/04.

Shaper encoded signal 5 is designed to generate a quaternary-encoded information signal of duration Nτ. Its scheme is known and described in RF patent No. 2240653, IPC ⁷ Н04В 7/12, decl. 04/21/03, publ. 11/20/04.

Shaper 6 signals of double frequency manipulation is intended for the formation of a four-coded radio signal. It can be implemented, as described in the book by N.L. Teplova, E.N. Kudelina, and O.P. Lezhniuk, “Nonlinear Radio Engineering Devices. Part 1 ”(Moscow: Military Publishing House, 1982, p. 344-344, Fig. 8.42).

Modulator 7 is designed for pseudo-random tuning of the operating frequency within the allocated frequency resource Δf = f _max -f _min (where f _max is the maximum value of the selected frequency range; f _min is the minimum value of the selected frequency range). It can be implemented, as described in the book by N.L. Teplova, E.N. Kudelina, and O.P. Lezhniuk, “Nonlinear Radio Engineering Devices. Part 1 ”(Moscow: Military Publishing House, 1982, p.130-137, Fig.4.29).

The transmitter 8 is designed to amplify the four-coded radio signal to the required power. Any transmitter manufactured by the industry can be used as a transmitter, for example, a transmitter that is included with the R-161A2M radio station.

The transmitting antenna 9 is designed to convert the energy of high-frequency currents in the antenna-feeder path into the energy of freely propagating electromagnetic waves. As the transmitting antenna, any transmitting antenna that is included with the R-161A2M radio station can be used.

Frequency synthesizer 10, in the transmitting portion and receiving portion 20 are identical and designed for generating pseudo harmonic oscillation denominated _hopping frequency Δf = 4lf _n (where l = 1, 2, ..., L; L = 2 ⁿ -1 - maximum pseudo-random number in decimal code, n≥2 is the number of controlled inputs of the frequency synthesizer). Their circuit is known and described in RF patent No. 2240653, IPC ⁷ H 04 B 7/12, decl. 04/21/03, publ. November 20, 04 or in the patent of the Russian Federation No. 2208915, IPC ⁷ N 04 K 3/00, decl. 11/04/02, publ. 07/20/03.

(где n≥2 - число управляющих выходов генератора псевдослучайных чисел; ΔF_c=4B - эффективная ширина спектра четверично-кодированного радиосигнала; ]x[ - меньшее целое число). Они могут быть реализованы, как описано в книге У.Тице, К.Шенк «Полупроводниковая схемотехника» (М.: Мир, 1982, с.356-359, рис.20.20).The pseudo-random number generators 11 in the transmitting part and 21 in the receiving part are identical and are designed to generate pseudo-random numbers l = 1, 2, ..., L in binary code, where the maximum pseudo-random number L depends on the allocated frequency resource Δf and is determined in decimal code by the following expression:

(where n≥2 is the number of control outputs of the pseudo-random number generator; ΔF _c = 4B is the effective width of the spectrum of the four-coded radio signal;] x [is the smaller integer). They can be implemented, as described in the book by W. Tice, K. Schenk “Semiconductor circuitry” (M .: Mir, 1982, p. 356-359, Fig. 20.20).

The receiving antenna 12 is designed to convert the energy of freely propagating electromagnetic waves into the energy of high-frequency currents. As the receiving antenna, any receiving antenna that is included with the R-161A2M radio station can be used.

The demodulator 13 is designed to eliminate pseudo-random tuning of the operating frequency within the allocated frequency resource. It can be implemented, as described in the book by N.L. Teplov, E.N. Kudelin, O.P. Lezhniuk "Non-linear radio engineering devices. Part 1 ”(Moscow: Military Publishing House, 1982, p.130-137, Fig.4.29).

The signal selector 14 is designed for selection of a four-coded radio signal. Its scheme is known and described in RF patent No. 2240653, IPC ⁷ Н04В 7/12, decl. 04/21/03, publ. November 20, 04 or in the patent of the Russian Federation No. 2188516, IPC ⁷ H04L 27/26, decl. 05.21.01, publ. 08/27/02.

