RU2123761C1 - Discrete signal transceiver - Google Patents

Abstract

FIELD: radio engineering, in particular, reverse duplex control channels, packet wireless networks for operational communication in trench regions under influence of noise, including internal ones. SUBSTANCE: transmitting part of device has low-frequency oscillator 1, pseudorandom sequence driver 2, phase shifter 3, pseudorandom sequence generator 4, two multipliers 5 and 8, squarer 6, full-phase manipulator 7, adder 9, modulo-two adder 19, additional pseudorandom sequence generator 20, first and second time discriminator 21 and 22, shift register 23, adder 24. Receiving part of device has synchronization unit 10, first and second multipliers 11, 15, pseudorandom sequence driver 12, phase shifter 13, reference pseudorandom sequence generator 14, first and second band-pass filters 16, 18, phase detector 17, first and second time selectors 25 and 26, shift register 27, delay gate 28, multiplier 29, additional pseudorandom sequence analyzer 30, sign multiplier 31, additional pseudorandom sequence generator 32, adder 33, gate 34. Device practically eliminates possibility to receive signal from extraneous transmitter with arbitrary power level, because signals are identified not only by level of relative correlation of received and reference signals, but also on logical level by means of analysis of introduced structure of additional pseudorandom sequence. EFFECT: increased stability to noise under influence of system noise. 2 dwg

Description

 The device relates to the field of radio engineering and can be used mainly in reverse duplex radio control channels and packet radio networks of command communication in positional areas under the influence of various interferences, including intra-system ones.

 Known radio communication systems with noise-like signals that serve to transmit discrete information. The main disadvantage of these systems is the low noise immunity under the influence of interference with a concentrated spectrum. This drawback is due to the non-optimal signal processing algorithm with respect to such interference.

The closest in technical essence to the claimed is the "Equipment for supplying and receiving discrete information. The block diagram contains a prototype device contains (figure 1):
1 - carrier and clock generator / GNTC /;
2, 12 — shaper of the orthogonal pseudorandom synchro sequence / FOPSP /;
3, 13 - phasing unit;
4 - pseudo-random sequence generator k / GPSP /;
5, 8, 11, 15 - multipliers;
6 - phase shifter 90 ^o ;
7 - phase manipulator at 0-180 ^o ;
9 is a diagram of addition;
10 - block synchronization;
14 - generator reference pseudo-random sequence / GOPSP /;
16, 18 - band-pass filters;
17 is a phase detector.

 A broadband radio communication system, widely used in command radio lines, which, in addition to minimum synchronization time, high noise immunity to fluctuation and concentrated interference, has high requirements for protection from imitation interference and to reduce the likelihood of an adversary entering a command radio wave on the first try. The device does not meet these requirements - the prototype, which is its drawback.

 The purpose of the broadband signal transceiver is to increase noise immunity under the influence of structural interference.

Figure 2 shows a block diagram of a transceiver, where the notation is entered:
On the transmitting side:
1 - carrier and clock frequencies / GNTC /;
2 - shaper pseudo-random sync sequence / FOPSP /;
3 - phasing unit;
4 - pseudo-random sequence generator / GPSP /;
5, 8 - multipliers;
6 - phase shifter 90 ^o ;
7 - phase manipulator at 0-180 ^o ;
9 is a diagram of addition;
19 - adder modulo two;
20 - additional D GSSP;
21, 22 - the first and second time spectra;
23 - shift register;
24 - adder.

On the receiving side:
10 - block synchronization;
11, 15 - the first and second multipliers;
12 - shaper orthogonal pseudo-random sync sequence / FOPSP /;
13 - phasing unit;
14 - generator reference PSP / GOPSP /;
16, 18 - the first and second band-pass filters;
17 - phase detector;
25-26 - the first and second temporary selectors;
27 - shift register;
28 is a delay element;
29 - multiplier;
30 - analyzer additional memory bandwidth;
31 - sign multiplier;
32 - additional generator PSP;
33 - adder;
34 is the key.

 The device has the following functional relationships.

