RU2556872C1 - Multiple access and time division multiplex data transmission system - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: method includes setting up a single time scale in the system and associating slots with exact universal time and reducing guard intervals in each slot; designing equipment based on principles of digital signal processing and program execution of basic functions in system nodes; facilitating modernisation of system equipment, for example, introducing new modulation, coding and interleaving modes and other functions by computer reprogramming.

EFFECT: facilitating two-way communication between each of a user station and a central station and through the central station with information recipients, high reliability and rate of transmitting data.

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Description

The invention relates to communication technology and can be used in data transmission systems with multiple access and time division channels.

A known system of multiple access with time division of channels, described in the book [1], which contains 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 disadvantages of this time-division multiple access system are the difficulties of its modernization, for example, the introduction of new modulation and coding modes, since its nodes are made in hardware, and the lack of adaptation properties, since it cannot work in radio communication networks with other types of modulation and coding.

A known system of data transmission with multiple access with time division of correspondents according to the patent [2], which contains N transmitting parts of subscriber stations (AC), each of which contains a source of information, a shaper of four-coded sequences, a transmitter, a transmitting antenna, a clock, a clock and the receiving part of the Central station (CA), which contains a receiving antenna, a unit for receiving Quaternary-encoded radio signals, a receiver of information similar to the proposed system. Moreover, in the known system, four-coded sequences (E-codes, Welty codes) are used to transmit information that do not have side outliers in the aperiodic autocorrelation function (ACF).

The disadvantages of this data transmission system with multiple access and time division of correspondents are the difficulties of its modernization, for example, the introduction of new modulation and coding modes, since its nodes are hardware-based, and the lack of adaptation properties, since it cannot work in radio communication networks with other types of modulation and coding.

A known data transmission system with multiple access and time division of channels [3], which contains N transmitting parts of subscriber stations, each of which contains a clock, clock, information source, shaper of the information signal, shaper of the encoded signal, shaper of signals of double frequency manipulation, 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 Aerial, demodulator, signal selector, additional sequence extraction unit, first two-channel matched filter, first subtractor, first information receiver, frequency synthesizer, pseudo-random number generator and clock.

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 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 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 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 jointly 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.

A data access system with multiple access and time division of channels - an analogue - 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 a four-coded sequence are transmitted at frequencies f3 + f or f4 + fPHF, and even elements of a quaternary-coded sequence are transmitted at frequencies f1 + fHPH or f2 + fHPHF, i.e. the frequency rating determines the number of the additional sequence in h tverichno-coded radio signal.

The disadvantage of this data transmission system with multiple access and time division of channels is the inefficiency of using the frequency resource and the lack of adaptation properties.

The closest in technical essence and functions to the claimed data transmission system with multiple access and time division of channels analogue (prototype) is a data transmission system with multiple access and time division of channels, containing N transmitting parts of subscriber stations and the receiving part of the central station, which adopted as a prototype [4]. At the same time, each transmitting part of the subscriber station contains a clock pulse generator, the output of which is jointly connected to the clock inputs of the information signal shaper, the first channel for generating the four-coded signals, a frequency synthesizer, a pseudorandom number generator and a chronizer. The output of the chronizer is jointly connected to the control input of the driver of the information signal and to the clock input of the information source. The output of the information source is connected to the information input of the driver of the information signal, the output of which is connected to the input of the transmitter, the output of the transmitter is connected to the input of the transmitting antenna. Moreover, 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 modulator. 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 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 the first channel for processing the quad-coded signals. The output of the clock generator is jointly connected to the clock inputs of the frequency synthesizer and the pseudo-random number generator, n control outputs of which are connected to the corresponding n control inputs of the frequency synthesizer, the output of the frequency synthesizer is connected to the modulating input of the demodulator.

