RU2327285C1 - Data receipt and transmission system - Google Patents

Abstract

FIELD: information technologies.

SUBSTANCE: invention relates to the telecommunications and can be used as data receipt and transmission system (DRTS) via digital connection. It is achieved because DRTS contains operatively linked dissimilar data sources, compress binary transfer rates (BTR) and their conversion system into signal flow and inverse conversion of signal flow in flow of compressed BTR, decompression block, data users and, if required, sectoring and multi-access blocks. At that compression block is made with ability of generating in its processor of ordered, simultaneous at heartbreak of binary digits BTR and their conversion into flow of M_n symbols. Decompression block is made with the ability of simultaneous at heartbeat conversion in its processor of digital flow M_n symbols into BTR, orderly delivered, as while reading, to the users.

EFFECT: effectiveness improvement of frequency recourse usage.

2 cl, 1 dwg, 1 tbl

Description

The invention relates to communication technology, and more specifically to systems for the transmission and reception of information (SPPI) through digital communication. The growing number of operators and subscribers, including cellular communications, exacerbates the problem of rational use of the frequency resource, which, in turn, requires further development and improvement of systems and methods for transmitting and receiving information. The invention allows to increase the capacitance of any existing passive interference suppression system for a given number of frequency bands allocated for operation of the system or to provide a specified capacity of the system with a smaller number of frequency bands, i.e. save frequency resource and increase the technical and economic efficiency of communication systems, taking into account all components that affect their full cost and technical performance.

A known system for transmitting and receiving information [Radio engineering: Encyclopedia. / Ed. Yu.L. Mazora et al. - M.: Dodeka-XXI Publishing House, 2002, pp. 63-64], the features of which are implemented, in essence, in all relevant systems and which is an analogue of the proposed technical solution. This system contains functionally sequentially connected information source, physical-electrical information converter, encoder, radio transmitting device, communication channel, radio receiving device, decoder, electrophysical information converter, information consumer.

, из К_n источников информации из n-й группы источников информации, где

, подключен, в том числе при необходимости ее форматирования в цифровой поток через свой блок форматирования, не обязательно одинаковый с другими блоками форматирования, к одному из К_n входов n-го блока уплотнения, в том числе комбинационного, синхронизированных бинарных цифровых потоков, который выходом подключен ко входу системы преобразования, обеспечивающей в том числе преобразование потока уплотненных синхронизированных бинарных цифровых потоков в поток сигналов, его передачу от передатчика по крайней мере к одному приемнику через канал передачи, совместимый с передаваемым сигналом, и обратное преобразование потока сигналов в поток уплотненных синхронизированных бинарных цифровых потоков, подаваемый с выхода этой системы на вход по крайней мере одного n-го блока разуплотнения потока уплотненных синхронизированных бинарных цифровых потоков, каждый из К_n выходов которого подключен, в том числе при необходимости форматирования цифрового потока в поток информации через свой блок форматирования, не обязательно одинаковый с другими блоками форматирования, к соответствующему потребителю информации, при этом все указанные блоки и упомянутая система функционально связаны с системой синхронизации, а при необходимости в систему передачи и приема информации перед передатчиком введен блок множественного доступа, имеющий N входов для доступа синхронизированных потоков сигналов, в том числе других групп источников информации, а после приемника введен блок множественного доступа, имеющий N выходов синхронизированных потоков сигналов, в том числе для других групп потребителей информации [Скляр Бернард. Цифровая связь. Теоретические основы и практическое применение. Изд. 2-е испр.: пер. с англ. - М.: Издательский дом «Вильямс», 2004. - 1104 с. (прототип с.32-36)]. Недостатком известных СППИ и прототипа по сравнению с заявляемой СППИ является исчерпание ими возможности дальнейшего повышения их технико-экономической эффективности.The closest analogue (prototype) of the present invention is a system for transmitting and receiving information from information sources to its consumers via digital communication, in which each k-th, where

, from K _n sources of information from the n-th group of information sources, where