The block for extracting additional sequences 15 is intended for extracting the first additional sequence from the odd elements of the quaternary-encoded sequence (extracting the elements α, β) and extracting the second additional sequence from the even elements of the quadruply-encoded sequence (extracting the elements γ, δ). Its scheme is known and described in RF patent No. 2240653, IPC ⁷ Н04В 7/12, decl. 04/21/03, publ. November 20, 04 or in the patent of the Russian Federation No. 2188516, IPC ⁷ H04L 27/26, decl. 05.21.01, publ. 08/27/02.

Two-channel matched filters 18.1-18.2 are intended for convolution of additional sequences up to the duration of one element of a four-coded sequence. In this case, two-channel matched filters are tuned to orthogonal quaternary-coded sequences. Their scheme is known and described in A.S. No. 1721837 USSR, IPC ⁶ H04L 27/26, declared 01/08/90, publ. 03/23/92.

Subtractors 17.1-17.2 are designed to subtract the pulses of the convoluted second additional sequence arriving at its second input from the pulses of the convoluted first additional sequence arriving at its first input and forming a convolutional four-coded information sequence. They can be implemented, as described in the book by W. Tice, K. Schenk “Semiconductor circuitry” (M .: Mir, 1982, p.137-138, Fig. 11.2).

The jammer 18, the circuit of which is shown in figure 2, is designed to compensate for intentional impulse noise in the form of a sequence of discrete pulses. It consists of the first and second decision blocks 18.1-18.2, the adder modulo two 18.3, the modulator 18.4, the adder 18.5. In this case, the first information input of the adder 18.5 and the input of the first decision block 18.1 are connected together and are the first information input of the interference compensator 18. The second information input of the modulator 18.4 and the input of the second decision block 18.2 are connected together and are the second information input of the noise canceller 18. The output of the first decision block 18.1 is connected to the first information input of the adder modulo two 18.3, and the output of the second decision block 18.2 is connected to the second information input of the adder modulo two 18.3. The output of the adder modulo two 18.3 is connected to the control input of the modulator 18.4. The output of modulator 18.4 is connected to the second information input of the adder 18.5, the output of which is the output of the interference canceller 18.

Decision blocks 18.1-18.2 are intended for deciding on the transmitted quaternary-coded sequence. They can be implemented on the basis of the comparator, as described in the book of W. Tice, K. Schenk “Semiconductor circuitry” (M .: Mir, 1982, pp. 76-77, Fig. 6.13).

The adder modulo two 18.3 is designed to form a control voltage. It can be implemented, as described in the book by P.G. Korolev, L.D. Stashchuk "Non-linear radio engineering devices. Part 2 ”(Moscow: Military Publishing House, 1984, p. 255-259, Fig. 9.6a).

Modulator 18.4 is designed to invert decorrelated impulse noise depending on the control voltage. Its scheme is known and described in the patent of the Russian Federation No. 20144738, IPC 5 H04J 11/00, 10/00, decl. 02/18/1991, publ. 06/15/1994, figure 3 or A.S. USSR No. 1721837, IPC 5 H04L 27/26, decl. 01/08/90, publ. 03/23/92, figure 1.

The adder 18.5 is designed to compensate for de-correlated impulse noise from the total value of the four-coded information sequence and interference. It can be implemented as described in the book by W. Tice, K. Schenk “Semiconductor circuitry” (M .: Mir, 1982, p.137, fig. 11.1).

The information receiver 19 is intended for dividing a collapsed quaternary-encoded information sequence (a group signal with a temporary seal, consisting of N information sequences) into separate N information sequences. It can be implemented, as described in the book by M.V. Gitlits, A.V. Lev, “Theoretical Foundations of Multichannel Communication” (Moscow: Radio and Communication, 1985, p. 156-159, Fig. 7.9).

The data transmission system with multiple access and time division multiplexing, presented in figure 1, operates as follows.

.When you turn on in the j-th transmitting part of the subscriber station, the clock generator 1 with a frequency f _tg generates a sequence of clock pulses with a duty cycle equal to two. Each element of this sequence with a high level of "1" will be considered odd, and with a low level of "0" - even. In the remaining transmitting parts of the subscriber stations, the formation of a sequence of clock pulses in the clock generator 1 will be delayed by

.

