RU2340107C1 - Method of transmitting and receiving information in direct and reverse directions - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: on the transmitting sides of a direct and reverse directed information source, if necessary binary digital streams are generated, compressed in compression units, for example with time division, and modulated in high frequency modulators, and converted to signal streams. On the receiving sides in the reverse order, signal streams are demodulated in high frequency demodulators, converted to compressed binary digital streams, decompressed in corresponding decompression units, formatted, if necessary and transmitted to information users. If necessary on the transmitting sides, signal streams of other groups of information sources are summed up, and on the receiving sides they are divided in multiple access units. In the forward direction in front of the modulator, simultaneously after one cycle, in the compression unit, binary digits of the binary digital streams are read out and converted to a stream of M_n symbols, and respectively after the demodulator, in the decompression unit, after one cycle, the M_n stream of symbols is simultaneously converted to binary digital stream, transmitted in the same order as during reading out, to users.

EFFECT: increased efficiency of using frequency response, simplification of the process of providing for electromagnetic compatibility, such as in systems of short-range navigation and GSM-900 networks.

2 cl, 2 dwg, 1 tbl

Description

The invention relates to communication technology, and more specifically to methods of transmitting and receiving information (PPI) in the forward and reverse directions through digital communication. The increase in the 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 the methods of IPP. The invention allows to increase the capacity of any existing system for transmitting and receiving information (SISP) for a given number of frequency bands allocated for operation or to provide a given capacity of SPSI with a smaller number of frequency bands, i.e. to save the frequency resource and increase the technical and economic efficiency of communication systems, taking into account all the components that affect their full cost and technical indicators.

A known method of 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 methods and which is an analogue of the proposed technical solution. In this method, the source information is sequentially converted into a message in the physicoelectric information converter, encoded in an encoder, in the radio transmitter, the carrier frequency is encoded by a message and a signal is sent via the communication channel, a signal is received in the radio receiver, it is demodulated, it is decoded and the electrophysical inverse is performed transformation of the message of information in a form convenient for the consumer.

, из L_k источников информации подают, в том числе, при необходимости, через свой блок форматирования, в котором информацию форматируют в цифровой поток, к одному из L_k входов блока уплотнения синхронизированных бинарных цифровых потоков, например, с временным разделением, а с одного k-того, где

, выхода блока уплотнения цифровой поток, принадлежащий n-той группе источников информации, где

, подают на вход модулятора высокочастотного сигнала, снабженного генератором несущей частоты, с выхода этого модулятора поток сигналов передают к передатчику прямого направления, а от него по крайней мере к одному приемнику прямого направления через канал передачи, совместимый с передаваемым высокочастотным сигналом, принятый поток сигналов подают на вход демодулятора высокочастотного сигнала, с выхода демодулятора цифровой поток подают, в том числе, при необходимости, через блок разуплотнения с одним k-тым входом и L_k выходами, в котором разуплотняют синхронизированный цифровой поток, и через свои блоки форматирования, в которых цифровые потоки форматируют в информацию, к соответствующим l-тым потребителям информации, при этом в обратном направлении информацию каждого l-того источника информации подают, при необходимости, через свой блок форматирования, в котором информацию форматируют в цифровой поток, к одному из L_k входов блока уплотнения синхронизированных бинарных цифровых потоков, например, с временным разделением, а с его k-того выхода на вход модулятора высокочастотного сигнала, снабженного генератором выделенной источнику информации несущей частоты, с выхода этого модулятора поток сигналов передают к передатчику обратного направления, а от него к приемнику обратного направления через канал передачи, совместимый с передаваемым высокочастотным сигналом, принятый поток сигналов подают на вход демодулятора высокочастотного сигнала, с выхода демодулятора цифровой поток подают, в том числе, при необходимости, через блок разуплотнения с одним k-тым входом и L_k выходами, в котором разуплотняют синхронизированный цифровой поток, и через свой блок форматирования, в котором цифровой поток форматируют в информацию, к соответствующему l-тому потребителю информации, причем производят синхронизацию функционирования всех указанных блоков, а при необходимости обеспечения множественного доступа, например, с кодовым разделением, в системе передачи и приема информации перед передатчиками прямого и обратного направлений умножают модулированный сигнал

на кодовый сигнал g_n(t) в умножителях, причем кодовые функции {g_n(t)} задают взаимно ортогональными или возможно более близкими к ним, и в блоках множественного доступа, имеющих N входов для доступа потоков сигналов g_n(t)s_n(t), в том числе, других групп источников информации, их суммируют, а после приемников прямого и обратного направлений в блоках множественного доступа, имеющих N выходов синхронизированных потоков сигналов, в том числе, для других групп потребителей информации, принятый сигнал

