RU2194365C2 - Multichannel communication system - Google Patents

Abstract

FIELD: electric and radio communication. SUBSTANCE: invention can find use in wire, radio, radio-relay and space communication lines. Transmitting side of communication system has time manipulator which K inputs are main information inputs of system, synchronizer, amplitude modulator, phase-difference manipulator, code converter which n inputs are additional inputs of system, carrier frequency generator, synchronization unit, transmitter, receiving side of system incorporates receiver, matched filter, amplitude detector, comparator, four storages, decoder which outputs are main outputs of system, signal retrieval and storage unit, synchronization unit, pulse former, binary counter, phase meter, unit computing phase difference, solving device which outputs are additional outputs of system, AND gate, local generator. EFFECT: raised carrying capacity of system without any additional energy consumption. 1 dwg

Description

 The invention relates to electrical and radio communications and can be used in wired, radio, radio relay and space communication lines.

A multi-channel communication system is known, which contains a coding unit on the transmitting side, consisting of a signal generator of transmission addresses and a group signal generator, a transmitter and a sync block, and on the receiving side, a receiver, signal processing unit, solver, decoder, sync block and signal generator of receive / addresses 1/. In the shaper of the group signal, K multipliers and an adder are combined here, in the signal processing unit - 2 ^k channels, and in the resolver - adders and decision blocks. Synchroblocks on the transmitting and receiving sides ensure the system is operational.

 However, such a system is complex and expensive and has low reliability.

 Closest to the claimed is a multi-channel system / 2 /.

 It contains on the transmitting side a coding unit consisting of a synchronizer and a temporary manipulator, a transmitter, a sync block, and on the receiving side there is a receiver, a matched filter, a comparator, first and second memory devices, a decoder, a device for sampling and storing a signal, a sync block, a pulse shaper, binary counter, communication line.

 However, this system has a low bandwidth.

 The invention is aimed at increasing the throughput of the system.

 For this, a multichannel communication system containing on the transmitting side an encoding unit consisting of a synchronizer and a temporary manipulator, the K inputs of which are the main information inputs of the system, and the (K + 1) th and (K + 2) th inputs are connected respectively to the first and second outputs of the synchronizer, the transmitter and the sync block, connected by the input to the first output of the synchronizer, and the output with the sync input of the transmitter, and on the receiving side - series-connected receiver and matched filter, series-connected a parator, first and second memory devices and a decoder, a device for sampling and storing a signal, the signal input of which is combined with the first input of the comparator, a clock input is connected to its output, and the output is connected to its second input, a synchro block is connected in series, the input of which is connected to the second output a receiver, a pulse shaper and a binary counter, the output of the sync block being connected to the clock inputs of the second memory device, the binary counter and the third input of the signal sampling and storage device, the output of the pulse shaper is connected to the third input of the comparator, and the outputs of the binary counter are connected to the second information inputs of the first storage device, an amplitude manipulator connected to the input to the output of the temporary manipulator, and an output to the signal input of the transmitter, series-connected code converter, n inputs which are additional information inputs of the system, and a phase difference manipulator, the output of which is connected to the second input of the amplitude the manipulator, the carrier frequency generator and the second input of the synchro block, the output of the carrier frequency generator connected to the second input of the synchro block and the (n + 1) -th input of the phase difference manipulator, the (n + 2) -th and (n + 3) -th inputs of which are connected respectively, to the output of the temporary manipulator and the first output of the synchronizer, and on the receiving side four additional outputs of the pulse shaper, an amplitude detector, the input of which is connected to the output of the matched filter, and the output to the signal input of the comparator, are connected in series the phase meter, the input of which is connected to the output of the matched filter, a third memory device, a fourth memory device, a phase difference calculation unit and a solver, the outputs of which are additional outputs of the system, the second inputs of the phase meter, third and fourth memory devices are combined and connected to the output of the comparator, and the output of the third storage device is connected to the second input of the phase difference calculation unit, circuit I, the output of which is connected to the third input of the a third storage device, and a local generator, the output of which is connected to the third input of the phase meter, and the second, third, fourth and fifth outputs of the pulse shaper are connected respectively to the third input of the fourth memory device, the clock input of the deciding device, the input of the circuit And, the second input of the circuit And and the fourth input of the phase meter.

 The drawing shows a functional diagram of the proposed multi-channel communication system.