. Тогда при передаче двоичной информации на выходе источника информации 3 каждой j-й передающей части абонентской станции информационные импульсы длительностью

будут появляться за цикл T_ц=Nτ работы системы передачи с множественным доступом и временным разделением каналов в строго определенном по времени месте. В качестве примера на фиг.3а, ..., з представлены эпюры информационных последовательностей от N=8 передающих частей абонентских станций соответственно (где цифрами (1, 2, 3, 4 и т.д.) показан порядковый номер информационных импульсов).Prior to the start of data transmission in a data transmission system with multiple access and time division of channels, clock generators 1 of all N transmitting parts of subscriber stations are synchronized by clock cycles, and chronometers 2 are synchronized by clock cycles so that they give enable pulses to the control inputs of information sources 3 at the specified specific j-th transmitting part of the subscriber station time intervals. In this case, the enabling pulses from the chroniser 2 are fed to the input of the information source 3 with a period

. Then, when transmitting binary information at the output of the information source 3 of each j-th transmitting part of the subscriber station, information pulses of duration

will appear during the cycle T _c = Nτ of the operation of the transmission system with multiple access and time division of channels in a strictly defined time place. As an example, FIGS. 3a, ..., h show diagrams of information sequences from N = 8 transmitting parts of subscriber stations, respectively (where the numbers (1, 2, 3, 4, etc.) show the serial number of information pulses).

An information pulse of duration τ from the output of the information source 3 (Fig. 3a, ..., h) is fed to the first information input of the driver of the information signal 4. The control input of the driver of the information signal 4 receives a clock from the synchronizer 2. The clock input of the driver of the information signal 4 the output of the clock generator 1 receives a sequence of clock pulses with a frequency f _tg . At the output of the driver of the information signal 4, an elongated information signal of duration Nτ is formed. Plots of elongated information signals from N = 8 transmitting subscriber stations are presented in FIGS. 3i, ..., p, respectively.

Thus, when an information impulse of the corresponding logical “1” arrives from the output of the information source 3 to the information input of the information signal former 4, an elongated information signal will be generated at its output, corresponding to the logical “1”, with a pulse duration equal to Nτ, a when the information the pulse corresponding to the logical "0", from the output of the information source 3 to the information input of the driver of the information signal 4 at its output will be formed elongated info mation signal corresponding to a logical "0" and a pulse duration equal Nτ.

The generated elongated information signal of duration Nτ (Fig.3i, ..., p) from the output of the shaper of the information signal 4 is fed to the information input of the shaper of the encoded signal 5. The clock input of the shaper of the encoded signal 5 from the output of the clock generator 1 receives a sequence of clock pulses with frequency f _tg . In the encoder 5, the formation and cyclic implementation of a quaternary-encoded sequence with a period of N = 2 ^k , for example, Velty codes or E-codes, takes place. As an example, on the diagrams of FIG. 3p, ..., h shows the implementation in encoders of encoded signals 5 in N transmitting parts of subscriber stations of the following initial quaternary-encoded sequence: αγαδαγβγ, with the number of elements N = 8, in which α = -β, γ = -δ. At the same time, in the quaternary-encoded information signal, the elements α, β of the quaternary-encoded sequence transmit the odd elements. E-code, and the elements γ, δ of the four-coded sequence are even elements of the E-code. Thus, at the output of the encoder 5, a four-coded information signal of duration Nτ is generated.

In this case, under the action of a logical "1" to the information input of the encoder 5, a non-inverted four-coded information signal is generated at its output, and under the action of a logical "0", an inverted four-encoded information signal is generated at its output .

From the output of the encoder signal shaper 5, the four-coded information signal (Fig.3p, ..., h) is fed to the information input of the signal shaper of double frequency manipulation 6, and the clock input of the signal shaper of double frequency manipulation 6 from the output of the clock generator 1 a sequence of clock pulses with a frequency f _tg . In the double-frequency manipulation signal generator 6, a four-coded information signal of duration Nτ is converted into a four-coded radio signal, and the elements of the four-coded radio signals α, β, γ and δ fulfill the frequency orthogonality condition. The diagrams of the quaternary-coded radio signals from N = 8 transmitting subscriber parts of the stations are shown in FIG.

