RU47603U1 - DIGITAL COMMUNICATION SYSTEM WITH PHASOMANIPULATED NOISE-LIKE SIGNALS - Google Patents

Abstract

A communication system with noise-like signals is proposed, characterized in that a frequency band divider of the analog speech signal, a coherent detector, and a shaper of a single-band signal, a doubler of its frequency band, a coherent detector are introduced on the transmitting side into it. In this system, the SHPS base is increased by 2 times in a given frequency band, which determined a 2-fold increase in noise immunity of the communication, the number of channels in a given frequency band, the accuracy of determining the object's motion parameters, and others. Volkov Anatoly Alekseevich Moscow Lazorevy passage, 24, apt. 45. index 129323 Kuznetsov Sergey Nikolaevich sinks. reg. Troitsk Serenevy Boulevard 6, Apt. 158 Index 142090 Kurganova Julia Viktorovna Moscow Obraztsova d.22, building 1508 (general) index 103055 A utility model relates to the field of radio engineering, namely to the transmission of noise-like signals with phase shift keying. The technical result of the claimed object is to increase the base of noise-like signals. The essence of the claimed utility model consists in the fact that a divider of the frequency band of 2 times the modulating signal connected between the microphone amplifier and the ADC and consisting of series-connected shaper of a single-band signal and a coherent detector, the reference input of which is connected to the second input, is introduced into the known device on the transmitting side the shaper to which the auxiliary carrier frequency generator is connected through the frequency divider 2 times, and on the receiving side a doubler of the frequency band of the transmitted izkochastotnogo signal, a frequency doubler, a coherent detector, the reference input of which is connected to the output of the oscillator carrier frequency shaper single-sideband signal through a second frequency doubler.

Description

The utility model relates to the field of radio engineering, namely to the transmission of noise-like signals with phase shift by 180 °.

Known digital communication systems with phase-manipulated noise-like signals (SHPS), described in various sources, for example:

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

2. Volkov A.A. Radio transmitting devices. - M.: Route, 2002.

3. A.S. 1506506 (USSR) MKI HO3s 1/52 Shaper of a single-band signal / A.A. Volkov Priority from 10.02.873

In known systems, a digital communication system with phase-manipulated noise-like signals is described [1], and only a transmitter of noise-like signals corresponding to [2] is described. Currently, a shaper of a single-band signal with a halved band (0.5 OBPAM) is known [3].

By technical nature, the system closest to the proposed utility model is described in [1], which, for this reason, is taken as a prototype model.

The system consists of a transmitter, a receiver and a communication line between them.

The prototype - the transmitter consists of a series-connected microphone, microphone amplifier, ADC, 180 ° phase manipulator, balanced modulator, amplifier, antenna, and also a synchronized subcarrier synchronizer and a ShSS generator through which the first input of the phase manipulator is connected to its second input, and

generator oscillations of the carrier frequency connected to the second input of the balanced modulator.

The prototype - the receiver consists of a series-connected antenna, a frequency converter, a frequency converter, a matched filter, a solver, a trigger, a DAC, as well as a synchronizer and a local oscillator connected in series through which the output of the matched filter is connected to the second input of the frequency converter; the output of the synchronizer is also connected to the second input of the deciding device.

The main indicators of the communication system with the NPS are determined by the value of the base B of noise-like signals, which is equal to the product of the duration T of the digital signal element by the frequency bandwidth F of the NPS, i.e. B = FT. Such indicators include: noise immunity, the number of channels in a given frequency band, the accuracy of determining the object's motion parameters, and others. Since the frequency resource is very scarce, it is very important to increase the signal base in a given frequency band.

The main disadvantage of the prototype is the relatively small base In noise-like signals in a given frequency band F.

The technical result of the claimed object is to increase the base B in a given frequency band by dividing the frequency band of the transmitted low-frequency (speech) signal.

The essence of the model lies in the fact that the prototype is a transmitter consisting of a series-connected microphone, microphone amplifier, ADC, 180 ° phase manipulator, balanced modulator, amplifier, antenna, as well as sequentially connected synchronizer and generator of BPS subcarriers through which the first input the phase manipulator is connected to its second input, and the oscillator of the carrier part connected to the second input of the balanced modulator, a 2 times divider of the frequency band of the speech signal is inserted, included between the mic fonnym amplifier and ADC, and in prototype - the receiver, consisting of

serially connected antennas, frequency converters, amplifiers, matched filter, solver, trigger, DAC, as well as serially connected synchronizer and local oscillator, through which the output of the matched filter is connected to the second input of the frequency converter; the synchronizer output is also connected to the second input of the deciding device; a doubler of the frequency band of the speech signal is introduced.

A significant difference between the model is the totality of the introduced elements and their relationships, because only they allow to increase the base of ШПС by 2 times in a given frequency band and thereby increase the noise immunity of reception, the number of channels in a given band, the accuracy of determining the motion parameters of an object, and others.

Figure 1 presents the structural diagram of the proposed transmitter, and figure 2 - the receiver.

The digital circuit consists of: 1 - a microphone, 2 - a microphone amplifier, 3 - a single-band signal shaper with a 2-fold frequency band (0.5 OBP AM), 4 - an auxiliary carrier frequency generator, 5 - a coherent detector, 6 - a frequency divider 2 times, 7-analog-to-digital converter (ADC), 8 - 180 ° phase manipulator, 9 - generator of noise-like carrier signals, 10 - synchronizer, 11 - balanced modulator, 12 - carrier generator, 13 - amplifier, A - antennas, 14 - frequency converter, 15 - local oscillator, 16 - intermediate frequency amplifier current amplifiers (UPCH), 17 - matched filter, 18-synchronizer, 19 - resolver, 20 - digital signal regenerator (trigger), 21 - DAC, 22 - single-band signal shaper, 23 - auxiliary carrier generator, 24.25 - frequency doubler , 26 coherent detector.

