RU2817302C1 - Noise-like radio communication system - Google Patents

Abstract

FIELD: radio communication.

SUBSTANCE: invention relates to radio communication and can be used in communication systems with noise-like signals for transmitting information using Manchester-2 technology. Radio communication system with noise-like signals further comprises in transmitting part in series connected input device (1), binding unit (2), which second input is connected to output of clock generator (7), and relative encoder (3), and in receiving part – serially connected relative decoder (15), clock synchronization device (19) is connected to the second input of the latter, and output device (16). Input of input device (1) is input of receiving part. Output of relative encoder (3) is connected to the first input of phase modulator (4). Output of the decision device is connected to inputs of relative decoder (15) and clock synchronization device (19). Output of output device (16) is the output of the receiving part.

EFFECT: high reliability of transmitting packet information.

1 cl, 2 dwg

Description

The invention relates to the field of radio communications and can be used in communication systems with noise-like signals for transmitting information using Manchester-2 technology (GOST R 52070-2003 and MIL-STD-1553B).

Communication systems with noise-like signals (NLS) are known, described in [1], [2], [3], [4], [5], [6]. The disadvantage of these systems is the impossibility of transmitting packet information using Manchester-2 technology without losing the transmitted information.

The closest analogue in technical essence to the proposed one is a radio communication system using broadband phase-keyed signals (FM WPS), presented in the book [1, pp. 16 - 17, Fig. 1.7], adopted as a prototype.

A functional diagram of the prototype system is shown in Fig. 1, where the following notations are introduced:

4 - phase modulator (PM);

5 - balanced modulator (BM);

6 - power amplifier (PA);

8 - phase-shift keyed signal generator (GPS);

9 - carrier frequency generator (CFO);

10, 18 - first and second synchronizers (C);

11 - mixer (Sm);

12 - intermediate frequency amplifier (IFA);

13 - matched filter (MF);

14 - decisive device (RU);

17 - local oscillator (Het).

The communication system consists of transmitting and receiving parts.

The transmitting part contains a series-connected phase modulator 4, a balanced modulator 5 and a power amplifier 6, the output of which is the output of the transmitting part. The output of the carrier frequency generator 9 is connected to the second input of the balanced modulator 5, the output of the first synchronizer 10 is connected to the input of the phase-shift keyed signal generator 8, the output of which is connected to the second input of the phase modulator 4. The first input of the phase modulator 4 is the information input of the transmitting part.

The receiving part contains a series-connected mixer 11, an intermediate frequency amplifier 12, a matched filter 13 and a decision device 14, the output of which is the output of the receiving part. The output of the matched filter 13 is connected to the input of the second synchronizer 18, the output of which is connected to the second input of the decision device 14 and the input of the local oscillator 17, the output of which is connected to the second input of the mixer 11, the first input of which is the information input of the receiving part.

The prototype system works as follows.

In the transmitting part from the information source, a sequence of binary information symbols 1 and 0 with a duration of T ₀ at a speed of 1/T ₀ is supplied to the first input of PM 4, the second input of which from the output of GFM 8 simultaneously receives a pseudo-random sequence signal (PSR) with a duration of T ₀ , representing is a sequence of video pulses 1 and 0 with a duration of τ ₀ = T ₀ /N, where N is the number of such pulses in the PSP signal. From the output of PM 4 the first input of BM 5 receives a phase-shift keyed video signal modulated by the symbols of the information sequence. At the same time, a carrier frequency signal is received from the output of LFO 9 to the second input of BM 5, and from its output a phase-shift keyed broadband signal comes to the input of PA 6, where it is amplified and entered into the communication channel. The first synchronizer 10 coordinates the operation of the GFM 8 with the rate of arrival of information symbols.

In the receiving part, the FM SHPS emitted by the transmitting part, having passed through the communication channel, enters the first input of the mixer Sm 11, the second input of which receives a signal from the local oscillator 17, while the received signal is transferred to an intermediate frequency and enters the input of the amplifier 12. The amplifier 12 carries out the main amplification receiving signals. From the output of the amplifier 12, the signal is supplied to the input of the matched filter SF 13, in which optimal processing of the received signal is performed. The signal from the output of SF 13 is supplied to the input of the second synchronizer 18 and to the first input of the decision device RU 14. The synchronizer 18 searches for the signal in frequency and time, accumulates the signal to increase the reliability of synchronization, controls the operation of the decision device 14 and the local oscillator 17. To search for PM frequency signal, the synchronizer 18 rearranges the local oscillator 17. After completing the search and entering into synchronism, an information sequence in the form of binary symbols appears at the output of the RU 14, which is sent to the information recipient.