The change in the high-frequency oscillations of the quaternary-encoded radio signal generated in the signal driver 2-fold frequency manipulation 6 can be described as shown in table. No. 1:

Table number 1 Quaternary Coded Elements Input No. 1 of block 6 (from block No. 5) Input No. 2 of block 6 (from block No. 1) Quadruple Coded Radio Frequency δ 0 0 f ₁ γ 0 one f ₂ β one 0 f ₃ α one one f ₄

where f ₁ <f ₂ <f ₃ <f ₄ or f ₁ > f ₂ > f ₃ > f ₄ is the frequency dependence of the frequency channels of the four-coded radio signal; Δf ₁ = | f ₁ -f ₂ |, Δf ₂ = | f ₂ -f ₃ |, Δf ₃ = | f ₃ -f ₄ | - the frequency shift between the frequency channels of the four-coded radio signal; Δf ₁ = xB, Δf ₂ = mB, Δf ₃ = zB; x = 1, 2, ... is an integer; m = 1, 2, ... is an integer; z = 1, 2, ... is an integer; x, m, z are the coefficients that control the change in the frequency shift between the frequency channels of the four-coded radio signal.

The four-coded radio signal generated in the shaper of double frequency manipulation 6, is fed to the information input of the modulator 7.

The clock input of the pseudorandom number generator 11 from the clock generator 1 receives a sequence of clock pulses with a frequency f _tg . In the pseudo-random number generator 11, the sequence of clock pulses is converted into a pseudo-random sequence, which is fed to the n control outputs of the pseudo-random number generator 11 with a time shift of one clock cycle at each output of the pseudo-random number generator 11 in binary code. The pseudo-random number generator 11 has a capacity of L = 2 ⁿ -1 depending on the allocated frequency resource Δf. The pseudo-random number generators 11 of all the transmitting subscriber parts of the stations form the same pseudo-random sequence.

A pseudo-random sequence in binary code from n control outputs is supplied to the n control inputs of the frequency synthesizer 10, respectively. The clock input of the frequency synthesizer 10 receives a sequence of clock pulses with a frequency f _tg from the output of the clock generator 1. The frequency synthesizer 10 is formed by a pseudorandom _{frequency hopping} Δf harmonic oscillation frequency depending on the nominal value allocated frequency resource Δf.

The generated pseudo harmonic oscillation _{frequency hopping} denominated Δf is supplied to the modulating input of the modulator 7. Diagrams pseudo harmonic oscillation when L = 4 are shown in Figure 4a. At the output of modulator 7, for x = m = z = 1, Δf ₁ = Δf ₂ = Δf ₃ and f ₁ <f ₂ <f ₃ <f ₄ , four-coded radio signals with frequency hopping are generated within the allocated frequency resource Δf.

The four-coded radio signal from the output of the modulator 7 is fed to the input of the transmitter 8, in which the radio signal is amplified, and then fed to the input of the transmitting antenna 9. The transmitting antenna 9 converts the energy of high-frequency currents in the antenna-feeder path into the energy of freely propagating electromagnetic waves.

The time-frequency matrix of quaternary-coded radio signals with frequency hopping (group radio signal) at L = 4, N = 8 is shown in Fig.4b (where the numbers and (1, 2, 3, 4, etc.) show the presence and value of the element amplitude group signal).

The receiving antenna 12 of the receiving part of the central station receives a set of four-coded radio signals from all N transmitting subscriber stations (group radio signal figb). The receiving antenna 12 converts the energy of freely propagating electromagnetic waves into the energy of high-frequency currents. From the output of the receiving antenna 12, the set of four-coded radio signals from all N transmitting subscriber stations is fed to the input of the demodulator 13.

Clock generator 22, a pseudorandom number generator 21 and the receiving frequency synthesizer 20 of the central work station and generating a pseudo harmonic oscillation denominated Δf _FH similarly as in the transmitting parts of the subscriber stations. Consequently, the output of the frequency synthesizer 20 is formed by a pseudorandom harmonic oscillation denominated Δf _{frequency hopping,} a similar pseudo-harmonic oscillation being generated in the transmitter portion of the subscriber stations (4a). The generated pseudo-random harmonic oscillation is fed to the modulating input of the demodulator 13.

