SU1069175A1 - Communication system with multi-base encoding - Google Patents

Abstract

MULTI-BASIC CODING COMMUNICATION SYSTEM containing a carrier frequency synthesizer and data source, the output of which is connected to the input of the clock generator, the output of which is connected to the synchronizing input of the signal converter, the output of which is connected to the first input of the phase modulator, the output of which is connected with the input of the power amplifier, and on the receiving side the receiver of information and the block of preliminary amplification and selection, the output of which is connected to the information input 1M multi-channel a linear correlator, a carrier recovery unit and a clock and cycle synchronization unit, the control input of which is connected to the first output of the carrier frequency recovery unit, the second output of which is connected to the information input of the reference signal conditioner, the outputs of which are connected to the control inputs of the multi-channel correl the torus, the outputs of which are connected to the information inputs of the block of selection of the maximum signal, while the outputs of the block clock and frame synchronization are connected to the synchronizing their inputs shaper reference signals. a multichannel correlator, a maximum signal selection unit and a combination recovery unit, so that, in order to reduce the frequency band occupied by the system, on the transfer side, a phase shift control unit, a differential coding unit and serially connected divider and decoder combinations, the output of which is connected to the first input of the signal converter and to the first input of the phase shift control unit, the second input and output of which are connected respectively to the output of the synthesis the carrier frequency and the second input of the phase modulator, the output of the data source is connected (L to the information input of the differential encoding unit, the clock input and the output of which are connected respectively to the output of the clock generator and the second input of the signal converter, the additional outputs of which are connected to information inputs of the decoder combinations, and the output of the clock clock pulse connected to the input of the divider, on the connection side entered two decoder and bl relative decoders, the input and output of which are connected to the 4-s, respectively, with the output of the restoring combination unit 01, the outputs of the first decoder are connected to one input, and the receiver of the maximum signal selection are connected to the inputs of the first and second decoders, the synchronization inputs of which are connected to the corresponding output of the clock and frame synchronization block, and the output of the second decoder is connected to another input of the combination recovery block.

Description

The invention relates to the technique of communication and can be used to improve the efficiency of signal transmission over communication channels with limited frequency and energy potential.

A communication system using a baseline coding is known, comprising on the transmitting side a data source, a TickerBHx pulse former, a divider, synthesizing a carrier frequency Tiop, a biorthogonal code shaper, a phase modulator and a power amplifier, and a receiving and selection unit on the receiving side, a multichannel correlator and - a decision block, a clock and frame synchronization block and a driver of the reference signals SP.

However, the communication system is not allowed to transmit information in a given frequency range without spreading.

; The closest technical solution to the invention is a communication system with a multi-core coding, comprising a carrier frequency synthesizer on the transmitting side and a data source, the output of which is connected to the input of the clock pulse generator, the output of which is connected to the synchronizing input of the signal converter, the output of which is connected to the first input of the phase modulator, the output of which is connected to the input of the power amplifier, and on the receiving side - the recipient of information and the preamplifier and selektov the output of which is connected to the information inputs of the multichannel correlator, the carrier recovery unit and the clock and frame synchronization unit, the control input of which is connected to the first output of the carrier recovery unit, the second output of which is connected to the information input of the reference signal former, the outputs of which are connected to the control inputs of the multichannel correlator, the outputs of which are connected to the information inputs of the block for selecting the maximum signal, while the outputs of the block are the serial and cyclic synchronization are connected to the synchronizing inputs of the shaper of the reference signals of the multichannel correlator, the max selection signal selection unit and the recovery unit C23,

However, a known communication system has a large frequency band.

The purpose of the invention is to reduce the frequency band occupied by the system.