In each transmitting part of the subscriber station of the sub-stream generating unit, it is identical to the first of the second channel for generating the quad-coded signals and the adder, and in the receiving part of the central station by introducing it identical to the first of the second channel for processing the four-coded signals and combiner. At the same time, in the receiving part, the output of the driver of the information signal is connected to the information input of the sub-stream generation unit, the first and second information outputs of which are respectively connected to the information inputs of the first and second channels for generating the quad-coded signals. The output of the clock generator is also jointly connected to the clock inputs of the sub-stream generating unit and the second channel for generating the quad-coded signals. The outputs of the first and second channels of the formation of the quaternary-encoded signals are respectively connected to the first and second information inputs of the adder, the output of which is connected to the information input of the modulator. In this case, 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 channel for processing the quad-coded signals, N information outputs of which are connected to the corresponding from the N + 1 through 2N information inputs of the combining device, and N information outputs of the first channel for processing the quaternary encoded signals are connected to the corresponding from the 1st to the Nth information inputs of the combining device, N information The output outputs of the combining device are N information outputs of the receiving part of the central station.

In each transmitting part of the subscriber station, there is a block for generating sub-flows, a second channel for generating four-coded signals and an adder identical to the first channel, and in the receiving part of the central station, a second channel for processing four-coded signals and a combiner identical to the first channel. At the same time, in the receiving part, the output of the driver of the information signal is connected to the information input of the sub-stream generation unit, the first and second information outputs of which are respectively connected to the information inputs of the first and second channels for generating the quad-coded signals. The output of the clock generator is also jointly connected to the clock inputs of the sub-stream generating unit and the second channel for generating the quad-coded signals. The outputs of the first and second channels of the formation of the quaternary-encoded signals are respectively connected to the first and second information inputs of the adder, the output of which is connected to the information input of the modulator. In this case, 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 channel for processing the quad-coded signals, N information outputs of which are connected to the corresponding from the N + 1 through 2N information inputs of the combining device, and N information outputs of the first channel for processing the quaternary encoded signals are connected to the corresponding from the 1st to the Nth information inputs of the combining device, N information The output outputs of the combining device are N information outputs of the receiving part of the central station.

The disadvantages of this system of data transmission with multiple access with time division of correspondents are:

- the presence of only the transmitting part of the subscriber stations and the receiving part of the central station, therefore, it cannot operate in duplex or simplex modes;

- time synchronization of equipment of space-distributed central and subscriber stations is difficult due to possible discrepancies in the time scales of the clock pulses of the subscriber stations and the central station, which limits the number of served speakers;

- system equipment is difficult to modernize, for example, the introduction of new modulation and coding modes, since its nodes are made in hardware.

The task to which the invention is directed is to expand the functionality of the system, namely:

- ensuring two-way data exchange between each of the speakers and the CA and through the CA with the recipients of information;

- the organization of a single time scale (synchronization) in the system will increase the reliability and speed of information transfer in the system by linking the slots to the exact world time and, therefore, reducing the guard intervals in each slot;

- the construction of equipment on the principles of digital signal processing and software performing the basic functions in the nodes of the system;

- increase in the number of serviced speakers;

- availability of a database of the current characteristics of the system subscribers with the possibility of current updating of arrays;

- the ability to upgrade system equipment, for example, the introduction of new modulation, coding, interleaving, and other functions by reprogramming computing tools.

The technical result of the invention is:

- software implementation of AS and CA equipment, simplifying the introduction of well-known new and the implementation of existing modes of two-way data exchange due to automatic software changes;

- dynamic tuning of not only operating frequencies, but also radio access technologies;

- effective use of the allocated frequency spectrum of the radio range.