The demodulator 13 due to the frequency synthesizer 20 controlled by a pseudorandom number generator 21, jumps a working frequency Δf _{frequency hopping} are removed, resulting in the quaternary-coded signal is transferred to the originally selected frequency (f _1, f _2, f ₃ and f _4).

From the output of the demodulator, the four-coded radio signal is fed to the input of the signal selector 14, which performs frequency selection of strictly defined high-frequency elements of the four-coded radio signal. At the first, second, third and fourth outputs of the signal selector 14, respectively, the first, second, third and fourth high-frequency radio signals are generated. Plots of the first, second, third and fourth high-frequency radio signals are presented in figa, ..., g, respectively.

The first, second, third and fourth high-frequency radio signals (figa, ..., g) from the outputs of the signal selector 14, respectively, are supplied to the first, second, third and fourth inputs of the block for selecting additional sequences 15.

At the first and second information outputs of the block for extracting additional sequences 15, the first and second additional sequences are respectively formed. In this case, the first additional sequence is formed from the odd elements of the quaternary-encoded sequence (allocation of elements α, β), and the second additional sequence of even elements of the quaternary-encoded sequence (selection of elements γ, δ). Plots of the first and second additional sequences are presented in figs. 5e, e, respectively.

The first additional sequence (Fig.5d) simultaneously enters the first information inputs of the first and second two-channel matched filters 16.1-16.2, and the second additional sequence (Fig.5e) simultaneously enters the second information inputs of the first and second two-channel matched filters 16.1-16.2. At the same time, the first two-channel matched filter 16.1 is tuned to the first quaternary-encoded sequence αγαδαγβγ (i = 1), and the second two-channel matched filter 16.2 is tuned to the second quaternary-encoded sequence αγαδβδαδ (r = 5). The quaternary-coded sequences to which the first and second two-channel matched filters 16.1-16.2 are tuned are orthogonal in code structure. In this case, the quaternary-encoded sequences orthogonal in the code structure do not have lateral outliers in the inter-correlation function (VKF) in accordance with the expression:

,

,

- время анализа ВКФ; i - номер четверично-кодированной последовательности E_i(t) (Е-кода), на которую настроен первый двухканальный согласованный фильтр 16.1, i=1, 2, ..., М; r - номер четверично-кодированной последовательности E_i(t} (Е-кода), на которую настроен второй двухканальный согласованный фильтр 16.2, r=1, 2, ..., М; М - число четверично-кодированных последовательностей (Е-кодов) M=N.Where

- time analysis VKF; i is the number of the four-coded sequence E _i (t) (E-code), which is configured to the first two-channel matched filter 16.1, i = 1, 2, ..., M; r is the number of the quaternary-encoded sequence E _i (t} (E-code), which is tuned to the second two-channel matched filter 16.2, r = 1, 2, ..., M; M is the number of quaternary-encoded sequences (E-codes ) M = N.

For example, with N = 8, the total number of quaternary-encoded sequences (E-codes) is represented as a matrix:

.

.

The number i of the four-coded sequence to which the first two-channel matched filter 16.1 is tuned is associated with the number r of the four-coded sequence to which the second two-channel matched filter 16.2 is tuned by the following relation:

In the first two-channel matched filter 16.1, the first and second additional sequences (Figs. 5e, e) are collapsed to the duration of one element of the four-coded sequence. Plots of folded first and second additional sequences are presented in figa, b, respectively. The folded first and second additional sequences (figa, b) are fed to the first and second information inputs of the first subtractor 17.1, respectively.

In the first subtractor 17.1, the pulses of the second folded additional sequence (Fig.6b) supplied to the second information input of the first subtractor 17.1 are subtracted from the pulses of the first folded additional sequence (Fig.6a) fed to the first information input of the first subtractor 17.1. At the output of the first subtractor 17.1, information pulses will be generated from N transmitting subscriber stations with an amplitude N = 2 ^k times the amplitude of the element of the four-coded sequence, which corresponds to the ACF of the four-coded sequences. The diagrams of collapsed quaternary-encoded information sequences from N transmitting parts of subscriber stations are presented in FIG.