On the transmitting side, information is supplied simultaneously to the inputs of the first temporary selector 21 and the adder modulo two 19, the second input of which is connected to the output of the additional generator 22, the output is to the input of the second temporary selector 22, the outputs of the first 21 and second 22 temporary selectors are connected to the inputs the adder 24, the output of which is connected to the information input of the phase manipulator 7, and the second inputs of these temporary selectors are connected to the outputs of the shift register 23, one output of the GNST1 is connected to two clock inputs of the register shear 23, the second output is with the first input of the addition circuit 9 through the SINF2 and the multiplier 5 and with the second input of the addition circuit 9 through the GPRSF and the multiplier 8. The third output of the GNSS1 is connected to the second input of the multiplier 5 through a 90 ^o 6 phase shifter and to the second input of the multiplier 8 through the phase manipulator 7, the fourth output of the GNTC1 is connected to the clock input of the shift register 23. The outputs of the phasing unit 3 are connected to the second inputs of FOPSP2 and GPSSP4.

 On the receiving side, the received signal is supplied to the synchronization unit 10, to the first input of the phase detector 17 through the multiplier 11 and the bandpass filter 16 and to the second input of the phase detector 17 through the multiplier 15 and the bandpass filter 18.

 The first output of the synchronization block 10 is connected to the clocked input of the shift register 27, the second output of the synchronization block 10 is connected to the clocked inputs of the additional generator PSP32 and the shift register 27, and the third output is connected to the outputs of the FOPSP12 and GOPSP14.

 The second inputs FOPSP12 and GOPSP14 are connected to the outputs of the phasing unit 13, and the outputs are connected to the second inputs of the respective multipliers 11 and 15. The output of the phase detector 17 is connected to the inputs of the first 25 and second 26 time selectors, the second inputs of which are connected to the outputs of the shift register 27, the input GPSSP32 which is connected to the control input of the key 34 and through the analyzer 30 with the output of the multiplier 29, the first input of which through the delay element 28 is connected to the first time selector 25 and to the first input of the adder 33, and to the second input - with the output of the second time change selector 26 and the first input of the symbol multiplier 31, the second input of which is connected to the output of the additional GPSP32, and the output is connected to the second input of the adder 33, the output of which is connected to the input of the key 34, the output of which is the output of the receiver.

The device operates as follows. On the transmitting side, GNST1 generates a sinusoidal voltage of the carrier frequency and three pulse sequences, one of which sets the clock frequency of the SRP generated by the SOPF2 and GPSP4, the second pulse sequence has a pulse rate equal to the pulse rate of the information symbols / information rate /, and the pulse pulse frequency of the third sequence is twice the frequency of information symbols. Information symbols to be transmitted are received at the input of the temporary selector 21 and at the input of the adder modulo two 19, the second input of which receives the elements of the SRP generated by the additional GPS 20, which is clocked by pulses with a frequency equal to the repetition rate of information symbols. From the output of the adder modulo, two 19 elements of the total sequence are fed to the input of the second temporary selector 22. The operation of the temporary selectors 21 and 22 is controlled by the shift register 23, to the synchronizing input of which pulses from the output of GNST1 with a repetition rate twice the speed of information transfer are received, and the input setting register 23 in the initial state receives a sequence of pulses with a frequency equal to the speed of information transfer. This implies that the arrival of information pulses synchronously in time with the phase of the pulses coming from the outputs of GNST1. The shift register 23 sequentially generates at its outputs pulses that are fed to the control inputs of the corresponding time selectors 21 and 22, which transmit signals to the input of the adder 24 only at the moment of applying the pulse from the output of the register 23. Thus, a sequence of characters is formed at the output of the adder 24, following with a frequency twice that of information symbols. Each odd element of this sequence is a corresponding information symbol, and each even element is the sum modulo two of this information symbol with the corresponding element of the SRP generated by the additional generator of SRP 20. The repetition period of this SRP / its duration or the number of elements / is determined by the noise immunity requirements to structural interference and admissible complexity of the analyzer of this PSP on the receiving side. From the output of the adder 24, a sequence of characters with a frequency twice the frequency of receipt of information symbols at the input of the device is supplied to the phase manipulator 7, the second input of which receives the carrier frequency signal from the output of GNST1. In the phase manipulator 7, the phase shift of the carrier frequency oscillations by 0-180 ^° is carried out in accordance with the values of the characters entering the phase manipulator 7 from the output of the adder 24. From the output of the phase manipulator 7, the phase-shifted carrier signal is fed to the input of the multiplier 8, to the second the input of which is fed by the SRP from the output of GPSP4. At the output of the multiplier 8, a phase-shifted signal is generated, phase-shifted 0-180 ^o phase as elements of the SRP, and elements of a sequence of characters coming from the output of the adder 24, which is fed to the second input of the adder 9. The carrier frequency signal from the third output of the GNT41 is also fed through a phase shifter 6 by 90 ^° to the second input of the multiplier 5, to the first input of which comes the SRP from the output of the SOP2, which is orthogonal to the SRP produced by the GPSP4. From the output of the multiplier 5, the carrier signal, phase-shifted by 0-180 ^o phase elements of the sync sequence, which is also 90 ^o phase-shifted relative to the phase of the carrier frequency in the information channel, is fed to the first input of adder 9. GPSP4 and FOPSP2 are clocked by pulses from the second GNSS output1. The in-phase operation of both PSP generators is provided by the phasing unit 3, which also ensures synchronization of the start-up of these generators with the moments of receipt of information symbols at the input of the device. At the output of the adder 9, a four-phase pseudo-random signal is generated, which is transmitted via a communication channel.