умножают на каждый n-тый из N кодовых сигналов g_n(t) и выделяют каждый n-тый сигнал g_n ²(t)s_n(t), который подают на вход соответствующего демодулятора сигнала [прототип: 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, 782-783)].The closest analogue (prototype) of the present invention is a method for transmitting and receiving information in the forward and reverse directions from information sources to its consumers via digital communication, in which the information of each l -th one, where

, from L _k information sources are fed, including, if necessary, through their formatting unit, in which information is formatted into a digital stream, to one of the L _k inputs of the compression unit of synchronized binary digital streams, for example, with time division, and from one k-where

the output of the compaction unit, a digital stream belonging to the nth group of information sources, where

, fed to the input of a high-frequency signal modulator equipped with a carrier frequency generator, from the output of this modulator, the signal stream is transmitted to the forward direction transmitter, and from it to at least one forward direction receiver through a transmission channel compatible with the transmitted high-frequency signal, the received signal stream is supplied a digital stream is fed to the input of the high-frequency signal demodulator from the demodulator output, including, if necessary, through a decompression unit with one k-th input and L _k outputs, in which ohms, the synchronized digital stream is decompressed, and through its formatting units, in which the digital streams are formatted into information, to the corresponding l-th information consumers, while in the opposite direction, the information of each l-th information source is supplied, if necessary, through its format unit, wherein the information is formatted into a bit stream to one of the sealing unit L _k binary inputs synchronized digital streams, for example, time division, and its k-order output at the modulator input high of an arbitrary signal, equipped with a generator of a carrier frequency information allocated to the source, the signal stream is transmitted from the output of this modulator to the transmitter of the reverse direction, and from it to the receiver of the reverse direction through a transmission channel compatible with the transmitted high-frequency signal, the received signal stream is fed to the input of the high-frequency signal demodulator, the digital stream is supplied from the output of the demodulator, including, if necessary, through a decompression unit with one k-th input and L _k outputs, in which the blue a synchronized digital stream, and through its formatting unit, in which the digital stream is formatted into information, to the corresponding l-th consumer of information, moreover, synchronize the functioning of all these blocks, and if necessary, provide multiple access, for example, with code division, in the transmission system and receiving information in front of the forward and reverse transmitters multiply the modulated signal

to the code signal g _n (t) in the multipliers, and the code functions {g _n (t)} are set to be mutually orthogonal or possibly closer to them, and in multiple access blocks having N inputs for accessing the signal flows g _n (t) s _n (t), including other groups of information sources, they are summed, and after the receivers of the forward and reverse directions in multiple access blocks having N outputs of synchronized signal flows, including for other groups of information consumers, the received signal

multiply by each nth of the N code signals g _n (t) and select each nth signal g _n ² (t) s _n (t), which is fed to the input of the corresponding signal demodulator [prototype: 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, 782-783)].

A disadvantage of the known methods of PPI and prototype compared with the claimed method is the exhaustion of the possibility of further improving their technical and economic efficiency.

, соответственно после демодулятора во введенном, в том числе, дополнительно, блоке разуплотнения с одним n-тым входом и К_n выходами, одновременно за такт преобразуют синхронизированный цифровой поток М_n-арных символов, подаваемых с M_n-арного демодулятора, в К_n синхронизированных бинарных цифровых потоков, которые подают упорядоченно, как при упомянутом считывании, к выходам введенного блока разуплотнения.The essence of the invention is aimed at increasing the technical and economic efficiency of the PPI method due to the fact that in a system for transmitting and receiving information in the forward direction in front of a high-frequency modulator, the signal is inserted, including, in addition, the compression unit of k-th synchronized digital streams with K _n inputs and with one nth output in order, for example, sequentially from 1 to K _n , at the same time, binary digits K _{n of} synchronized binary digital streams are read per clock and converted to the nth stream of M _n -ary symbols in where

respectively, after the demodulator in the introduced, including additional, decompression unit with one n-th input and K _n outputs, simultaneously synchronized digital stream of M _n -ary symbols supplied from M _n- ary demodulator is converted to K _n per cycle synchronized binary digital streams, which are supplied in an orderly manner, as in the aforementioned reading, to the outputs of the introduced decompression unit.