 The multi-channel communication system contains on the transmitting side an encoding unit 1, consisting of a synchronizer 2 and a temporary manipulator 3, the inputs of which are the main information inputs of the system, the (K + 1) and (K + 2) -th inputs are respectively connected to the first and the second outputs of the synchronizer 2, series-connected amplitude manipulator (AM) 4, the input of which is connected to the output of the temporary manipulator 3, and the transmitter 5, series-connected code converter 6, n inputs of which are additional information system strokes, and a phase difference manipulator 7, the output of which is connected to the second input of the amplitude manipulator 4, a carrier frequency generator 8, the output of which is connected to the (n + 1) -th input of the phase difference manipulator 7, (n + 2) and (n + 3) the th inputs of which are connected respectively with the output of the temporary manipulator 3 and the first output of the synchronizer 2, the sync block 9, the first and second inputs of which are connected respectively with the first output of the synchronizer and the output of the carrier generator 8, and the output - with the sync input of the transmitter 5, and on the receiving side - p therefore, a connected receiver 10, a matched filter (SF) 11, an amplitude detector (HELL) 12, a comparator 13, a first memory device 14, a second memory device 15 and a decoder 16, a signal sampling and storage device 17, a signal input of which combined with the first input of the comparator, the clock input is connected to its output, and the output is connected to its second input, the sync block 18 is connected in series, the input of which is connected to the second output of the receiver 10, the pulse shaper 19 (FI) and the binary counter (DC) 20, and sync block output 18 connected to the clock inputs of the second memory 15, DC 20 and the third input of the UVX 17, the output of the FI 19 is connected to the third input of the comparator 13, and the outputs of the DC 20 are connected to the second information inputs of the first memory 14, in series connected to the phase meter 21 (IF), the first input which is connected to the output of the SF 11, the third memory 22, the fourth memory 23, the phase difference calculation unit 24 (BVRF) and the solving device (RU) 25, n outputs of which are additional information outputs of the system, the second inputs of the IF 21, the third memory 22 and the fourth memory 23 combined with the output of the comparator 13, cx mu And 26, the output of which is connected to the third input of the memory 22, the local reference frequency generator 27, the output of which is connected to the third input of the phase meter 21, and the second, third, fourth and fifth outputs of FI 19 are connected respectively to the third input of the fourth memory 23, clock the input RU 25, the first input of the circuit And 26, the second input of the circuit And 26 and the fourth input of the IF 21. The transmitting and receiving sides of the system are connected via a communication line 28.

A multi-channel communication system operates as follows. On the transmitting side K (K = 1,2,3 ...) of synchronous channel signals, consisting of characters "1" and "0" of duration T and representing a K-digit number in binary parallel form, are sent to the time manipulator 3, so that at its output at time moment τ _s = S • T / 2 ^K (where S is the value of the input binary number in decimal form) relative to the leading edge of the pulse acting on the second output of synchronizer 2 and coinciding in time with the beginning of channel symbols, rectangular pulse of duration T / 2 ^k equal to the period followed ia short pulses from the first output of synchronizer 2. Thus, each combination of input channel symbols corresponds to one of 2 ^{to the} temporary positions of the signal of block 3 in the time interval 0, T (etc.). This signal in block 4 is used for amplitude manipulation of the carrier wave with a certain initial phase, coming from the carrier frequency generator 8 through the phase difference manipulator 7. The received group signal together with synchronization signals, which are short radio pulses at the carrier frequency, coming from sync block 9 and carrying information about the beginning of channel symbols, is transmitted by transmitter 5 over communication line 28. At the receiving side, a group signal arriving along with interference from the output of the receiver A 10, is optimally processed in SF 11, is detected by amplitude in block 12 and is supplied to the signal inputs of comparator 13 and UVX 17. Short sync pulses with a period T equal to the duration of information symbols are fed to inputs FI 19, UVX 17, DS 20 and memory 15 generated in the sync block 18 by the output clock signal of the receiver 10 and coinciding in time with the moments when they are received. When the first clock pulse arrives at its trailing edge, the UVX 17, DS 20 and ZU 15 are zeroed, and at the first output of FI 19, 2 ^k short pulses with a period of T / 2 ^k corresponding to the possible positions of the maximum amplitudes of the filtered signal are generated in time. At the moment of the action of the first of them (its leading edge), the signal from the output of the AD 12 enters the comparator 13 and is compared in level with the signal supplied to its second signal input from the UVX 17 unit (in this case, zero). If it is larger than the latter, the output of the comparator 13 produces a voltage drop that opens the entrance SHA 17 and allows it to remember blood pressure output signal 12. This procedure is repeated ^for two times. As a result, by the time the second clock pulse arrives from the output of block 18 and UVX 17, the level of the largest of the output signals AD 12 is recorded for a time equal to T. The binary K-bit counter DS 20 is designed to count the number of pulses arriving at it from the first output of the block FI 19. Each time a voltage drop appears at the output of the comparator 13, the readings K of the bits of the DS 20 are read in the memory 14. This allows you to record the number of the temporary position of the largest of the output signals HELL 12 on the time interval T. In the moment of arrival of the second clock pulse from the output of the sync block 18, the number recorded in the memory 14 is recorded in the memory 15. The decoder uniquely converts the binary number into channel symbols, which, in the absence of interference, coincide with the transmitted information symbols K of the main channels.

 Thus, the transmission and reception of information of the main compressed channels.