, is connected, including if necessary to format it into a digital stream through its formatting unit, not necessarily the same as other formatting units, to one of the K _n inputs of the nth compression unit, including combinational, synchronized binary digital streams, which is output connected to the input of the conversion system, including the conversion of the stream of compressed synchronized binary digital streams into a signal stream, its transmission from the transmitter to at least one receiver through channel compatible with the transmitted signal and the inverse transform flow signal stream multiplexed synchronized binary digital streams supplied from the output of the system to the input of at least one n-th stream demultiplexing unit densified synchronized binary digital streams, each of K _n which outputs connected, including if necessary, to format the digital stream into the information stream through its formatting unit, not necessarily the same with other formatting units, to the corresponding to the existing consumer of information, while all of these blocks and the said system are functionally connected to the synchronization system, and if necessary, a multiple access unit with N inputs for accessing synchronized signal streams, including other groups of information sources, is introduced before the transmitter in the information transmission and reception system and after the receiver a multiple access unit is introduced, having N outputs of synchronized signal streams, including for other groups of information consumers [Sklyar Bernard. Digital communication. Theoretical foundations and practical application. Ed. 2nd rev .: trans. from English - M.: Williams Publishing House, 2004. - 1104 p. (prototype p.32-36)]. A disadvantage of the known SPPI and prototype compared with the claimed SPPI is the exhaustion of the possibility of further improving their technical and economic efficiency.

The essence of the invention is aimed at increasing the technical and economic efficiency of the SISP due to the introduction of a processor compaction unit capable of producing an ordered simultaneous reading of binary digits K _{n of} synchronized binary digital streams and converting them into a stream of M _n -ary symbols, and, accordingly, introducing a decompression processor unit adapted to simultaneous production per cycle flow transformation M -ary symbols _n in K _n synchronized binary n Frova streams supplied orderly manner as in the aforementioned reading, outputs to the decompression unit.

, из К_n источников информации из n-й группы источников информации, где

, подключен, в том числе при необходимости ее форматирования в цифровой поток через свой блок форматирования, не обязательно одинаковый с другими блоками форматирования, к одному из К_n входов n-го блока уплотнения, в том числе комбинационного, синхронизированных бинарных цифровых потоков, который выходом подключен ко входу системы преобразования, обеспечивающей в том числе преобразование потока уплотненных синхронизированных бинарных цифровых потоков в поток сигналов, его передачу от передатчика по крайней мере к одному приемнику через канал передачи, совместимый с передаваемым сигналом, и обратное преобразование потока сигналов в поток уплотненных синхронизированных бинарных цифровых потоков, подаваемый с выхода системы преобразования на вход по крайней мере одного n-го блока разуплотнения потока уплотненных синхронизированных бинарных цифровых потоков, каждый из К_n выходов которого подключен, в том числе при необходимости форматирования цифрового потока в поток информации через свой блок форматирования, не обязательно одинаковый с другими блоками форматирования, к соответствующему потребителю информации, при этом все указанные блоки и упомянутая система функционально связаны с системой синхронизации, а при необходимости в систему передачи и приема информации перед передатчиком введен блок множественного доступа, имеющий N входов для доступа синхронизированных потоков сигналов, в том числе других групп источников информации, а после приемника введен блок множественного доступа, имеющий N выходов синхронизированных потоков сигналов, в том числе для других групп потребителей информации, в соответствии с настоящим изобретением n-й блок уплотнения выполнен с возможностью производства в его процессоре упорядоченного, например последовательного от 1 до K_n, одновременного за такт считывания двоичных цифр K_n синхронизированных бинарных цифровых потоков и их преобразования в n-й поток М_n-арных символов, где