In the receiver, this signal is fed to synchronizer 10 and multipliers 11 and 15. Synchronization block 10 detects and searches for the delay of the received signal, synchronizes the reference sequences generated by FORSP12 and GOPSP14 with similar sequences generated on the transmitting side of FOPSP2 and GPSSP4 and generates clock pulses, following with a frequency equal to the information transfer rate / i.e. with a repetition period equal to the duration of the clock / and a sequence of clock pulses with a frequency of twice as much. After capturing the input signal by block 10, the reference sequence from the output of FOPSP12 is supplied to the second input of the multiplier 11, and the reference sequence from the output of GOPSP14 to the second input of the multiplier 15. The signals from the outputs of the multipliers 11 and 15 are fed through the bandpass filters 16 and 18 to the inputs of the phase detector 17 . At the same time, the carrier frequency oscillation is allocated at the output of the band-pass filter 16, and the same oscillation is detected at the output of the band-pass filter 18, but phase-manipulated elements of the sequence that arrive at the transmitting side to the phase mani ulyator 7 and shifted in phase by 90 ^o. In the phase detector 17, these oscillations are reduced to a single phase and the informational phase difference between the clock signal and the information signal is extracted, i.e. coherent demodulation is carried out in the information channel. The demodulated signals from the output of the phase detector 17 is fed to the inputs of the first 25 and second 26 time selectors. The operation of the temporary selectors 25, 26 is controlled by the shift register 27, to the synchronizing input of which pulses are received from the output of the synchronization unit 10 with a period equal to half the duration of the clock signal, and the pulse train with the period twice as long is received at the input of the register register 27 in the initial state. The shift register 27 sequentially generates at its outputs pulses with a duration equal to half the duration of the clock signal and a repetition period equal to the duration of the clock signal, i.e. "meander", at each of the outputs phase-shifted for half the period. Temporary selectors 25 and 26 pass signals from the output of register 27. Since each of the information symbols was transmitted during the duration of the first half of the clock signal unchanged, and during the second half being summed with the corresponding element of the SRP generated by the additional GPS 20, the output of the first temporary selector 25 an information impulse is allocated, and at the output of the second temporary selector 26, the results of superposition of an additional memory element element onto the information symbol. To reduce in time the output voltages of the temporary selectors 25 and 26, the signal from the output of the first temporary selector 25 is delayed in the delay element 28 for a time equal to half the duration of the clock signal. The signal from the output of the delay element 28 directly, and from the output of the second temporary selector 26 through the sign multiplier 31 are fed to the adder 33. At the same time, these signals are fed to the multiplier 29. If the synchronization unit 10 has correctly detected the signal of its transmitter, then the output of the multiplier 29 allocated PSP identical to PSP formed on the transmitting side by the generator of additional PSP20. From the output of the multiplier 29, the allocated PSP is fed to the input of the analyzer of the additional PSP30, which analyzes the incoming sequence at the transmitter with the additional generator PSP20. If this sequence is recognized as additional, i.e. belonging to its transmitter, the analyzer 30 generates an identification pulse of this sequence, which is phased by an additional generator PSP32, the clock input of which receives clock pulses from the synchronization unit 10 with a frequency equal to the information transfer speed. From the output of the additional generator PSP32, the additional PSP is fed to the second input of the sign multiplier 31, the output of which is allocated voltage corresponding to the true values of the information symbols, i.e. “removal” of the elements of the additional memory card superimposed on the information symbols at the transmitter is carried out. The output voltages of the symbol multiplier 31 and the delay element 28 are added to the adder 33, at the output of which information symbols are allocated, which in turn are sent to the key 34. The key 34 is opened by an additional memory signal recognition pulse, which is generated by the additional memory signal analyzer 30, and passes the extracted information to the device output .