, из L_k источников информации подают, в том числе, при необходимости, через свой блок форматирования, в котором информацию форматируют в цифровой поток, к одному из L_k входов блока уплотнения синхронизированных бинарных цифровых потоков, например, с временным разделением, а с одного k-того, где

, выхода блока уплотнения цифровой поток, принадлежащий n-той группе источников информации, где

, подают на вход модулятора высокочастотного сигнала, снабженного генератором несущей частоты, с выхода этого модулятора поток сигналов передают к передатчику прямого направления, а от него по крайней мере к одному приемнику прямого направления через канал передачи, совместимый с передаваемым высокочастотным сигналом, принятый поток сигналов подают на вход демодулятора высокочастотного сигнала, с выхода демодулятора цифровой поток подают, в том числе, при необходимости, через блок разуплотнения с одним k-тым входом L_k выходами, в котором разуплотняют синхронизированный цифровой поток, и через свои блоки форматирования, в которых цифровые потоки форматируют в информацию, к соответствующим l-тым потребителям информации, при этом в обратном направлении информацию каждого l-того источника информации подают, при необходимости, через свой блок форматирования, в котором информацию форматируют в цифровой поток, к одному из L_k входов блока уплотнения синхронизированных бинарных цифровых потоков, например, с временным разделением, а с его k-того выхода на вход модулятора высокочастотного сигнала, снабженного генератором выделенной источнику информации несущей частоты, с выхода этого модулятора поток сигналов передают к передатчику обратного направления, а от него к приемнику обратного направления через канал передачи, совместимый с передаваемым высокочастотным сигналом, принятый поток сигналов подают на вход демодулятора высокочастотного сигнала, с выхода демодулятора цифровой поток подают, в том числе, при необходимости, через блок разуплотнения с одним k-тым входом и 4 выходами, в котором разуплотняют синхронизированный цифровой поток, и через свой блок форматирования, в котором цифровой поток форматируют в информацию, к соответствующему l-тому потребителю информации, причем производят синхронизацию функционирования всех указанных блоков, а при необходимости обеспечения множественного доступа, например, с кодовым разделением, в системе передачи и приема информации перед передатчиками прямого и обратного направлений умножают модулированный сигнал

на кодовый сигнал g_n(t) в умножителях, причем кодовые функции {g_n(t)} задают взаимно ортогональными или возможно более близкими к ним, и в блоках множественного доступа, имеющих N входов для доступа потоков сигналов g_n(t)s_n(t), в том числе, других групп источников информации, их суммируют, а после приемников прямого и обратного направлений в блоках множественного доступа, имеющих N выходов синхронизированных потоков сигналов, в том числе, для других групп потребителей информации, принятый сигнал

умножают на каждый n-тый из N кодовых сигналов g_n(t) и выделяют каждый n-тый сигнал g_n ²(t)s_n(t), который подают на вход соответствующего демодулятора сигнала, в соответствии с настоящим изобретением в системе передачи и приема информации в прямом направлении перед модулятором высокой частоты сигнал во введенном, в том числе, дополнительно, блоке уплотнения k-тых синхронизированных цифровых потоков с К_n входами и одним n-тым выходом упорядоченно, например, последовательно от 1 до K_n, одновременно за такт считывают двоичные цифры К_n синхронизированных бинарных цифровых потоков и преобразуют их в n-тый поток М_n-арных символов, где

, соответственно после демодулятора во введенном, в том числе, дополнительно, блоке разуплотнения с одним n-тым входом и К_n выходами одновременно за такт преобразуют синхронизированный цифровой поток М_n-арных символов, подаваемых с М_n-арного демодулятора, в К_n синхронизированных бинарных цифровых потоков, которые подают упорядоченно, как при упомянутом считывании, к выходам введенного блока разуплотнения.To achieve the specified technical result in the method of transmitting and receiving information in the forward and reverse directions from information sources to its consumers through digital communication, in which the information of each l -th one in the forward direction is, where

, from L _k information sources are fed, including, if necessary, through their formatting unit, in which information is formatted into a digital stream, to one of the L _k inputs of the compression unit of synchronized binary digital streams, for example, with time division, and from one k-where

the output of the compaction unit, a digital stream belonging to the nth group of information sources, where