The specified technical result is achieved by the fact that in the known data transmission system with multiple access and time division of channels containing N subscriber stations (AC) and a central station (CS), each subscriber station, like the central station, contains a clock the output of which is simultaneously connected to the clock inputs of the driver of the information signal, frequency synthesizer and chronizer, the output of which is jointly connected to the control input of the driver of the information signal and to the clock input of the speaker information source with the data input of each speaker, the output of which is connected to the information input of the driver of the information signal, the transmitter, the output of which is connected to the input of the transmitting antenna, a receiving antenna, and the central station also contains a combining center, N information outputs of which are N information outputs of the central station, in each subscriber station, as in the central station, the output of the receiving antenna through a series-connected filter matching device a, a broadband amplifier, an analog-to-digital converter (ADC) is connected to the information input of the first signal processor, the output of the information signal shaper through a second signal processor connected in series, a digital-to-analog converter (DAC), the filter is connected to the transmitter input, the clock input of the clock generator is connected to the output signal receiver global navigation satellite systems with an antenna, the corresponding outputs of the chronizer are connected to the sync inputs of the first and second of the signal processors and the frequency synthesizer, the corresponding outputs of the synthesizer are connected to the ADC and DAC clock inputs, the first control bus of the introduced central processor with an external input / output is connected to the corresponding inputs / outputs of a filter-matching device, a broadband amplifier, an analog-to-digital converter, the first signal processor, the second the control bus of the central processor with external input / output is connected to the corresponding inputs / outputs of the driver of the information signal, of a signal processor, DAC, filter, transmitter, synthesizer, the outputs of the chronizer are connected to the corresponding inputs of the ADC, DAC, and the central processor with external input / output, as well as the information output of the first signal processor of each subscriber station is connected to the AC combining device, synchronized by pulses from the corresponding the output of the chronizer, the output of the combining device is the output of the AC, N information inputs are the inputs of the CA and the information source of the CA, the output of which is connected to a signal generator to the CA, and the sync input to the corresponding chronizer output to the CA, the first control bus of the AC central processor with external input / output is connected to the corresponding input / output of the AC combining device, and the first control bus of the central processor of the CA with external input / output is connected to the corresponding input / output of the CA combining device, the transmitting antennas of each AC are connected by radio to the receiving antenna of the CA, and the transmitting antenna of the CA is connected to the receiving antenna of each AC.

The structural diagram of the inventive radio communication system with moving objects, is presented in the drawing, where it is indicated:

1 - subscriber station (AS) in the amount of N pieces;

2 - central station (CA);

3 - clock generator;

4 - shaper information signal;

5 - frequency synthesizer;

6 - chronizer;

7 - speaker information source with data input of each speaker;

8 - transmitter;

9 - transmitting antenna;

10 - receiving antenna;

11 is a device combining a CA whose N information outputs are N information outputs of a central station;

12 - filter matching device;

13 - broadband amplifier;

14 - analog-to-digital Converter (ADC);

15 - the first signal processor;

16 - the second signal processor;

17 - digital-to-analog converter (DAC);

18 - filter;

19 is a receiver of signals of global navigation satellite systems with an antenna;

20 - the first control bus of the central processor 21 with external input / output 22;

23 - the second control bus of the central processor with external input / output;

24 - a device for combining speakers;

25 - CA information source.

The system operates as follows. When organizing the exchange of data between any speaker and a central processing unit 21 with an external input / output 22, the presence of the selected speaker in the service area is determined by the presence of the corresponding radio signal of a given frequency in a certain time interval. If the presence of the radio signal is confirmed, then the information received at the input of the CA for the corresponding AC 1 is transmitted in the allocated (known in advance for all speakers) range and operating frequency. In this case, the availability of relevant data directly from the source 25 of information of the DS 2, for example, voice signals or data at the corresponding input of the DS 2, at the output of the shaper 4 of the information signal associated with the bus 23, from the output of the central processor 21 via the bus 23 to the DS 2 corresponding control signals to nodes 16, 5 18, 8 and through node 5 to node 17, and using the received data, a message is generated containing the address of the recipient, for example, by slot number, as well as the sender address, for example, by input channel number CA information source 25 (if necessary). The radio signal emitted from the DS 2 using the transmitting antenna 9 is received at the AS, and when receiving control signals from the output of the central processor 21 via the bus 20 on the AS 1, it is processed sequentially at nodes 12, 13, 14, 15. Then the message is reduced to the required format in the device 24 combining the speaker and enters the output of the subscriber station 1.

If there is information at the input of AC 7 information source 7, for example, voice communication or data at the output of information signal former 4 (bus 23), the corresponding control signals are sent to nodes 16, 5 and through it via bus 23 to AC 1 17, 18, 8, and using the received data, a message is generated containing the recipient’s address in the specified time interval (slot). When receiving on CA 2, operations similar to those described above when describing the functions performed on AC 1 are carried out. The only difference is that in addition to restoring the data format, the CA combining device 11 carries out message routing operations for the required user through one of the N information outputs of the central station 2. In addition, the source of information 7 AC 1 is designed to convert the input information message into a parcel lasting less than a specified time interval for each concre hydrochloric subscriber station for the work cycle of the system.