The entered elements are circled in dashed lines: in the transmitter, the divider is 2 times the frequency band of the modulating signal, and in the receiver is the doubler of the frequency band of the received low-frequency signal.

The operation of the transmitter circuit is illustrated by timing diagrams in figure 3 and occurs as follows.

The input analog (speech) signal from the microphone 1 b (t) = U (t) cosφ (t), where U (t), φ (t) is the envelope and phase of this signal, amplified in block 2 and through it in block 3 one side band of frequencies u ₃ (t) = U (t) cosO, 5 [ωt + φ (t)] is formed in half. This signal 0.5 OBP AM is fed to the information input of the coherent detector 5, to the reference input of which the auxiliary carrier frequency oscillation U ₆ (t) = U ₄ (t) cosωt from the generator 4 is fed through the frequency divider 6. The coherent detector consists of a signal multiplier and low-pass filter. The output of the detector multiplier voltage

The low-frequency detector of the detector passes to its input only a low-frequency signal (the first term) with a frequency band divided in half, which is fed to the input of an analog-to-digital converter (ADC) 7. The first operation of the ADC is to sample the low-frequency signal in time according to Kotelnikov's theorem. According to this theorem, the sampling frequency F ₀ is chosen equal to or greater than twice the maximum frequency of the spectrum of the low-frequency signal. For speech, F ₀ = 8 kHz, and the sampling period T = 1 / F ₀ = 125 μs.

Since in the circuit of Fig. 1 the low-frequency signal band is reduced by 2 times, the sampling period corresponds to a doubling of the digital signal element, i.e. instead of T, you need to take 2T.

From the output of the ADC 7, an alternating digital signal g ₇ (t) (Fig. 3) is fed to the low-frequency input of the phase manipulator 8 and to the input of the synchronizer 10. A subcarrier - ShPS carrier u ₉ (t) is fed to the high-frequency input of block 8 (Fig. 3 ) from block 9, synchronized by the front of the digital signal. Phase manipulator 8 is a

a signal multiplier and, therefore, the phase of the NPS at its output u ₈ (t) will change by 180 ° according to the sign of the digital signal, as shown in Fig. 3. From multiplication, an element of a digital signal with a duration of 2T is divided into N binary (binary) elements of an APS of duration τ ₀ :

N = 2T / τ ₀ = 2T · F = 2B.

It can be seen that ShPS B base doubled as proposed. Information SHPS from block 8 is fed to one input of a balanced modulator (multiplier) 11, the second input of which is a harmonic oscillation of the carrier frequency from block 12. In block 11, the information SHPS is transferred to the operating frequency of the transmitter, after which it is amplified in block 13 and emitted by antenna A .

On the receiving side (Fig. 2), the signal from the antenna is fed to one input of the frequency converter 14, to the second input of which the oscillation of the local oscillator 15. From the output of block 14, the intermediate frequency signal after amplification in block 16 is fed to the input of the matched filter 17. In block 17 code combinations are converted into single pulses u ₁₇ (t) shown in figure 4. These pulses are fed to the input of the deciding device 19 and to the input of the synchronizer 18. The synchronizer is a series of half-wave rectifier with active load and one-shot, output pulses u ₁₈ (t), which is shown in figure 4. These pulses synchronize the local oscillator 15 and control the operation of block 19. Using single pulses u ₁₇ (t) from block 19, a digital signal is restored in block 20, which is fed to the input of the DAC 21. By the low-frequency analog signal, u ₈ (t) = U (t) cos0.5φ (t) from block 21, a single-band signal is formed u ₀ (t) = U (t) cos [ωt + 0.5φ (t)] in block 22 on an auxiliary carrier from the generator 23, which doubles in frequency in block 24 and then this single-band signal is coherently detected in block 26, according to the reference oscillation from the generator 23, doubled in frequency in block 25:

It can be seen that the transmitted signal b (t) = kU (t) cosφ (t) takes place at the output of block 26, where k is a constant factor. The low-pass filter of block 14 eliminates the high-frequency component (rf) - the second term.

The technical and economic effect of this utility model is a 2-fold increase in noise immunity, an increase in the number of channels in a given frequency band, and an increase in the accuracy of determining the object's motion parameters (coordinates, speeds, etc.).

Claims (1)

Digital communication system with phase-manipulated noise-like signals (SHPS), consisting on the transmitting side of a microphone, microphone amplifier, ADC, 180 ° phase manipulator, balanced modulator, amplifier, antenna, as well as synchronized synchronizer and generator of ShSS subcarriers through which the first input of the phase manipulator is connected to its second input, and the oscillator of the carrier part connected to the second input of the balanced modulator, and on the receiving side from antenna, frequency converter, intermediate frequency amplifier (IF), matched filter, solver, trigger, DAC, as well as serially connected synchronizer and local oscillator, through which the output of the matched filter is connected to the second input of the frequency converter; the synchronizer output is also connected to the second input of the deciding device, characterized in that a frequency divider of 2 times the modulating signal, connected between the microphone amplifier and the ADC and consisting of a serially connected shaper of a single-band signal and a coherent detector, the reference input of which is input, is introduced into it on the transmitting side connected to the second input of the shaper, to which the auxiliary carrier frequency generator is connected through the frequency divider 2 times, and on the receiving side a doubler p frequency bands of the transmitted low-frequency signal, consisting of a serially connected single-band signal shaper, a frequency doubler, a coherent detector, the reference input of which is connected to the output of the carrier-frequency oscillator of the single-band signal shaper through a second frequency doubler.