, fed to the input of a high-frequency signal modulator equipped with a carrier frequency generator, from the output of this modulator, the signal stream is transmitted to the forward direction transmitter, and from it to at least one forward direction receiver through a transmission channel compatible with the transmitted high-frequency signal, the received signal stream is supplied RF demodulator input signal from the output of the demodulator is fed the digital stream, including, if necessary, through the decompression unit with one k-fifth input L _k outputs, wherein decompress the synchronized digital stream, and through their formatting units, in which the digital streams are formatted into information, to the corresponding l-th information consumers, while in the opposite direction, the information of each l-th information source is fed, if necessary, through its formatting block, to which information is formatted into a digital stream, to one of the L _k inputs of the compression unit of synchronized binary digital streams, for example, with time division, and from its k-th output to the input of the modulator a frequency signal equipped with a generator of a carrier frequency information allocated to the source, from the output of this modulator the signal stream is transmitted to the reverse transmitter, and from it to the reverse receiver through a transmission channel compatible with the transmitted high-frequency signal, the received signal stream is fed to the input of the high-frequency signal demodulator, the digital stream is supplied from the output of the demodulator, including, if necessary, through a decompression unit with one k-th input and 4 outputs, in which the synchronization is decompressed a lowered digital stream, and through its formatting unit, in which the digital stream is formatted into information, to the corresponding l-th consumer of information, moreover, synchronize the functioning of all these blocks, and if necessary, provide multiple access, for example, with code division, in the transmission system and receiving information in front of the forward and reverse transmitters multiply the modulated signal

to the code signal g _n (t) in the multipliers, and the code functions {g _n (t)} are set to be mutually orthogonal or possibly closer to them, and in multiple access blocks having N inputs for accessing the signal flows g _n (t) s _n (t), including other groups of information sources, they are summed, and after the receivers of the forward and reverse directions in multiple access blocks having N outputs of synchronized signal flows, including for other groups of information consumers, the received signal

multiply by every nth of N code signals g _n (t) and each n-th signal g _n ² (t) s _n (t) is extracted, which is supplied to the input of the corresponding signal demodulator, in accordance with the present invention in a transmission system and receiving information in the forward direction in front of the high-frequency modulator, the signal in the inserted, including, additionally, compression unit of k-th synchronized digital streams with K _n inputs and one n-th output is ordered, for example, sequentially from 1 to K _n , simultaneously per clock read binary digits _n To synchronize nnyh binary digital streams and convert them into a stream of n-th M _n -ary symbols where

respectively, after the demodulator in the introduced, including, additionally, decompression unit with one nth input and K _n outputs, at the same time, a synchronized digital stream of M _n -ary symbols supplied from M _n- ary demodulator is converted to K _n synchronized binary digital streams, which are supplied in an orderly manner, as in the aforementioned reading, to the outputs of the introduced decompression unit.

In addition, in the forward and reverse directions, at least information about the reference levels of M _n -ary signals is transmitted through at least one additional transmission channel.

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 specified set of distinctive features, which allows us to consider the PPI method of the present invention as new and having an inventive step.

The PPI method of the present invention can be embodied in a device whose block diagrams are shown in FIG. 1 (implementation of the prototype method) and FIG. 2 (implementation of the inventive method).

In the figures, the numbers in the digital streams of groups of information sources entering the multiple access blocks on the transmitting sides of the system and leaving the multiple access blocks on the receiving sides of the system are enclosed in parentheses.

In the inventive method, the PPI, in comparison with the well-known from the prior art, is introduced in the forward direction, in addition, additionally, to the compaction unit, the binary digits K _{n of} synchronized binary digital streams are ordered at the same time per clock and converted into a stream of M _n -ary symbols and, respectively, in the input, including, optionally, the demodulator after decompression unit simultaneously per cycle is converted stream M -ary symbols _n in K _n synchronized digital binary streams, which are ayut orderly manner as in the aforementioned reading, outputs to the decompression unit. These actions allow using appropriate software to provide an increase in the technical and economic efficiency of known systems.

, из L_k источников информации из n-той группы источников информации, где

, подключен, в том числе, при необходимости через свой блок форматирования 3 информации в цифровой поток и блок уплотнения 4, например, с временным разделением, синхронизированных бинарных цифровых потоков с L_k входами 5 и одним выходом 6 k-того, где

, цифрового потока к модулятору высокочастотного сигнала 7, снабженному генератором несущей частоты 8 и соединенному с передатчиком прямого направления 9. Последний функционально связан через канал передачи 10, совместимый с передаваемым высокочастотным сигналом, по крайней мере с одним приемником прямого направления 11, который подключен через демодулятор высокочастотного сигнала 12 и, при необходимости, через блок разуплотнения 13 синхронизированного цифрового потока с одним входом 14 и L_k выходами 15 и свой блок форматирования 16 цифрового потока в информацию к соответствующему потребителю информации 2. При этом в обратном направлении каждый из источников информации 17 подключен, при необходимости, через свой блок форматирования 18 информации в цифровой поток и блок уплотнения 19, например, с временным разделением, синхронизированных бинарных цифровых потоков с L_k входами 20 и выходом 21 к модулятору высокочастотного сигнала 22, снабженному генератором 23 выделенной источнику информации несущей частоты и соединенному с передатчиком обратного направления 24. Последний функционально связан через канал передачи 10, совместимый с передаваемым высокочастотным сигналом, с приемником обратного направления 25, который подключен через демодулятор высокочастотного сигнала 26 и, в том числе, при необходимости, через блок разуплотнения 27 синхронизированного цифрового потока с одним входом 28 и L_k выходами 29 и свой блок форматирования 30 цифрового потока в поток информации к соответствующему потребителю информации 31. Все указанные блоки функционально связаны с системой синхронизации 42. При необходимости обеспечения множественного доступа, например, с кодовым разделением, перед передатчиками прямого 9 и обратного 24 направлений введены умножители 32 и 37 модулированного сигнала