The performance monitoring of the remote speakers 1 at the central station 2 is carried out by the availability of information in the corresponding slots and the control message generated by the second signal processor 17, transmitted after a specified time (in the absence of data at the input of the speaker 1). If such information is not available, then a request message is sent from CA 2 about the status of AC 1. The absence of a response for a specified time characterizes the inoperative or off state of a specific AC 1. When data is received for such AC 1, they are stored in the memory of the central processor 21 of CA 2 restoration of the performance of the subscriber station 1 are transmitted to it. If AC 1 is not restored for a long time, then outdated data is erased, and new messages are written in their place.

The node 4 is designed to generate a discrete message from the output of the information source 7 in the corresponding slot so that its duration is placed in this slot taking into account the protective intervals and is consistent with the requirements for the input signal parameters of the second signal processor 16. The transmitting antenna 9 is designed to convert high-frequency energy currents in the antenna-feeder path into the energy of freely propagating electromagnetic waves, and the receiving antenna 10 to convert energy freely distributed stranyayuschihsya electromagnetic waves into energy of high-frequency currents. The output signals of the frequency synthesizer 5, clocked by the chronizer 6 and controlled by the central processor 21, are necessary for converting analog signals to digital in ADC 14 and digital signals to analog in DAC 17.

The chronizer 6 of all N subscriber stations 1 issues enable pulses, including pulses characterizing the beginning of each cycle and slot, to the clock inputs of information sources 7, nodes 4, 16 and 17, nodes 14, 15 and 24 at intervals specified for a particular subscriber station time with a period equal to one exchange cycle. Chronizer 6 DS 2 generates enable pulses to the clock inputs of the source 25 of information DS 2, nodes 4, 16 and 17, nodes 14, 15 and 24 in all slots during the exchange cycle of a transmission system with multiple access and time division of channels. In the device 11 combining the CA 2 allocated in the first signal processor 15 information pulses are converted into messages of the desired format and are output from the central station.

In the central processors 21, in accordance with the information inputted through the external input / output 22, control signals are generated to implement the protocols of the physical, channel and network level of the reference model for the interaction of open systems in the corresponding nodes of the AC and the CA for organizing data exchange using known operations, for example , [5]:

- coding and decoding of data in signal processors 15 and 16 for error correction;

- interleaving data in the signal processors 15 and 16 to combat packetization errors due to fading and impulse noise;

- scrambling data in the signal processors 15 and 16 to align the spectrum of the transmitted signal;

- the formation in the signal processors 15 and 16 of the key synchronization sequence and preamble containing a known sequence for implementing adaptive methods for receiving messages;

- the formation in the filters 18 of a given shape of the envelope of each symbol such as a raised cosine to provide a given spectral mask of the emitted signal.

The radio signal generated for transmission from the output of the filter 18 is fed to the input of the transmitter 8, in which, using the control actions of the central processor 21, conditions are prepared for generating a radio signal emitted through the corresponding transmit antenna 9, the input impedance of which is matched to the output impedance at the operating frequency: required power level operating frequency. Then the amplified radio signal is transmitted over the air. If necessary, to increase the energy potential (increase the reliability of information transfer), for example, several parallel transmitters operating on the corresponding number of sector antennas can be used simultaneously.

Using the control signals of the central processor 21 on the receiving side after the receiving antenna 10, which is matched in node 12 with the input impedance of the broadband amplifier 13, the radio signal is filtered out from neighboring ranges also in node 12, quantized in amplitude and sampled in time in the ADC 14 and fed to the first signal processor 15, where, in accordance with known procedures, it is demodulated, descrambled, deinterleaved, decoded with error correction, checked for errors not corrected by the decoder and in the absence of errors, they form from it in nodes 11 or 24 a message necessary for the user, for example, in accordance with ISO 8208, intended for data transmission via the X.25 protocol. To protect against fading of the radio signal (increasing the reliability of information transmission), for example, several parallel receiving antennas spaced apart in space can be used at the same time.

The central processor 21 stores complete information about its own computing, hardware capabilities and characteristics of the CA 2 and all AC 1 serviced by the system, the current state of the air and the algorithms of actions that subscribers of the system can perform.