The disadvantage of the prototype system is the impossibility of transmitting packet information using Manchester-2 technology without losing the transmitted information. The transmission of packet information involves pauses between packets of information, so from time to time the transmission is stopped, which leads to a breakdown in synchronization on the receiving side [2, p. 429] and, as a consequence, to the loss of received information during the time of synchronization restoration.

The goal is to increase the reliability of packet information transmission by eliminating the influence of transmission interruptions on synchronization failures on the receiving side, leading to loss of received information.

To solve the problem, a radio communication system with noise-like signals containing in the transmitting part a phase modulator, a balanced modulator and a power amplifier connected in series, the output of which is the output of the transmitting part, while the output of the carrier frequency generator is connected to the second input of the balanced modulator, the output of the first synchronizer is connected with the input of a phase-shift keyed signal generator, the output of which is connected to the second input of the phase modulator; in the receiving part, a mixer, an intermediate frequency amplifier, a matched filter and a decision device are connected in series, while the output of the matched filter is connected to the input of the second synchronizer, the output of which is connected to the second input of the decision device and the input of the local oscillator, the output of which is connected to the second input of the mixer, the first input which is the information input of the receiving part, characterized in that a series-connected input device, a binding block and a relative encoder are introduced into the transmitting part, the output of which is connected to the first input of the phase modulator, while the output of the clock generator is connected to the second input of the binding block, the input of the input device is the input of the receiving part; in the receiving part - a relative decoder and an output device connected in series, the output of which is the output of the receiving part, while the output of the decision device is connected to the inputs of the relative decoder and the clock synchronization device, the output of which is connected to the second input of the relative decoder.

In fig. Figure 2 shows a functional diagram of the proposed radio communication system with noise-like signals, where the following symbols are given:

1 - input device (Input);

2 - binding block (BPr);

3 - relative encoder (RtnK);

4 - phase modulator (PM);

5 - balanced modulator (BM);

6 - power amplifier (PA);

7 - clock generator (TGen);

8 - phase-shift keying signal generator (GPS);

9 - carrier frequency generator (CFO);

10, 18 - first and second synchronizers (C);

11 - mixer (Sm);

12 - intermediate frequency amplifier (IFA);

13 - matched filter (MF);

14 - decisive device (RU);

15 - relative decoder (RtnD);

16 - output device (OutU);

17 - local oscillator (Het);

19 - clock synchronization device (TCD).

The proposed radio communication system consists of transmitting and receiving parts.

The transmitting part contains a series-connected input device 1, a binding unit 2, a relative encoder 3, a phase modulator 4, a balanced modulator 5 and a power amplifier 6, the output of which is the output of the transmitting part. The output of the carrier frequency generator 9 is connected to the second input of the balanced modulator 5, the output of the first synchronizer 10 is connected to the input of the phase-shift keyed signal generator 8, the output of which is connected to the second input of the phase modulator 4. The output of the clock generator 7 is connected to the second input of the binding block 2. Input of the input device 1 is the input of the receiving part.

The receiving part contains a series-connected mixer 11, an intermediate frequency amplifier 12, a matched filter 13, a decision device 14, a relative decoder 15 and an output device 16, the output of which is the output of the receiving part. The output of the matched filter 13 is connected to the input of the second synchronizer 18, the output of which is connected to the second input of the decision device 14 and the input of the local oscillator 17, the output of which is connected to the second input of the mixer 11, the first input of which is the information input of the receiving part. The output of the decision device 14 is connected to the input of the clock synchronization device 19, the output of which is connected to the second input of the relative decoder 15.

The proposed radio communication system with noise-like signals works as follows.

In the transmitting part, the “Manchester-2” information signal is received from the information source, which is a sequence of bipolar pulses that make up the information package. The maximum burst duration is 640 µs. Transmitted packets arrive from the information source asynchronously with pauses from 4 to 12 μs. Input device 1 converts the incoming bipolar signal into a unipolar one, suitable for processing by logic chips. Manchester-2 information packets arriving at the input of the receiving part with a clock frequency F ₁ are clocked in the binding block 2 and are thus phase locked to the signal of the clock generator 7, which operates at a frequency F ₂ = n⋅F ₁ , where n is an integer, and then written to memory cells with a clock frequency F _zap = F ₂ / n. The stability of the clock generator 7 ensures the discrepancy between the recording frequency F _record and the clock frequency F ₁ within minimal limits, and therefore, during the transmission of an information packet of maximum duration, the moment of recording does not go beyond the minimum duration pulse in the packet. From the output of the binding block 2, the packet signal is supplied to the input of the relative encoder 3, which produces a continuous signal at its output, since the encoded pause between packets after encoding is a meander.