, соответственно, n-й блок разуплотнения выполнен с возможностью одновременного за такт преобразования в его процессоре n-го потока М_n-арных символов в К_n синхронизированных бинарных цифровых потоков, подаваемых упорядоченно, как при упомянутом считывании, к выходам n-го блока разуплотнения, при этом процессор блока уплотнения имеет по крайней мере К_n входов, являющихся упомянутыми входами подключения блока уплотнения, и по крайней мере один выход, являющийся упомянутым выходом подключения к упомянутой системе преобразования, и процессор блока разуплотнения имеет по крайней мере один вход, являющийся упомянутым входом подключения блока разуплотнения к упомянутой системе преобразования, и по крайней мере К_n выходов, являющихся упомянутыми выходами подключения блока разуплотнения, а упомянутая система преобразования выполнена в том числе с возможностью преобразования потока М_n-арных символов в поток сигналов и обратного преобразования потока сигналов в поток М_n-арных символов.To achieve the specified technical result in the system of transmitting and receiving information from information sources to its consumers through digital communication, in which every k-th, where

, from K _n sources of information from the n-th group of information sources, where

, is connected, including if necessary to format it into a digital stream through its formatting unit, not necessarily the same as other formatting units, to one of the K _n inputs of the nth compression unit, including combinational, synchronized binary digital streams, which is output connected to the input of the conversion system, including the conversion of the stream of compressed synchronized binary digital streams into a signal stream, its transmission from the transmitter to at least one receiver through channel compatible with the transmitted signal and the inverse transform flow signal stream multiplexed synchronized binary digital streams supplied from the output of the conversion system to the input of at least one n-th stream demultiplexing unit densified synchronized binary digital streams, each of K _n which outputs connected, including if necessary, formatting the digital stream into the information stream through its formatting unit, not necessarily the same with other blocks formatted I, to the relevant consumer of information, while all of the indicated blocks and the mentioned system are functionally connected to the synchronization system, and if necessary, a multiple access unit with N inputs for accessing synchronized signal streams, including others, is inserted in front of the transmitter in the information transmission and reception system groups of information sources, and after the receiver, a multiple access unit is introduced, having N outputs of synchronized signal streams, including for other groups of information consumers, in In accordance with the present invention, the nth compression unit is configured to produce in its processor an ordered, for example sequential from 1 to K _n , synchronized binary digital streams at a time for reading binary digits K _n and converting them into the nth stream M _n -ary characters where

accordingly, the nth decompression unit is capable of simultaneously converting the nth stream of M _n -ary symbols into K _n synchronized binary digital streams in its processor at the same time as the reading, to the outputs of the nth decompression unit wherein, the processor of the seal unit has at least K _n inputs, which are said inputs of the connection of the seal unit, and at least one output, which is said output of the connection to said conversion system, and a process p of the decompression unit has at least one input, which is the said input of the connection of the decompression unit to the said conversion system, and at least K _n outputs, which are the mentioned outputs of the connection of the decompression unit, and the said conversion system is also configured to convert the stream M _n -ary symbols into a signal stream and the inverse transformation of the signal stream into a stream of M _n -ary symbols.

In addition, at least one additional transmission channel of at least information on the reference levels of M _n -ary signals has been introduced in the AISS.

In the current level of technology, no sources of information have been identified that would contain information about objects of the same purpose with the indicated set of distinctive features, which allows us to consider the SPPI of the present invention as new and having an inventive step.

The SPDI of the present invention can be embodied in a device, a block diagram of which is shown in the drawing.

In the drawing, the numbers of the digital streams of information sources entering the compaction unit and exiting the decompression unit are enclosed in brackets. Similarly, in brackets are numbers of digital streams of groups of information sources entering the multiple access unit on the transmitting side of the system and leaving the multiple access unit on the receiving side of the system.

Compared with generally known systems of the prior art, in the inventive SPPI, processors are introduced into the compaction and decompression units using well-known decision circuits and allowing, using appropriate software, to increase the technical and economic efficiency of the known systems.