If there is interference on the air using DS 2, it is ensured: automatic selection of the operating frequency from the list of allowed frequencies, random and redundant access to the communication channel in multiple access mode with time division, transmission of information about the assigned new operating frequency to all AC 1.

When priority messages for AS 1 are transmitted from CA 2 in accordance with the categories of urgency accepted in the system, the CA code information block in the message header is used to block the transmission of other data.

Due to the digital processing of the signals at nodes 14, 15, 16, 17 and the filter 18 in the system, each registered AC 1 guarantees the required characteristics of the radio link, namely, the probability of timely delivery of a message with a given reliability and the required message flow rate. The number N depends on the specified message duration, the data transfer rate in the radio wave propagation channel, the duration of the guard intervals that prevent overlapping information in neighboring slots. The smaller the value of the guard interval, the higher the information transfer rate and its reliability. Therefore, the synchronization of the work of all nodes of the system is based on the use of CA 2 and all AC 1 of the single global universal coordinated time (UTC) received from existing objects of the global navigation satellite system [5, 6]. The technology for organizing an accurate synchronous timeline on the CA 2 and AC 1, for example, is as follows. OTC 2 clocks are synchronized with second UTC marks on DS 2 and AC 1. These pulses are used in chroniser 6 to form time scales in each system cycle for digital signal processing, including slots, for nodes 4, 5, 11, 14 , 17, 21, 25 on CA 2 and for nodes 4, 5, 7, 14, 17, 21, 24 on AC 1. The exact synchronization of the slots used for data exchange between subscribers of the system, and their planned use for transmission and reception is known to each user.

Due to the introduction of a digital signal processing system, the following operations are ensured:

- radio communication channels are being formed;

- signals are processed and generated (operations are carried out: slot selection, encoding / decoding, modulation / demodulation and interleaving / deinterleaving, including the operations of generating four-coded signals, twofold frequency manipulation and its inverse);

- The functions of frequency conversion and filtering of radio signals are performed;

- the parameters of the two-way data exchange are controlled (the communication mode is set, the AC 1 distribution among the slots, the type of modulation and transmission frequency, frequency bandwidth, etc.);

- the output impedance of the transmitter module and the input impedance of the filter-matching device are matched with the parameters of the antenna-feeder path at all operating frequencies.

At the time of application submission, functioning algorithms have been developed. Nodes 1-11 are the same as the prototype.

Nodes can be made: node 21 - on a processor board 5066-586-133MHz-1MB, 2 MB Flash CPU Card from Octagon Systems, nodes 8, 9, 10, 13 - on commercially available products, nodes 7, 11, 24, 25 - based on, for example, a matrix of gateways programmed by fields (FPGA - Field Programmable Gate Array) using PCI technology (VME), signal processors 15, 16 - on an IC type DSP ADSP-21060 (Analog Devices), nodes 3, 4, 5, 6, 12, 18 - based on programmable logic integrated circuits (FPGAs) EPF10K50 (Altera company), AVR ATmega16 controllers (Atmel company) for monitoring and controlling the process of digital signal processing (for codec modems, filters), ADC 14 -a PMI-based company Linear Technology LTC2208 (16 bits, 130 MHz), DAC - PMI-based DAC-16FP.

The claimed invention has the following advantages:

- due to the use of digital processing together with filtering, the phase and amplitude relations between the quadrature signals I and Q are identical, the amplitude and phase of the signals I and Q are automatically corrected, which suppresses the spectral components in the idle band to minus 90 dB [5];

- information about their own computing (software), hardware capabilities and characteristics of other subscribers, the current state of the broadcast and the algorithm of actions that system subscribers can perform allow for a “flexible” programmable configuration change, make a quick transition from processing one type of signal to another with changing types modulation, coding and interleaving, depending on the parameters of the radio channel and the existing interference environment, enter programmatically through the external interface 22 but output operating conditions of the CA 2 and AC 1;

- the organization of a single synchronization in the radio network, the availability of a database of current characteristics of the system subscribers with an input for the current update of arrays and the construction of equipment based on the principles of the software performing the basic functions allows increasing the number of subscriber stations;

- the construction of equipment on the principles of the software performing the basic functions in the nodes of the system allows for the modernization of system equipment, including the introduction of new modulation, coding, interleaving, pseudo-random tuning of the operating frequency within the allocated frequency resource and other functions by reprogramming the central processors.