In the second two-channel matched filter 16.2 and in the second subtractor 17.2, the convolution of the first and second additional sequences (Figs. 5e, e) occurs similarly. Moreover, the VKF of orthogonal in the code structure of the quaternary-encoded sequences is by definition equal to zero. Therefore, at the output of the second subtractor 17.2, a zero will be formed (Fig. 6d), which corresponds to the VKF of the four-coded sequences.

The folded pulses of the quaternary-coded sequences (Figs. 6c, d) from the outputs of the first and second subtractors 17.1-17.2 are fed to the corresponding first and second information inputs of the interference compensator 18.

The jammer 18 presented in figure 2, operates as follows. The folded pulses of the quaternary-coded sequences (Fig.6c, d), passing through the corresponding first and second decision blocks 18.1-18.2 sequentially without structural change, the adder modulo two 18.3, the modulator 18.4 and the adder 18.5, go to the output of the interference canceller 18. At the output interference equalizer 18 are formed convoluted pulses of a quadruple-encoded information sequence (pigv).

The folded quaternary-encoded information sequences (Fig.6c) from the output of the interference canceller 18 are fed to the input of the information receiver 19, while the signals N of the transmitting parts of the subscriber stations due to the pulsed form of the ACF of the four-coded information sequence and their time shift in the information receiver 19 are respectively by time.

Suppose that the input of the receiving part of the central station of the data transmission system with multiple access and time division of channels is affected by an impulse noise (hereinafter, an interference) in the form of a sequence of discrete pulses with an amplitude U _p = 10U (where U is the amplitude of the element of the four-coded sequence).

The total value of the Quaternary-encoded radio signal and interference is fed to the input of the signal selector 14, which frequency selects strictly defined elements of the Quaternary-encoded radio signal in the form of the sum of the useful signal and interference U _s + U _p . At the first, second, third and fourth information outputs of the signal selector 14, respectively, the first, second, third and fourth high-frequency radio signals are generated in the form of the sum of the useful signal and interference U _s + U _p . Plots of the generated first, second, third and fourth high-frequency radio signals in the form of the sum of the useful signal and interference U _s + U _{p are} presented in Figs. 7a, ..., g, respectively, where the interference is presented in the form of dark squares with an amplitude U _p = 10U. The first, second, third and fourth high-frequency radio signals in the form of the sum of the useful signal and interference U _s + U _p (Fig. 7a, ..., g) from the corresponding information outputs of the signal selector 14 are respectively sent to the first, second, third and fourth information the inputs of the block allocating additional sequences 15.

In the block for extracting additional sequences 15, the envelope is extracted from the first, second, third, and fourth high-frequency radio signals in the form of the sum of the useful signal and interference U _s + U _p (Fig. 7a, ..., g) and elimination of the carrier high-frequency oscillations. At the first and second information outputs of the block for extracting additional sequences 15, the first and second additional sequences are respectively formed. Plots of the formed first and second additional sequences are presented in figa, b, respectively. The first additional sequence (Fig.8a) is supplied to the first information inputs of the first and second two-channel matched filters 16.1-16.2, the second additional sequence (Fig.8b) is fed to the second information inputs of the first and second two-channel matched filters 16.1-16.2.

In the first two-channel matched filter 16.1, the first and second additional sequences (figa, b) are collapsed. The diagrams of the folded first and second additional sequences are shown in Figs. 9a, b, respectively. The folded first and second additional sequences (Figs. 9a, b) from the corresponding information outputs of the first two-channel matched filter 16.1, respectively, are supplied to the first and second information inputs of the first subtractor 17.1.

In the first subtractor 17.1, the subtraction of the pulses (Fig. 8b) arriving at its second information input is provided from the pulses (Fig. 8a) arriving at its first information input. Therefore, at the output of the first subtractor 17.1, pulses of the total value of the folded four-coded information sequence and interference will be generated. Plots of the folded Quaternary-coded information sequence and interference are shown in Fig. 9c.