The goal is achieved by the fact that in a communication system with multibasic coding, containing on the transmitting side a carrier frequency synthesizer and data source, the output of which is connected to the input of the clock pulse generator, the output of which is connected to the clock input of the signal converter, the output of which is connected to the first input of the phase module torus, the output of which is connected to the input of the power amplifier, and on the receiving side the recipient of information and the pre-amplification and selection unit, the output of which is connected It is connected to the information inputs of the multichannel correlator, the carrier recovery unit and the clock and frame synchronization unit, the control input of which is connected to the first output of the carrier frequency recovery unit, the second output of which is connected to the information input of the reference signal former, the outputs of which are connected to the control inputs a multichannel correlator whose outputs are connected to the information inputs of the maximum signal selection block, while the outputs of the clock and frame synchronous blocks The couplings are connected to the synchronization inputs of the reference signal generator, the multichannel correlator, the maximum signal selection unit and the combination recovery unit; on the transmitting side, the phase shift control unit, the differential encoding unit and the serially connected divider and decoder combinations are entered, the output of which is connected to the first input the signal converter and to the first input of the block, the phase shift control, the second input and output of which are connected respectively to the output of the synthesizer and The operating frequency and the secondary input of the phase modulator, the output of the data source is connected to the information input of the differential encoding unit, the input clock and output of which are connected respectively to the output of the clock generator and the second / i input of the signal converter, the additional outputs of which are connected to the information inputs the decoder of the combinations, and the output of the Tat generator: the pulses are connected to the input of the divider, two decoders and a relative unit are entered on the receiving side decoding, logging in and out. the stroke of which is connected respectively to the output of the combination recovery unit, to the same inputs of which the outputs of the first decoder are connected, and to the input of the recipient of information, while the outputs of the maximum signal selection unit are connected to the inputs of the first and second decoders, the clock inputs of which are connected to the corresponding output of the clock and frame synchronization, and the output of the second decoder is connected to another input of the recovery combination unit. FIG. Figure 1 shows the structural electrical circuit of the transmitting side of the proposed communication system; in fig. 2 the same, the receiving side. The communication system with MNOGOOSNOVNELM coding contains on the transmitting side (Fig. 1) data source 1, differential coding unit 2 signal converter 3, phase modulator 4, power amplifier 5, driver of clock pulses, divider 7, decoder 8 combinations of control unit 9 phase shift, carrier synthesizer 10, and on the receiving side (Fig. 2) pre-amplification and selection block 11, multichannel correlator 12, maximum signal selection block 13, first decoder 14, carrier recovery block 15 rmirovatel 16 reference signals, the second decoder 17, the reduction unit 18 combinations .blok 19 with respect to the decoding unit 20 so tovoy and frame synchronization, the receiver 21 of information. The communication system operates as follows. The sequence of binary symbols from the output of data source 1 is first fed to differential coding unit 2 on the transmitting side, where the binary data is converted into a new sequence of binary symbols of an interdependent form. This sequence of symbols is processed in the signal converter 3, to the control input of which the cyclic frequency pulses are also generated, formed from the clock frequency allocated by the driver of the clock pulses from the sequence of binary signals from the source 1 data by dividing it by four. At the output of the 3 signal converter, the information appears with a delay of four clock cycles. The decoder of 8 combinations is connected to the outputs of converter 3, which is polled with a period of following cyclic pulses of Tue 4Tg, so that with each new conversion at its output it generates the results of decrypting the next four-digit combination. Combinations with an even number of each type are passed through converter 3 unchanged, and combinations with an odd number of characters of each type are converted into even type combinations by inverting the first character of the code combination provided by feedback from the decoder 8 combinations to the input of the converter 3. Signals from the output of the decoder. In combinations, they are also used to control the shift of the carrier oscillation when implementing the second level of relativity. The phase shift of the carrier oscillation is carried out by switching the quadrature outputs of the synthesizer 10 Nes5, Tdei frequency on the control potentials generated by the decoder 8 combinations. As a result, the output signals of the converter 3 in the phase modulator 4 carry out phase modulation of the carrier oscillation, which has undergone additional processing in block 9 of the phase shift control. The resultant signal is amplified in the power amplifier 5 and fed to the communication line to the receiving side. At the receiving side (Fig. 2), the incoming signal is first fed to the pre-amplification and selection unit 11. Then, from the received signal in block 15, recovery of the carrier frequency and block 20 of clock and frame synchronization, the sync parameters — carrier frequency, clock frequency of binary symbols, and cycle frequency of combinations following — are separated. These functions can be performed by known methods of frequency and time selection. For example, separation of the carrier frequency (double carrier) is provided by the Kostas method of phase-locked loop control, separation of the binary signal following period can be performed based on the synchronous detection of received signals and subsequent filtering of the main wiring frequency from the total signal (Pistelcors method, etc.). On the basis of the allocated carrier, clock and cyclic frequencies, in the reference signal shaper 16, copies of the transmitted signals (reference oscillations) are formed, which are fed to the information separation channel. The main element of this channel is a multichannel correlator 12, which calculates the convolutions of the received signal with all copies (integration time TU) and the results of the calculation of the correlation intervals at time points, 2 ,. the number of which naturally coincides with the number of different signals is supplied to the parallel inputs of the maximum signal selection unit 13. At one of the outputs of block 13, a normalized signal is formed, fixing the channel number, at the output of which the received signal gives the maximum OUTPUT effect. The signals from the outputs of the block 13 arrive at the first 14 decoder and the second 17 decoders, respectively. The task of the first decoder 14 is to convert a normalized pulse signal at the output of block 13 into a four-bit combination (of even type) corresponding to this output. In this case, the second decoder 17 determines, based on the analysis of solutions made at the current and previous intervals, whether these decisions relate to one type of carrier (or cos y) or different types of carrier (lA and cos tdv, or cos u ) X HSinoix) and forms on this basis, at its output, a sign (impulse) of the membership of the current combination to a set of combinations of the odd type. The absence of pulse at the output of the second decoder 17 corresponds, in this case, to receiving a combination of the even type. At the final stage of processing, in the recovery block 18, based on the output signals of the first decoder 14 and the second decoder 17, a recovered code combination is formed, which is written off in a sequential code and input of the relative decoding unit 19, where the final playback of the received binary information is performed and outputted 21 information. The technical advantage of the proposed Technical Solution in comparison with the known one is to reduce the required frequency band for transmitting the same number of biorthogonal signals by a factor of 2, since the minimum interval between adjacent moments of a change in the phase of the carrier oscillation is equal to Tb in the transmitted signal, while a device in which the number of elements of a biorthogonal signal is 2 times larger, the minimum interval between adjacent moments of phase change is Tv / 2.