During the analysis of the level of modern technology, including a search by patent and scientific and technical sources of information and identifying sources containing information about analogues of the claimed invention, an analogue was not found, characterized by features identical to all the essential features of the claimed invention. The selection from the list of identified analogues of the closest in the set of essential features of the prototype allowed us to identify the set of essential distinguishing features in relation to the proposed technical solution, set forth in the claims. Therefore, the claimed invention meets the criterion of "novelty."

To verify the conformity of the claimed invention with the criterion of "inventive step", an additional search was carried out for known technical solutions in order to identify signs that match the distinctive features of the claimed invention from the prototype. The search results showed that for a specialist in the field of radio engineering the claimed invention does not follow explicitly from the prior art. Not identified technical solutions having features that match the distinctive features of the claimed invention. Therefore, the claimed invention meets the criterion of "inventive step".

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

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

- for the claimed system 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 has been confirmed;

- a tool that embodies the claimed system in its implementation, is able to ensure the achievement of the proposed technical result of the applicant.

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

Literature

1. Borisov V.A. "Radio engineering information transmission systems." - M.: Radio and Communications, 1990, p.227-232.

2. RF patent No. 2012143, IPC7 H04B 7/12, 1994.

3. RF patent No. 2240653, IPC7 H04B 7/12, 2004.

4. RF patent No. 2315428, IPC H04B 7/212, 2008 (prototype).

5. Keystovich A. V., Komyakov A. V. Radio communication systems and equipment in aviation: textbook. allowance - Nizhny Novgorod: NSTU, 2012, 236 p.

6. GPS - a global positioning system. - M .: PRIN, 1994, 76 p.

Claims (1)

A data access system with multiple access and time division of channels contains N subscriber stations (AS) and a central station (DS), each subscriber station, like the central station, contains a clock pulse generator, the output of which is simultaneously connected to the clock inputs of the information signal conditioner , a frequency synthesizer and a chronizer, the output of which is jointly connected to the control input of the information signal former and to the clock input of the AC information source with the data input of each A C, the output of which is connected to the information input of the driver of the information signal, the transmitter, the output of which is connected to the input of the transmitting antenna, a receiving antenna, and the central station also contains a combining center, N information outputs of which are N information outputs of the central station, characterized in that each subscriber station, as in the central station, the output of the receiving antenna through a series-connected filter matching device, a broadband amplifier, analog-to-digital A new converter (ADC) is connected to the information input of the first signal processor, the output of the signal generator is connected through a second signal processor, a digital-to-analog converter (DAC), the filter is connected to the input of the transmitter, the clock input of the clock generator is connected to the output of the signal receiver of global navigation satellite systems with antenna, the corresponding outputs of the chronizer are connected to the clock inputs of the first and second signal processors and synthesizer from, the corresponding outputs of the synthesizer are connected to the ADC and DAC sync inputs, the first control bus of the introduced central processor with an external input / output is connected to the corresponding inputs / outputs of a filter-matching device, a broadband amplifier, an analog-to-digital converter, the first signal processor, and the second control bus of the central processor with external input / output connected to the corresponding inputs / outputs of the driver of the information signal, the second signal processor, DAC, filter, the transmitter, synthesizer, the outputs of the chronizer are connected to the corresponding inputs of the ADC, DAC, and the central processor with an external input / output, and the information output of the first signal processor of each subscriber station is connected to the unit of the speaker system, synchronized by pulses from the corresponding output of the chronizer, the output of the unit of output is the output AS, N information inputs are the inputs of the CA and the information source of the CA, the output of which is connected to the input of the driver of the information signal to the CA, low input - to the corresponding output of the synchronizer on the CA, the first control bus of the AC central processor with external input / output is connected to the corresponding input / output of the AC combining device, and the first control bus of the central processor of the AC with external input / output is connected to the corresponding input / output of the combining device DS transmitting antennas of each speaker over the air are connected to the receiving antenna of the DS, and the transmitting DS antenna with the receiving antenna of each speaker.