From the output of relative encoder 3, a continuous encoded signal is supplied to the input of phase modulator 4, the second input of which receives a pseudo-random sequence signal from generator 8. PM 4 carries out phase modulation of the PSP signal.

From the output of FM 4 to the first input of BM 5, a sequence of BPS is received in the form of FM signals, carrying information symbols. At the same time, a carrier frequency signal is received from the output of LFO 9 to the second input of BM 5. BM 5 carries out balanced modulation of the oscillation with the carrier frequency by an FM signal. An oscillation with a carrier frequency is created by LFO 9. PA 6 amplifies the phase-shifted signal for subsequent radiation into space. The first synchronizer 10 coordinates the operation of the GFM 8 with the rate of arrival of information symbols.

In the receiving part, the FM broadband emitted by the transmitting part, having passed through the communication channel, enters the first input of the mixer 11, the second input of which receives a signal from the local oscillator 17, while the received signal is transferred to an intermediate frequency and is fed to the input of the amplifier 12, which carries out the main amplification of the receiving signal parts. From the output of the amplifier 12, the signal is supplied to the input of the matched filter 13, in which optimal processing of the received signal is performed. The signal from the output of SF 13 is supplied to the input of the second synchronizer 18 and to the first input of the decision device 14. The second synchronizer 18 searches for the signal in frequency and time, accumulates the signal to increase the reliability of synchronization, controls the operation of the decision device 14 and local oscillator 17. To search for PM frequency signal, the synchronizer 18 rebuilds the local oscillator 17. After the search is completed and synchronization is achieved, a continuous information sequence in the form of binary symbols appears at the output of the RU 14.

From the output of RU 14, a continuous encoded signal is supplied to the input of the relative decoder 15, as well as to the input of the clock synchronization device 19. The TCB 19 extracts a clock signal from the continuous encoded signal, which is supplied to the second input of the relative decoder 15. At the output of the relative decoder 15, the original packet is generated information signal of logical levels, which is then supplied to the input of the output device 16. The output device 16 generates a bipolar burst signal corresponding to the Manchester-2 standard, which is supplied to the consumer.

Thus, the introduction of additional blocks into the proposed system eliminates the influence of transmission interruptions on synchronization failures on the receiving side, leading to loss of received information.

Technical result - increased reliability transmission of packet information.

Information sources:

1. Varakin L.E. Communication systems with noise-like signals. - M.: Radio and communication, 1985.

2. Borisov V.I. and others. Noise immunity of radio communication systems with expansion of the spectrum of signals modulated by a carrier pseudo-random sequence. Ed. IN AND. Borisova. - M.: Radio and communication, 2003.

3. Patent RU 2450452 C1 Radio communication system with multiple access. Published 05/10/2012 Bulletin. No. 13.

4. Patent RU 2396707 C1 Radio communication system with noise-like signals. Published 08/10/2010 Bulletin. No. 22.

5. Patent RU 2279763 C1 Radio communication line. Published 07/10/2006 Bulletin. No. 19.

6. Patent RU 2165677 C1 Communication line of discrete information with broadband signals. Published 04/20/2001.

Claims (1)

A radio communication system with noise-like signals, containing in the transmitting part a phase modulator, a balanced modulator and a power amplifier connected in series, the output of which is the output of the transmitting part, while the output of the carrier frequency generator is connected to the second input of the balanced modulator, the output of the first synchronizer is connected to the input of the phase-shift keyed signal generator , the output of which is connected to the second input of the phase modulator; in the receiving part, a mixer, an intermediate frequency amplifier, a matched filter and a decision device are connected in series, while the output of the matched filter is connected to the input of the second synchronizer, the output of which is connected to the second input of the decision device and the input of the local oscillator, the output of which is connected to the second input of the mixer, the first input which is the information input of the receiving part, characterized in that a series-connected input device, a binding block and a relative encoder are introduced into the transmitting part, the output of which is connected to the first input of the phase modulator, while the output of the clock generator is connected to the second input of the binding block, the input of the input device is the input of the receiving part; in the receiving part - a relative decoder and an output device connected in series, the output of which is the output of the receiving part, while the output of the decision device is connected to the inputs of the relative decoder and the clock synchronization device, the output of which is connected to the second input of the relative decoder.