Claims (1)

MULTI-BASIC ENCODING COMMUNICATION SYSTEM, comprising a carrier frequency synthesizer and a data source on the transmitting side, the output of which is connected to the input of a clock pulse shaper, the output of which is connected to the clock input of the signal converter, the output of which is connected to the first input of the phase modulator, the output of which is connected to the input of the amplifier power, and on the receiving side, the recipient of information and the pre-amplification and selection unit, the output of which is connected to the information inputs of the multi-channel to an correlator, a carrier frequency recovery unit, and a clock and cyclical synchronization unit, the control input of which is connected to the first output of the carrier frequency recovery unit, the second output of which is connected to the information input of the reference signal generator, the outputs of which are connected to the control inputs of the multi-channel correlator, the outputs of which are connected to information inputs of the maximum signal selection block, while the outputs of the clock and cycle synchronization block are connected to the synchronizing inputs of the form a reference signal adjuster, a multi-channel correlator, a maximum signal selection unit and a combination recovery unit, which entails that, in order to reduce the frequency band occupied by the system, a phase shift control unit and a differential encoding unit are introduced into it on the transmitting side and series-connected splitter and decoder combinations, the output of which is connected to the first input of the signal converter and to the first input of the phase shift control unit, the second input and output of which are connected respectively However, with the output of the carrier frequency synthesizer and with the second input of the phase modulator, the output of the data source is connected to the information input of the differential coding unit, the synchronizing input and output of which are connected respectively to the output of the clock generator and to the second input of the signal converter, the additional outputs of which connected to the information inputs of the decoder combinations, and the output of the pulse shaper is connected to the input of the divider, two decoders are introduced on the receiving side ora and decode unit relative ditch ^ - <Nij, the input and the output of which soedi19eny respectively, with the release of combinations recovery unit, to one input of which are connected the outputs of the first decoder, and input the recipient's information!; the outputs of the maximum signal selection block are connected to the inputs of the first and second decoders, the synchronizing inputs of which are connected to the corresponding output of the clock and cycle synchronization block, and the output of the second decoder is connected to another input of the combination recovery block. ’ SU ... 1069175