The transmission of symbols n (n = 1, 2, 3 ...) of additional synchronous to the main channels is carried out by phase-difference manipulation of time-related radio pulses of a group signal. These symbols are sent in parallel through the code converter 6 to the phase difference manipulator 7 and set the initial phase of the oscillation coming from the carrier frequency generator 8, with one of the shifts ϑ _m = m (2π / 2 ^m ), where m is the value of the input binary number in decimal form, relative to the initial phase of the radio pulse established earlier. Demodulation of the signal thus obtained is carried out digitally / 3 / by means of blocks 21, 23-25. A memory device 22 is used to store intermediate data. The phase meter 21 each time a voltage drop arrives at its second input from the output of the comparator 13 passes part of the reference pulses to its third input from the fifth output of the FI 19 block, proportional to the phase difference of the output signal of the SF 11 and the local non-adjustable generator 27 carrier reference frequency, and the memory 22 is reset to zero and it counts these pulses. The same difference also clears the memory 23. As a result, after the time moment i • Т (i = 2, 3 ...) in the memory 22, in the absence of interference, a number proportional to the phase difference of two adjacent radio pulses of the i-th and i + 1 th. At the moment of time i • Т + 0.5τ (where τ is the period of the carrier frequency), a pulse of duration 0.5 • τ from the fourth output of FI 19, which allows reference pulses that overwrite the number recorded in the memory 22, in the memory 23 and BVRF 24. As a result, at the time moment i • Т + 2τ of the action of the short pulse at the second output of FI 19, the number is transferred from the memory 23 to the BVRF 24. The pulses from outputs 2, 3 4 FI 19, and the voltage drop at the output of the comparator 13 play the role of impulses overwrite, read, start and measuring and setting / 3 /.

 Thus, the proposed multi-channel communication system can increase throughput without additional energy costs.

 All blocks included in the system are known. The principle of operation and various schemes of phase difference manipulators are given, for example, in the book of A.M. Zvezdnogo et al. "Phase difference manipulation", Moscow: Communication, 1967, p. 146-154.

Sources of information
1. Copyright certificate of the USSR 907834, cl. H 04 J 11/00, 1982.

 2. RF patent 2103827, cl. H 04 J 11/00; H 04 Q 11/00, 1996.

 3. L.Ya. Lipkin, A.A. Shishkov "Digital demodulator of signals of relative phase manipulation". Telecommunications, 2, 1973, p. 47.

Claims (1)

 A multi-channel communication system transmitting synchronous channel symbols, which is a K-digit number, containing a synchronizer and a time manipulator on the transmitting side, the K inputs of which are the main information inputs of the system, and the (K + 1) -th and (K + 2) - the first inputs are connected respectively to the first and second outputs of the synchronizer, the transmitter and the sync block connected by the input to the first output of the synchronizer, and the output with the sync input of the transmitter, and on the receiving side, the receiver and the serial a coded filter, a comparator and a first memory device connected in series, a second memory device and a decoder that converts a binary number recorded in the first memory device and rewritten in the second memory device into channel symbols, a signal sampling and storage device, the signal input of which is combined with the first input comparator, the clock input is connected to the output of the comparator, and the output is connected to the second input of the comparator, a sync block is connected in series, the input of which is connected nen with the second output of the receiver, a pulse shaper and a binary counter, the output of the clock being connected to the clock inputs of the second memory device, the binary counter and the third input of the signal sampling and storage device, the output of the pulse shaper connected to the third input of the comparator, and the outputs of the binary counter connected to the second information inputs of the first storage device, characterized in that on the transmitting side an amplitude manipulator is connected to it, connected by an input to the output of a temporary man a pulser, and the output - with the signal input of the transmitter, a code converter, n inputs of which are additional information inputs of the system, and n additional symbols are transmitted through the code converter in binary parallel form to a phase difference manipulator, the output of which is connected to the second input of the amplitude manipulator, a carrier frequency generator and the second input of the sync block, and the output of the carrier frequency generator is connected to the second input of the sync block and the (n + 1) -th input of the phase difference manipulator the, (n + 2) -th and (n + 3) -th inputs of which are connected respectively to the output of the temporary manipulator and the first output of the synchronizer, and on the receiving side four additional outputs of the pulse shaper are introduced, an amplitude detector whose input is connected to the output of the matched filter, and the output to the first input of the comparator, a phase meter connected in series, the input of which is connected to the output of the matched filter, a third storage device, a fourth storage device, a phase difference calculation unit and a resolver and, the second inputs of the phase meter, the third and fourth storage devices are combined and connected to the output of the comparator, and the output of the third storage device is connected to the second input of the phase difference calculation unit, circuit I, the output of which is connected to the third input of the third storage device, and the local generator the output of which is connected to the third input of the phase meter, and the second, third, fourth and fifth outputs of the pulse shaper are connected respectively to the third input of the fourth storage devices, the clock input of the deciding device, the input of the circuit And, the second input of the circuit And and the fourth input of the phase meter, while the demodulation of n additional symbols is carried out digitally by means of a phase meter, a fourth storage device, a phase difference calculation unit and a resolver, n outputs of which are additional information outputs of the system.