, из К_n источников информации 1 из n-й группы источников информации, где

, подключен, в том числе при необходимости ее форматирования в цифровой поток через свой блок форматирования 3, не обязательно одинаковый с другими блоками форматирования, к одному из К_n входов 4 n-го блока уплотнения 5 синхронизированных бинарных цифровых потоков, который выходом 6 подключен ко входу 7 системы преобразования 8, обеспечивающей в том числе преобразование потока уплотненных синхронизированных бинарных цифровых потоков в поток сигналов, его передачу от передатчика 9 по крайней мере к одному приемнику 10 через канал передачи 11, совместимый с передаваемым сигналом, и обратное преобразование потока сигналов в поток уплотненных синхронизированных бинарных цифровых потоков, подаваемый с выхода 12 этой системы на вход 13 по крайней мере одного n-го блока разуплотнения 14 потока уплотненных синхронизированных бинарных цифровых потоков, каждый из K_n выходов 15 которого подключен, в том числе при необходимости форматирования цифрового потока в поток информации через свой блок форматирования 16, не обязательно одинаковый с другими блоками форматирования, к соответствующему потребителю информации 2, при этом все указанные блоки и упомянутая система функционально связаны с системой синхронизации 17. При необходимости в систему передачи и приема информации перед передатчиком введен блок множественного доступа 18, имеющий N входов 19 для доступа синхронизированных потоков сигналов, в том числе других групп источников информации, а после приемника 10 введен блок множественного доступа 20, имеющий N выходов 21 синхронизированных потоков сигналов, в том числе для других групп потребителей информации. В СППИ n-й блок уплотнения 5 выполнен с возможностью производства в его процессоре 22 упорядоченного, например последовательного от 1 до К_n, одновременного за такт считывания двоичных цифр К_n синхронизированных бинарных цифровых потоков и их преобразования в n-й поток М_n-арных символов, где

. Соответственно, n-й блок разуплотнения 14 выполнен с возможностью одновременного за такт преобразования в его процессоре 23 n-го потока М_n-арных символов в К_n синхронизированных бинарных цифровых потоков, подаваемых упорядоченно, как при упомянутом считывании, к выходам 15 n-го блока разуплотнения 14. При этом процессор 22 блока уплотнения 5 имеет по крайней мере K_n входов 24, являющихся упомянутыми входами 4 подключения блока уплотнения 5, и по крайней мере один выход 25, являющийся упомянутым выходом 6 подключения к упомянутой системе преобразования 8. Процессор 23 блока разуплотнения 14 имеет по крайней мере один вход 26, являющийся упомянутым входом 13 подключения блока разуплотнения 14 к упомянутой системе преобразования 8, и по крайней мере К_n выходов 27, являющихся упомянутыми выходами 15 подключения блока разуплотнения 14. Система преобразования 8 выполнена в том числе с возможностью преобразования потока M_n-арных символов в поток сигналов и обратного преобразования потока сигналов в поток M_n-арных символов.In the system of transmitting and receiving information from information sources 1 to its consumers 2 through digital communication, each k-th, where

, from K _n information sources 1 from the n-th group of information sources, where

is connected, including if necessary to format it into a digital stream through its formatting unit 3, which is not necessarily the same as other formatting units, to one of the K _n inputs 4 of the nth compression unit 5 of synchronized binary digital streams, which output 6 is connected to the input 7 of the conversion system 8, which provides, among other things, the conversion of the stream of compressed synchronized binary digital streams into a signal stream, its transmission from the transmitter 9 to at least one receiver 10 via the transmission channel 11, s Capacity with the transmitted signal and the inverse signal stream conversion into a stream multiplexed synchronized binary digital streams supplied from the output 12 of the system at entrance 13 of at least one n-th stream demultiplexer 14 the block of compacted synchronized binary digital streams, each of K _n outputs 15 which is connected, including if necessary, to format the digital stream into the information stream through its formatting unit 16, not necessarily the same with other formatting units, to the corresponding the consumer of information 2, while all of these blocks and the aforementioned system are functionally connected to the synchronization system 17. If necessary, a multiple access unit 18 having N inputs 19 for accessing synchronized signal streams, including other groups, is introduced in front of the transmitter to the information transmission and reception system sources of information, and after the receiver 10, a multiple access unit 20 is introduced, having N outputs 21 of synchronized signal streams, including for other groups of information consumers. In SPPI, the nth compaction unit 5 is configured to produce in its processor 22 an ordered, for example sequential from 1 to K _n , simultaneous clock reading binary digits K _{n of} synchronized binary digital streams and converting them into the nth stream M _n -ary characters where