 In the case of false detection and synchronization, which can occur in the synchronization unit 10 under the influence of, for example, powerful structural interference, either intra-system or intentional, some random symbol sequence is allocated at the output of the multiplier 29, which is not recognized in the analyzer of the additional SRP30. In this case, an identification pulse is not generated at the output of the PSP30 analyzer, the key 34 does not open and information does not pass to the device output, which indicates a false detection and signal capture in the synchronization unit 10 and the need for a second detection cycle.

 Thus, in the device, the transmitted information is equipped with a sign in the form of an additional memory bandwidth, which allows you to identify the belonging of the received signals transmitted by "your" transmitter and weed out all the "foreign" signals. The introduction of this feature does not impair the noise immunity of the proposed device in relation to other types of interference, such as narrow-band noise, pulsed, etc. This is due to the fact that in this device linear addition of signal elements related to one information symbol is carried out, which are obtained as a result of coherent demodulation, i.e. as in the known device, coherent signal accumulation is implemented.

 In conventional broadband communication systems with coherent signals, the near-far problem is very acute, i.e. the problem of receiving a weak signal from its transmitter in the presence of a powerful signal from a nearby transmitter using the same class of signals. In this case, the receiver will capture with a probability close to unity the signal of the “foreign” transmitter and will highlight the information transmitted by this transmitter. This will happen if the signal power of an extraneous transmitter exceeds the signal power of its transmitter from / at the receiving location / by approximately the number of times equal to the base of the signals used. In the device, receiving information from an extraneous transmitter with any power level across is almost impossible, because identification of signals is carried out not only by the level of mutual correlation of incoming and reference signals, but also at a logical level due to the analysis of the introduced feature - the structure of the additional memory bandwidth.

Claims (1)

A digital transmitting and receiving device containing a carrier and clock frequency (NTC) generator on the transmitting side, the first output of which is connected to the first input of the addition block through a series-connected shaper of the orthogonal pseudorandom sync sequence (OSSR) and the first multiplier with the second input of the addition block through in series connected by a pseudo-random sequence generator (PSP) and a second multiplier, and the second output of the NTCH generator is connected to the second input of the first multiplier ithout phase shifter 90 ^o and to a second input of the second multiplier through a phase manipulator and outputs block phasing are respectively connected to the control input of OPSSP and generator SAPs, and at the receiving side - the synchronization unit, the signal input of which is connected to the first input of the phase detector through a series-connected the first multiplier and the first bandpass filter, and with the second input of the phase detector through the second multiplier and the second bandpass filter connected in series, and the output of the synchronization unit with it is connected to the first inputs of the SSPS generator and the PSP generator, the second inputs of which are connected to the corresponding outputs of the phasing unit, and the outputs of the SSPS and the PSP generator are connected to the second inputs of the first and second multipliers, characterized in that, in order to increase the noise immunity under the influence of structural interference, the first and second time selectors, an adder modulo two, an additional SRP generator, a shift register and an adder, the outputs of the reg the shift ister respectively connected to the first inputs of the first and second time selectors, the outputs of which through the adder are connected to another input of the phase manipulator, the first additional output of the NTCH generator is connected to the input of the additional generator of the SRP and to the input of the shift register, the clock input of which is connected to the corresponding output of the NTCH generator moreover, the output of the auxiliary generator PSP is connected to the input of the first temporary selector through an adder modulo two, the other input of which is connected to the input of the second The belt selector is the information input of the device, and the first and second time selectors, a shift register, an SRP analyzer, a delay element, a multiplier, an adder, a sign multiplier and a key are introduced on the receiving side, while the output of the phase detector is connected to the first inputs of the first and second time selectors, the second inputs of which are connected respectively to the outputs of the shift register, the clock input of which and the clock input of the additional generator PSP are connected to the second output of the synchronization unit, the output is not the first time selector through the delay element is connected to the first inputs of the multiplier and the adder, and the output of the second temporary selector is connected to the second input of the multiplier and through the sign multiplier with the second input of the adder, the output of which is connected to the input of the key, the control input of which is connected to the input of the additional generator ПСП and with the output of the PSP analyzer, the input of which is connected to the output of the multiplier, the output of the additional generator is connected to the second input of the signed multiplier, the third output of the sync block tions connected to the input shift register and the output key is the output of the device.

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