In the second two-channel matched filter 16.2 and in the second subtractor 17.2, the convolution of the first and second additional sequences (Fig. 8a, b) occurs similarly. The diagrams of the folded first and second additional sequences are shown in FIGS. 10a, b, respectively. The folded first and second additional sequences (Fig. 10a, b) from the corresponding information outputs of the second two-channel matched filter 16.2, respectively, are supplied to the first and second information inputs of the second subtractor 17.2. In this case, the VCF of orthogonal in the code structure of the four-coded sequences is by definition equal to zero, therefore, at the output of the second subtractor 17.2, only decorrelated (collapsed) interference pulses will be generated. Diagrams of de-correlated interference are presented in Fig. 10c.

The collapsed pulses of the total value of the four-coded information sequence and interference (Fig. 9c), as well as decorrelated interference (Fig. 10c) from the corresponding outputs of the first and second subtractors 17.1-17.2, respectively, are supplied to the corresponding first and second information inputs of the interference compensator 18.

In the interference compensator 18, the convoluted pulses of the total value of the four-coded information sequence and the interference (Fig. 9c) are input to the first decision block 18.1, and the decorrelated noise pulses (Fig. 10c) are input to the second decision block 18.2. In the first and second decision blocks 18.1-18.2, a decision is made depending on the sign of the total value of the four-coded information sequence and interference (Fig. 9c) and decorrelated interference (Fig. 10c) according to the following rule:

At the outputs of the first and second decision blocks 18.1-18.2, information pulses U _inf . Plots of information pulses are presented in figa, b, respectively.

The generated information pulses U _inf (figa, b) from the outputs of the first and second decision blocks 18.1-18.2 are fed to the corresponding first and second information inputs of the adder modulo two 18.3. At the output of the adder modulo two 18.3 control pulses are formed. The diagrams of the control pulses are presented on figv.

The decorrelated interference (Fig.10c) from the output of the second subtractor 17.2 also arrives at the information input of the modulator 18.4, and the control pulses of the modulator 18.4 receive control pulses (Fig.11c) from the output of the adder modulo two 18.3. This takes into account that the modulator 18.4 works according to the following rule:

Thus, under the action of a logical "1" on the control input of the modulator 18.4, inversion of decorrelated interference (Fig. 10c) does not occur, and under the action of a logical "0" on the control input of the modulator 18.4, inversion of decorrelated interference occurs (Fig. 10c). Diagrams of de-correlated noise at the output of modulator 18.4 are shown in Fig. 11g.

The decorrelated noise (Fig. 11g) from the output of the modulator 18.4 is fed to the second information input of the adder 18.5, and the pulses of the total value of the quad-coded information sequence and interference (Fig. 9c) from the output of the first subtractor 17.2 are sent to the first information input of the adder 18.5. In the adder 18.5, the interference is compensated (Fig. 11d) from the pulses of the total value of the four-coded information sequence and the interference (Fig. 9c). At the output of adder 18.5, information pulses will be generated from N transmitting parts of subscriber stations with an amplitude N = 2 ^k times the amplitude of the element of the four-coded sequence. The diagrams of collapsed quaternary-encoded information sequences from N transmitting subscriber parts of the stations are shown in Fig. 11d.

Thus, in the noise compensator 18 is the selection and compensation of impulse noise in the form of a sequence of discrete pulses. At the output of the interference compensator 18, pulses of a four-coded information sequence are generated (Fig.6c or Fig.11d). As a result, the four-encoded information sequences (Velty codes or E-codes) are convolved from N transmitting parts of subscriber stations, characterized in that it does not have side emissions in aperiodic ACF and VKF. The collapsed quaternary-encoded information sequences (Fig.6c or Fig.11d) (collapsed group signal) take the form, as in a transmission system with multiple access and time division of channels (prototype) and are also delayed by time (T _c -τ).

The folded Quaternary-encoded information sequences (Fig.6c or Fig.11d) from the output of the interference canceller 18 are fed to the input of the information receiver 19, while the signals of the N transmitting parts of the subscriber stations due to the pulsed form of the ACF of the four-coded information sequence and their time shift in the receiver information 19 is respectively divided by time.