на кодовый сигнал g_n(t), причем кодовые функции {g_n(t)} взаимно ортогональны или как можно более близки к ним. Соответственно введены блоки множественного доступа 33 и 38, имеющие N входов 34 и 39 для доступа потоков сигналов g_n(t)s_n(t), в том числе, других групп источников информации, и их суммирования. После приемников прямого 11 и обратного 25 направлений введены блоки множественного доступа 35 и 40, имеющие, соответственно, N выходов 36 и 41 синхронизированных потоков сигналов, в том числе, для других групп потребителей информации, и выполненные с возможностью синхронизированного умножения принятого сигнала

на каждый n-тый из N кодовых сигналов g_n(t) с выделением каждого n-того сигнала g_n ²(t)s_n(t), подаваемого на вход соответствующего демодулятора сигнала 12 или 26.As in the prototype, in the method for transmitting and receiving information (Fig. 1) in the forward and reverse directions from information sources 1 (and, accordingly, 17) to its consumers 2 (and, respectively, 31) through digital communication, each l-th one, where

, from L _k information sources from the nth group of information sources, where

, is connected, including, if necessary, through its information formatting unit 3 to a digital stream and compression unit 4, for example, with time division, of synchronized binary digital streams with L _k inputs 5 and one output 6 of the kth, where

, a digital stream to a high-frequency signal modulator 7, equipped with a carrier frequency generator 8 and connected to the forward direction transmitter 9. The latter is functionally connected via a transmission channel 10 compatible with the transmitted high-frequency signal to at least one forward direction receiver 11, which is connected through a demodulator high-frequency signal 12 and, if necessary, through the decompression unit 13 of the synchronized digital stream with one input 14 and L _k outputs 15 and its own digital formatting unit 16 the flow of information to the corresponding consumer of information 2. In this case, in the opposite direction, each of the information sources 17 is connected, if necessary, through its own information formatting unit 18 to a digital stream and a compression unit 19, for example, with time division, of synchronized binary digital streams with L _k inputs 20 and output 21 to the high-frequency signal modulator 22, equipped with a generator 23 of a dedicated source of information of the carrier frequency and connected to the transmitter of the opposite direction 24. The last functional It is connected via a transmission channel 10, compatible with the transmitted high-frequency signal, to the receiver 25, which is connected through the demodulator of the high-frequency signal 26 and, including, if necessary, through the decompression unit 27 of the synchronized digital stream with one input 28 and L _k outputs 29 and its own formatting unit 30 of the digital stream into the information stream to the corresponding information consumer 31. All of these blocks are functionally connected to the synchronization system 42. If necessary, provide a plurality of For access, for example, with code division, in front of the transmitters of the forward 9 and reverse 24 directions, multipliers 32 and 37 of the modulated signal are introduced

to the code signal g _n (t), and the code functions {g _n (t)} are mutually orthogonal or as close to them as possible. Accordingly, multiple access units 33 and 38 are introduced, having N inputs 34 and 39 for accessing signal streams g _n (t) s _n (t), including other groups of information sources, and their summation. After receivers of direct 11 and reverse 25 directions, multiple access blocks 35 and 40 are introduced, having, respectively, N outputs 36 and 41 of synchronized signal streams, including for other groups of information consumers, and configured to synchronously multiply the received signal

for each n-th of N code signals g _n (t) with the allocation of each n-th signal g _n ² (t) s _n (t) supplied to the input of the corresponding signal demodulator 12 or 26.