. Accordingly, the nth decompression unit 14 is capable of simultaneously converting, at its processor 23, the nth stream of M _n -ary symbols into K _n synchronized binary digital streams supplied in orderly, as in the said reading, to outputs 15 of the nth 14. in this case, the decompression unit processor 22 compression unit 5 has at least 24 K _n inputs, the inputs are referred to 4 connecting seal unit 5, and at least one outlet 25, which said output connection 6 to said transformation system 8. The processor 23 Ia decompression unit 14 has at least one inlet 26, said inlet 13 being connecting the decompression unit 14 to said conversion system 8, and at least K _n outputs 27, 15 are mentioned connecting outputs decompression unit 14. Conversion System 8 is made including the possibility of converting the stream of M _n -ary symbols into a signal stream and the inverse transformation of the signal stream into a stream of M _n -ary symbols.

, из К_n источников информации 1 из n-й группы источников информации, где

, подают, в том числе при необходимости через свой блок форматирования 3, не обязательно одинаковый с другими блоками форматирования, в котором информацию форматируют в цифровой поток, к одному из K_n входов 4 n-го блока уплотнения 5, соединенного с одним из входов процессора 22. В процессоре 22 n-го блока уплотнения 5 упорядоченно, например последовательно от 1 до К_n, одновременно за такт считывают двоичные цифры K_n синхронизированных бинарных цифровых потоков, поступающих в процессор через К_n входов 24, и преобразуют их в n-й поток M_n-арных символов, где

, подаваемый с выхода 25 процессора, являющегося упомянутым выходом 6 блока уплотнения 5, ко входу 7 системы преобразования 8. В системе преобразования 8 в том числе преобразуют поток уплотненных синхронизированных бинарных цифровых потоков в поток сигналов. Этот поток сигналов передают через передатчик 9 по крайней мере к одному приемнику 10 через канал передачи 11, совместимый с передаваемым сигналом (низкочастотным, высокочастотным или оптическим), и преобразуют в обратном порядке поток сигналов в поток уплотненных синхронизированных бинарных цифровых потоков. Далее этот поток подают с выхода 12 системы преобразования 8 на вход 13 по крайней мере одного n-го блока разуплотнения 14, соединенного со входом 26 процессора 23. В процессоре 23 n-го блока разуплотнения 14 одновременно за такт преобразуют n-й поток M_n-арных символов в К_n синхронизированных бинарных цифровых потоков, подаваемых с выходов 27 процессора, являющихся упомянутыми выходами 15 блока разуплотнения 14, в том числе при необходимости к своим блокам форматирования 16, не обязательно одинаковым с другими блоками форматирования. В блоках 16 цифровые потоки форматируют в информацию, которую направляют к соответствующим потребителям информации 2. При этом производят синхронизацию функционирования всех указанных блоков и упомянутой системы преобразования 8. При необходимости в системе преобразования 8 перед передатчиком 9 суммируют синхронизированные потоки сигналов в блоке множественного доступа 18, имеющем N входов 19 для доступа в том числе других групп источников информации, а после приемника 10 разделяют синхронизированные потоки сигналов в блоке множественного доступа 20, имеющем N выходов 21, в том числе для других групп потребителей информации.The system operates as follows. Information of every k-th, where

, from K _n information sources 1 from the n-th group of information sources, where