In the claimed data transmission system with multiple access and time division of channels after eliminating the frequency hopping frequency and forming the first and second additional sequences, a simultaneous, independent correlation convolution of the sum of the complex signal and the impulse noise is performed, which provides decorrelation of the impulse noise and its compensation from the total value of the quad-encoded information sequence and interference. As a result, the convolutional quadruple-encoded information sequences are restored from N transmitting parts of subscriber stations. Compensation of impulse noise from the total value of the quaternary-encoded information sequence and the interference is carried out by fulfilling the condition of orthogonality in the code structure between two quaternary-encoded sequences (E-codes) that do not have side emissions in aperiodic ACF and VKF.

Thus, the proposed data access system with multiple access and time division of channels provides expansion of the scope due to increased noise immunity and reliability under the influence of deliberate impulse noise in the form of a sequence of discrete pulses in communication channels with random signal parameters (phase, amplitude and polarization) of meter and decameter frequency ranges with frequency hopping due to the allocation and compensation of intentional impulse noise, provided the use of orthogonal GOVERNMENTAL quaternary structure of a code sequence encoded without extension of frequency resources and reducing system capacity, and is designed for data transmission systems with code division signal and data transmission systems with multiple access and time division multiplexing.

The above information indicates the following conditions are met when using the claimed device:

- a tool embodying the claimed device in its implementation, is intended for use in transmission systems and data collection with multiple access and time division channels;

- for the claimed device in the form described in the claims, the possibility of its implementation using the means and methods described in the application or known prior to the priority date is confirmed;

- a tool embodying the claimed invention in its implementation, is able to ensure the achievement of the perceived by the applicant technical result.

Thus, the claimed invention meets the criterion of "industrial applicability".

Claims (2)

1. The data transmission system with multiple access and time division of channels contains N = 2 ^k (where k≥2 is an integer; j = 1, 2, ..., N is the number of the transmitting part of the subscriber station) of the transmitting parts of the subscriber stations and the receiving part of the central station, while in each transmitting part of the subscriber station, an information source, an information signal shaper, a coded signal shaper, a two-frequency frequency shift signal shaper, a modulator, a transmitter and a transmitting antenna, a gene output are connected in series the clock pulse generator is jointly connected to the clock inputs of the chronizer, information signal generator, coded signal generator, double frequency manipulator, pseudorandom number generator and frequency synthesizer, the chronizer output is connected to the control inputs of the information signal generator and information source, n control outputs of the pseudorandom generator numbers, where n≥2, are connected to the corresponding n control inputs of the frequency synthesizer, the output of which connected to the modulating input of the modulator, and the receiving part of the central station contains a receiving antenna, the output of which is connected to the information input of the demodulator, the output of the demodulator is connected to the input of the signal selector, the first, second, third and fourth information outputs of which are connected respectively to the first, second, third and the fourth information inputs of the additional sequences allocation unit, the first and second information outputs of which are connected respectively to the first and second info the inputs of the first two-channel matched filter, the first and second information outputs of which are connected respectively to the first and second information inputs of the first subtractor, the information receiver, the output of the clock generator is connected to the clock inputs of the frequency synthesizer and pseudo-random number generator, n control outputs of the pseudo random number generator are connected to corresponding n control inputs of the frequency synthesizer, the output of which is connected to the modulating input of the demodulator, distinguishing In that a second two-channel matched filter, a second subtractor and a noise canceller are additionally introduced into the receiving part of the central station, while the first and second information outputs of the additional sequence extraction unit are also connected respectively to the first and second information inputs of the second two-channel matched filter, the first and second the information outputs of which are connected respectively to the first and second information inputs of the second subtractor, and the outputs of the first and second The subtractors are connected respectively to the first and second information inputs of the interference canceller, the output of which is connected to the input of the information receiver. 2. The transmission system according to claim 1, characterized in that the interference compensator consists of the first and second decision blocks, an adder modulo two, a modulator, an adder, while the first information input of the adder and the input of the first decision block are connected together and are the first information input the interference compensator, as well as the second information modulator and the input of the second decision block are connected together and are the second information input of the noise canceller, the output of the first decision block is connected to the first information input modulo two to the adder, and the output of the second decision block is connected to the second information input of the modulo two adder, the output of which is connected to the control input of the modulator, the modulator output is connected to the second information input of the adder, the output of which is the output of the noise canceller.

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