. Соответственно после демодулятора 12 введен, в том числе, дополнительно, n-тый блок разуплотнения 46 с одним входом 47 и К_n выходами 48, выполненный с возможностью одновременного за такт преобразования n-того синхронизированного M_n-арного цифрового потока, поступающего с М_n-арного демодулятора 12, в К_n синхронизированных бинарных цифровых потоков, подаваемых упорядоченно, как при упомянутом считывании, к выходам 48 введенного n-того блока разуплотнения 46.In the PPI system (Fig. 2), only in the forward direction in front of the high-frequency signal modulator 7 is introduced, including, in addition, the nth sealing unit of 43 k-th synchronized digital streams with K _n inputs 44 and one output 45, configured to the production of an ordered, for example, sequential from 1 to K _n , simultaneous for the cycle of reading binary digits K _n synchronized binary digital streams and converting them into the nth stream of M _n -ary characters, where

. Accordingly, after the demodulator 12 is introduced, including, in addition, the nth decompression unit 46 with one input 47 and K _n outputs 48, configured to simultaneously convert the n-th synchronized M _n -ary digital stream coming from M _n -ar demodulator 12, in K _n synchronized binary digital streams supplied in an orderly manner, as in the aforementioned reading, to the outputs 48 of the input n-th decompression unit 46.

, из L_k источников информации 1 из n-той группы источников информации, где

, подают, в том числе, при необходимости, через свой блок форматирования 3, в котором информацию форматируют в цифровой поток, к одному из L_k входов 5 n-того блока уплотнения 4 синхронизированных бинарных цифровых потоков (этот блок уплотнения, например, с временным разделением, может, при необходимости, присутствовать в действующей системе ППИ). Цифровой поток (k-тый, где

) с выхода 6 блока уплотнения 4 поступает на один из К_n входов 44 блока уплотнения 43. В нем упорядоченно, например, последовательно от 1 до К_n, одновременно за такт считывают двоичные цифры К_n синхронизированных бинарных цифровых потоков, поступающих через K_n входы 44, и преобразуют их в n-тый поток M_n-арных символов. Этот поток цифровых символов подают с выхода 45 на вход М_n-арного высокочастотного модулятора 7, снабженного генератором несущей частоты 8. Этот поток сигналов с выхода модулятора 7 передают через передатчик 9 по крайней мере к одному приемнику 11 через канал передачи 10, совместимый с передаваемым высокочастотным сигналом. Принятый поток сигналов подают на вход M_n-арного n-того демодулятора высокочастотного сигнала 12. Синхронизированный цифровой поток с выхода демодулятора 12 подают на вход 47 по крайней мере одного n-того блока разуплотнения 46. В блоке разуплотнения 46 одновременно за такт преобразуют n-тый поток М_n-арных символов в K_n синхронизированных бинарных цифровых потоков. Эти потоки подают с выходов 48 блока разуплотнения 46, в том числе, при необходимости (т.е., если указанные ниже блоки имеются в действующей системе ППИ) к одному входу 14 блока разуплотнения 13 синхронизированного цифрового потока, имеющего L_k выходов 15, и далее - к своим блокам форматирования 16. В блоках 16 l-тые цифровые потоки форматируют в информацию, которую направляют к соответствующим потребителям информации 2.The essence of the method is as follows. Forward information of each l -th where

, from L _k information sources 1 from the nth group of information sources, where

, including, if necessary, fed through its formatting unit 3, in which the information is formatted into a digital stream, to one of the L _k inputs 5 of the nth compression unit 4 synchronized binary digital streams (this compression unit, for example, with a temporary separation, may, if necessary, be present in the current PPI system). Digital stream (k-th, where

) from the output 6 of the compaction unit 4, it enters one of the K _n inputs 44 of the compaction unit 43. In it, for example, sequentially from 1 to K _n , at the same time, binary digits K _{n of the} synchronized binary digital streams coming through K _n inputs are read per cycle 44, and convert them to the nth stream of M _n -ary symbols. This digital symbol stream is fed from the output 45 to the input M -ary _n RF modulator 7, provided with a carrier frequency generator 8. This signal stream from the modulator 7 output is transmitted via transmitter 9 to the at least one receiver 11 via transmission channel 10 that is compatible with the transmitted high frequency signal. The received signal stream is fed to the input of the M _n -th n-th demodulator of the high-frequency signal 12. The synchronized digital stream from the output of the demodulator 12 is fed to the input 47 of at least one n-th decompression unit 46. In the decompression unit 46, n- the th stream of M _n -ary symbols in K _n synchronized binary digital streams. These streams are supplied from the outputs 48 of the decompression unit 46, including, if necessary (i.e., if the following blocks are present in the current PPI system) to one input 14 of the decompression unit 13 of a synchronized digital stream having L _k outputs 15, and further, to its formatting units 16. In blocks 16, the l-th digital streams are formatted into information that is sent to the corresponding consumers of information 2.