, fed, including if necessary through its formatting unit 3, not necessarily the same as other formatting units, in which the information is formatted into a digital stream, to one of the K _n inputs 4 of the n-th block of the seal 5 connected to one of the inputs of the processor 22. In the processor 22 of the nth compaction block 5 in an orderly manner, for example sequentially from 1 to K _n , at the same time, binary digits K _{n of} synchronized binary digital streams entering the processor through K _n inputs 24 are read per clock and converted to the nth stream of M _n -ary symbols where

supplied from the output 25 of the processor, which is the mentioned output 6 of the seal unit 5, to the input 7 of the conversion system 8. In the conversion system 8, the stream of compressed synchronized binary digital streams is also converted into a signal stream. This signal stream is transmitted through the transmitter 9 to at least one receiver 10 via a transmission channel 11 compatible with the transmitted signal (low-frequency, high-frequency or optical), and the signal stream is converted in the reverse order to a stream of compressed synchronized binary digital streams. Further, this stream is fed from the output 12 of the conversion system 8 to the input 13 of at least one nth decompression unit 14 connected to the input 26 of the processor 23. In the processor 23 of the nth decompression unit 14, the nth stream M _{n is} simultaneously converted per cycle -ary symbols in K _n synchronized binary digital streams supplied from the outputs 27 of the processor, which are the mentioned outputs 15 of the decompression unit 14, including, if necessary, to their formatting units 16, not necessarily the same with other formatting units. In blocks 16, the digital streams are formatted into information that is sent to the corresponding consumers of information 2. In this case, the operation of all these blocks and the mentioned conversion system 8 are synchronized. If necessary, the synchronized signal streams in the multiple access unit 18 are summed in front of the transmitter 9, having N inputs 19 for access, including other groups of information sources, and after the receiver 10, synchronized signal streams in the multiple access 20 having N outputs 21, including information for other groups of users.

To increase the reliability of the system, it is advisable to transmit information about the reference, for example, single, levels of M _n -ary signals. It can be transmitted, for example, after several clock cycles on the main channel. However, in some cases, it may be advisable to use an additional channel to transmit this and other information necessary for the organization of the system.

Therefore, at least information about the reference levels of M _n -ary signals is transmitted through at least one additional transmission channel.

In the processor of the compaction unit, at each clock cycle (i.e., simultaneously), information from K _n sources is orderly read. Note that each information channel can carry information of any kind, for example, encoded by any code or a mixture of codes. The read information is converted into a stream of M _n -ary symbols. In the processor of a decompression unit, at the same time, a stream of M _n -ary symbols is restored (decompressed) to K _n synchronized binary digital streams and fed them in an orderly manner, as when reading in the processor of the compaction unit, to K _n consumers in a convenient form. In the invention, in the compaction and decompression units, a method relating to the number of combination combining and decompression methods of channels [Kharkevich A.A. Essays on the general theory of communication. M .: Gostekhizdat, 1955, § 53].

All blocks of this SPPI can be made the same as in the closest analogue or in other systems of the same purpose. The timing and synchronization issues of the transmitting and receiving sides of the system used are solved by any means well known in the art, for example, in the same way as in the prototype. In some cases, it is sufficient to use one decompression unit, from each output of which information is sent to the corresponding consumer of information. In some cases, two or more, up to K _n , decompression blocks can be used. For example, in cellular communications, each mobile station includes a decompression unit. From the stream of M _n -ary symbols entering this block, a binary digital stream is allocated that is currently addressed only to this consumer. Thus, in cellular communications, the signal flow is delivered to all consumers, and the decompression procedure is performed by each final destination.

Below is a table illustrating the transmission and reception of three streams of text information in the inventive system:

The table in columns 1, 3, 5 shows the streams of textual information of three sources: (Hertz • - -) (Popov • -) (Siemens •).