In the opposite direction, the information of each of the sources 17 is fed, if necessary, through its information formatter 18 to a digital stream to one of the L _k inputs 20 of the compaction unit 19 of the synchronized binary digital streams (this compaction unit, for example, with time division, may if necessary, be present in the current PPI system). The digital stream from the output 21 of the seal unit 19 is fed to the input of a high-frequency modulator 22 provided with a carrier frequency generator 23 allocated to the information source, and then transmitted through the transmitter 24 to at least one receiver of the opposite direction 25 through the transmission channel 10 compatible with the transmitted high-frequency signal . The received signal stream is fed to the input of the high-frequency signal demodulator 26. The synchronized digital stream from the output of the demodulator 26 is supplied, including, if necessary (that is, if the following blocks are available in the current PPI system) to one input 28 of the decompression unit 27 of the synchronized a digital stream having L _k outputs 29, and then to its formatting units 30. In blocks 30, the l-th digital streams are formatted into information that is sent to the respective consumers of information 31. In this case, the the function of all the indicated blocks.

на кодовый сигнал g_n(t) в умножителях 32 и 37 и суммируют синхронизированные потоки сигналов g_n(t)s_n(t), в том числе, других групп источников информации, в блоках множественного доступа 33 и 38, имеющих N входов 34 и 39 для доступа, в том числе, других групп источников информации. При этом кодовые функции {g_n(t)} должны быть взаимно ортогональны или как можно более близки к ним. После приемников прямого и обратного направлений 11 и 25 разделяют синхронизированные потоки сигналов в соответствующих блоках множественного доступа 35 и 40, имеющих N выходов 36 и 41, в том числе, для других групп потребителей информации, и выполненных с возможностью синхронизированного умножения принятого сигнала

на каждый n-тый из N кодовых сигналов g_n(t) с выделением каждого n-того сигнала g_n ²(t)s_n(t), который подают на вход соответствующих демодуляторов сигналов 12 и 26.If it is necessary to provide multiple access, for example, with code division, the modulated signal is multiplied in front of the forward and reverse transmitters 9 and 24

to the code signal g _n (t) in the multipliers 32 and 37, and the synchronized signal flows g _n (t) s _n (t), including other groups of information sources, are summed in multiple access blocks 33 and 38 having N inputs 34 and 39 for access, including other groups of information sources. Moreover, the code functions {g _n (t)} must be mutually orthogonal or as close to them as possible. After the receivers of the forward and reverse directions 11 and 25, the synchronized signal streams are separated in the corresponding multiple access blocks 35 and 40, having N outputs 36 and 41, including for other groups of information consumers, and configured to synchronously multiply the received signal

for each n-th of N code signals g _n (t) with the allocation of each n-th signal g _n ² (t) s _n (t), which is fed to the input of the corresponding demodulators of signals 12 and 26.

In the drawings, multiple access units, known seal types and formatting units in the system are indicated by a dashed line, which means their use if necessary. If there is no need for multiple access, the signal from modulators 7 and 22 is fed to transmitters 9 and 24, and from receivers 11 and 25 to demodulators 12 and 26 via communication lines indicated by n.

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 appropriate to transmit this and other information necessary for the organization of the system through an additional channel. Therefore, at least information about the reference levels of M _n -ary signals is transmitted through at least one additional transmission channel.

In the introduced, including, additionally, compaction unit, at each clock cycle (i.e., simultaneously), information from K _n sources is ordered in an orderly manner. 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 to a stream of digital characters. In the decompression unit, at the same time, the digital symbol stream is restored (decompressed) into K _n synchronized binary digital streams and served in an orderly manner, as when reading in the compaction unit, to consumers in a form convenient for them.

When implementing the method, all blocks of the PPI system can be made the same as in other systems of the same purpose. The timing and synchronization issues of the transmitting and receiving sides 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 digital symbols coming into 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.

Efficient computational algorithms, including well-known ones, are used for compaction and decompression (restoration of initial information), which facilitates their hardware-software implementation.

In this technical solution, when transmitting information from multiple sources in the forward direction, one frequency is used, and when transmitting information in the opposite direction, each source uses, as in the prototype, the frequency allocated to it. As applied, for example, to cellular communications, this technical solution allows to reduce the number of frequencies required for the operation of base station (BS) transmitters of cellular communications and to free up a significant part of the frequencies of BS transmitters, including in the frequency band used in GSM- communication systems 900. This is important for practice, as BS transmitters use the frequency band in which the aircraft’s avionics of the short-range radio navigation and landing system operate and create unintentional radio interference to them. Therefore, a decrease in the number of operating frequencies of BS transmitters covering the territory of the country makes it possible to significantly simplify the solution of the problem of ensuring electromagnetic compatibility, for example, short-range radio navigation systems and networks of the GSM-900 standard [Prikhodko V.V., Panov V.P., Kalugin V.G. . Scientific and technical aspects of conducting flight research to provide EMC systems for short-range radio navigation and GSM-900 networks. Telecommunications, No. 1, 2005].

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

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

(Siemens •).

- пробел, => - знак упорядоченного потактового считывания двоичных цифр бинарных цифровых потоков и их преобразования в поток M_n-арных символов и его обратного преобразования в бинарные цифровые потоки.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 table indicates: • - point,

- space, => - sign of an orderly tick-by-bit reading of binary digits of binary digital streams and their conversion to a stream of M _n -ary symbols and its inverse conversion to binary digital streams.

This simplest possible example of the use of the proposed method PPI 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. In addition, the invention improves the structural and informational secrecy of the transmitted digital signal in addition to the encoding laws currently in use. 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 (with frequency, time, code, spatial and polarization separation) and known processing methods signals, including, for example, for all known cellular standards.

Industrial applicability. The present invention can be applied in PPI systems using high frequency signals in any communication system. The PPI method according to this invention allows efficient use of 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 that are identical to all the features of the claimed technical solution are absent, which indicates the compliance of the proposed method with the condition of "novelty".

The search results for known solutions in the field of PPI methods in order to identify signs that match the distinctive features of the prototype of the claimed method showed 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 method of transmitting and receiving information in the forward and reverse directions from information sources to its consumers through digital communication, in which the information of each l-th in the forward direction, where

, from L _k information sources are fed, including if necessary, through their formatting unit, in which information is formatted into a digital stream, to one of the L _k inputs of the compression unit of synchronized binary digital streams, for example, with time division, and from one k where

the output of the compaction unit, a digital stream belonging to the nth group of information sources, where

, fed to the input of a high-frequency signal modulator equipped with a carrier frequency generator, from the output of this modulator, the signal stream is transmitted to the forward direction transmitter, and from it to at least one forward direction receiver through a transmission channel compatible with the transmitted high-frequency signal, the received signal stream is supplied RF demodulator input signal from the output of the demodulator is fed the digital stream, including, if necessary, through the decompression unit with one k-th input and output L _k, wherein decompress the synchronized digital stream, and through their formatting units, in which the digital streams are formatted into information, to the corresponding l-th information consumers, while in the opposite direction the information of each l-th information source is supplied, if necessary, through its formatting block, to which information is formatted into a digital stream, to one of the L _k inputs of the synchronization binary digital stream compression unit, for example, with time division, and from its k-th output to the input of the high-frequency modulator of the signal supplied by the generator with a dedicated carrier frequency information source, from the output of this modulator the signal stream is transmitted to the reverse direction transmitter, and from it to the reverse direction receiver through a transmission channel compatible with the transmitted high-frequency signal, the received signal stream is fed to the input of the high-frequency signal demodulator, output from the digital demodulator stream is fed, including, if necessary, through the decompression unit with one k-th input and L _k outputs which is synchronized decompact The specified digital stream, and through its formatting unit, in which the digital stream is formatted into information, to the corresponding l-th consumer of information, moreover, they synchronize the operation of all these blocks, and if necessary, provide multiple access, for example, with code division, in the transmission system and receiving information in front of the forward and reverse transmitters multiply the modulated signal

to the code signal g _n (t) in the multipliers, and the code functions {g _n (t)} are set to be mutually orthogonal or possibly closer to them, and in multiple access blocks having N inputs for accessing the signal flows g _n (t) S _n (t), including other groups of information sources, they are summed, and after the receivers of the forward and reverse directions in multiple access blocks having N outputs of synchronized signal streams, including for other groups of information consumers, the received signal

multiply by each n-th of N code signals g _n (t) and select each n-th signal g _n ² (t) s _n (t), which is fed to the input of the corresponding signal demodulator, characterized in that in the transmission system and receiving information in the forward direction in front of the high-frequency modulator, the signal in the inserted, including additional, block of compression of k-th synchronized digital streams with K _n inputs and one n-th output in an orderly manner, for example, sequentially from 1 to K _n , simultaneously per clock read binary digits K _n synchronized binary digital streams and transform them into the nth stream of M _n -th characters, where

respectively, after the demodulator in the introduced, including, additionally, decompression unit with one n-th input and K _n outputs, simultaneously synchronized digital stream M _n -th symbols supplied from M _n- th demodulator are simultaneously converted to K _n synchronized binary digital streams, which are supplied in an orderly manner, as in the aforementioned reading, to the outputs of the introduced decompression unit. 2. The method according to claim 1, characterized in that in the forward and reverse directions, at least information about the reference levels M _n signals are transmitted through at least one additional transmission channel.

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