Columns 2, 4, 6 show the corresponding binary digital streams. Column 7 shows the stream of M _n -ary symbols transmitted from the bottom up received in the processor 22 of the compression unit 5 by ordering, sequentially from the first to the third stream, simultaneously reading the binary digits of binary digital streams and converting them into the specified stream of characters. Columns 8, 10, 12 show the results of the simultaneous conversion of the stream of M _n -ary symbols into three binary digital streams in the processor 23 of the decompression unit 14 into three binary digital streams, which are supplied in an orderly manner, as in the aforementioned reading, to the outputs of the decompression unit and then distributed to the corresponding consumers of information . Columns 9, 11, 13 show the streams of text information received by the recipients. The following is indicated in the table: • - dot, - - space, ⇒ - sign of ordered tick-by-word reading of binary digits of binary digital streams and their conversion to a stream of M _n -ary characters and its inverse conversion to binary digital streams.

This simplest possible example of the use of the claimed SPSI clearly shows the possibility of simultaneous transmission and reception of three streams of text information on one channel, which increases the efficiency of using the frequency resource.

The present invention is useful in that it can be practically applied to develop and improve any digital communication system with any organization of its work, for example, already using well-known multiple access methods (for example, with frequency, time, code, spatial and polarization separation) and known signal processing methods, including, for example, for all known cellular standards.

Industrial applicability. The present invention can be applied in SISP using low-frequency, high-frequency and optical signals in any communication systems. SPPI according to this invention allows you to effectively use the frequency resource and can work simultaneously with a large number of heterogeneous information.

The analysis made it possible to establish: analogues with a set of features identical to all the features of the claimed technical solution are absent, which indicates the conformity of the claimed system to the “novelty” condition.

The search results for well-known solutions in the field of API for the purpose of identifying features that match the distinctive features of the claimed system from the prototype have shown that they do not follow explicitly from the prior art. Therefore, the claimed invention meets the condition of patentability "inventive step".

Claims (2)

1. The system of transmitting and receiving information from information sources to its consumers through digital communication, in which every k-th, where

from K _n information sources from the n-th group of information sources, where

, connected, including, if necessary, its formatting into a digital stream through its formatting unit, not necessarily the same as other formatting units, to one of the K _n inputs of the nth compression unit, including combinational, synchronized binary digital streams, which the output is connected to the input of the conversion system, which provides, among other things, the conversion of the stream of compressed synchronized binary digital streams into the signal stream, its transmission from the transmitter to at least one receiver through channel compatible with the transmitted signal and the inverse signal stream conversion into a stream multiplexed synchronized binary digital streams supplied from the output of the conversion system to the input of at least one n-th stream demultiplexing unit densified synchronized binary digital streams, each of K _n which outputs connected, including, if necessary, formatting the digital stream into the information stream through its formatting unit, not necessarily the same with other blocks formatted I, to the relevant consumer of information, while all of the indicated blocks and the mentioned system are functionally connected to the synchronization system, and if necessary, a multiple access unit with N inputs for accessing synchronized signal flows, including others, is included in the information transmission and reception system in front of the transmitter groups of information sources, and after the receiver, a multiple access unit is included, having N outputs of synchronized signal streams, including for other groups of information consumers, from ichayuschayasya in that the n-th block is executed on the processor seal to perform an orderly, sequential e.g. from 1 to K _n, for simultaneous reading clock K _n binary digits synchronized binary digital streams and converting them to n-th stream of symbols M _n -x where

accordingly, the nth decompression unit is capable of simultaneously converting the nth stream of M _n symbols into K _n synchronized binary digital streams in its processor at its processor, supplied in an orderly manner, as in the above reading, to the outputs of the nth decompression unit, wherein the processor seal block has at least K _n inputs, the said inputs are connect seal unit and at least one output, said output being the connection to said conversion system, and a processor unit decompressor has at least one input being block connecting said inlet to said decompression conversion system, and at least K _n outputs, which are output by said connecting decompression unit, and said conversion system is constructed including stream to convert M _n -x characters in the signal stream and the inverse transformation of the signal stream into a stream of M _n characters. 2. The system according to claim 1, characterized in that at least one additional transmission channel of at least information about the reference levels M _n signals is introduced for organizing the operation of the system.