RU2069035C1 - Multichannel radio communication device - Google Patents

Abstract

FIELD: space and ground radio communication lines. SUBSTANCE: multichannel radio communication line has main-message signal generator 1, power splitter 2, amplitude modulators 3, 4, paraphase amplifier 5, transmitting antenna feeds 6, 7, transmitting antenna 8, receiving feeds 9, 10, receiving antenna 11, adders 12, 20, subtracting unit 13, synchronous detector 14, amplitude limiter 15, main-message detector 16, narrow-band low-frequency filter 17, polarization reversal unit 18, master oscillator 19, 90-deg phase shifters 21, 28, signal generator 22, coders 23, 24, multipliers 25, 30, low-frequency filters 26, 31, decoders 27, 32, reference- voltage generator 29. EFFECT: improved design. 1 dwg

Description

 The proposed device relates to the field of radio communications and can be used in space and terrestrial radio links.

 Known devices using polarization modulation of radio signals, in particular, with elliptical polarization of the wave by changing the parameters of the ellipse of polarization (see Gusev K. G. A. Filatov, A. P. Sopolev "Polarization modulation. M." Sov. Radio " 1974 p. 63161).

 The disadvantage of these devices is that they can be used in conditions where the propagation parameters of the signals along the highway and the relative position of the transmitting and receiving antennas are constant, because otherwise a large level of mutual interference between the individual channels of the radio line occurs. However, in most practical cases, both the propagation parameters of the signals and the relative position of the antennas change.

 A device is also known according to US patent N 4087818, in which frequency reuse in conditions of changing the parameters of the signal propagation medium and the relative position of the antennas is achieved by ensuring polarization orthogonality of two simultaneously transmitted signals with circular or linear polarization. This orthogonality is maintained using an automatic circuit in the form of a closed loop control using special pilot signals. It contains a transmitting device that generates two signals with the same frequency and orthogonal polarization of the wave, a receiving device that provides separate reception of these signals due to their orthogonal polarization.

 However, this device, due to the high requirements for the necessary accuracy of ensuring orthogonality in the polarization of the transmitted signals, has a complex auto-tuning system. In addition, the implementation of this device requires a special additional communication line.

 Closest to the technical nature of the proposed device is the copyright certificate N 1385305, presented in Fig. 1.

 The radio communication system comprises a signal generator 1, a power splitter 2, amplitude modulators 3, 4 an out-of-phase amplifier 5, transmitting antenna irradiators 6 and 7, 8, receiving antenna irradiators 9 and 10, a total-difference unit 12, consisting of an adder 13 and a subtractor 14, synchronous detector 15, demodulator 16 of the main message, amplitude wrench 17, low-pass filters 18 and 19, low-pass filter 20, block for controlling the position of the polarization axes of the receiving antenna irradiators, key 21, phase detector 22, phase shifter 23, delay lines 24 and 25, and a comparator 26.

 The main message demodulator consists of a phase detector (PD) 27, a low-pass filter 28 and a voltage-controlled generator 29.

The prototype device operates as follows. The generator 1 generates a sinusoidal signal, modulated in frequency or phase by the main messages, which has the form
U _c (t) = Ucos [ωt + Φ (t)] (1)
where U is the constant amplitude of the signal
Φ (t) is the function of changing the phase of the signal corresponding to the frequency or phase modulation.

 This signal is fed to a power splitter 2, where the signal power is divided in half and is issued respectively at two outputs to amplitude modulators 3, 6, made in the form of high-frequency amplifiers.

где U₁ постоянная амплитуда,
f(t) функция изменения амплитуды сигналов, соответствующая дополнительным сообщениям S_д.In modulators 3 and 4, the amplitude of the incoming signals changes out of phase according to the law of the transmitted additional messages S _d using the voltages removed from the paraphase amplifier 5. In this case, the signals at the outputs of the amplitude modulators 3 and 4 will be

where U ₁ constant amplitude
f (t) the function of changing the amplitude of the signals corresponding to additional messages S _d .

 Signals (2) and (3) are fed to the inputs of the irradiators 6 and 7 of the transmitting antenna 8, which can be implemented as a mirror antenna with two irradiators or in the form of vibrator antennas with corresponding pathogens. Irradiators 6 and 7 create fields with orthogonal linear or circular polarization relative to one another. The signals emitted by the transmitting antenna 8 are received by the receiving antenna 11. Its irradiators (pathogens) 9 and 10 have orthogonal linear or circular polarization. The receiving antenna 11 with irradiators 9 and 10 is made similar to the transmitting one.

Эти сигналы поступают на входы сумматора 12 и вычитающего устройства 13, при этом на выходе сумматора 12 получим

а на выходе вычитающего устройства 13

Сигнал (6) с выхода сумматора 12 поступает на вход амплитудного ограничителя 15, на выходе которого при угле рассогласования

и достаточно низком уровне ограничения будет иметь вид
•cos[ωt+Φ(t)] (7)
где V_огр эффективная амплитуда ограниченного сигнала.The output of the irradiators 9 and 10 of the receiving antenna 11 will receive a signal

These signals are fed to the inputs of the adder 12 and the subtractor 13, while the output of the adder 12 will receive

and at the output of the subtractor 13

The signal (6) from the output of the adder 12 is fed to the input of the amplitude limiter 15, the output of which at the angle of mismatch

and a fairly low level of restriction will look like
• cos [ωt + Φ (t)] (7)
where V _{ogre is the} effective amplitude of the limited signal.

 The signal (7) is supplied to the synchronous detector 14 as a reference and simultaneously to the demodulator 16 of the main messages. The signal input of the synchronous detector 14 receives a signal from the subtractor 13.

At the output of the synchronous detector 14 in the low frequency region, we obtain a signal
(t) = KV ₀ [f (t) cosα-sinα] (8)
where K is the gain of the synchronous detector.

As can be seen from expression (8), the signal S _cd contains a constant component, the sign of which depends on the sign of the angle of mismatch α. In this case, this component of growth
U = -KV ₀ sinα (9)
This component is extracted using a low-pass narrow-band filter 17 and fed to the control device 18 of the position of the polarization axes of the irradiators (pathogens), which will turn the irradiators so that the angle α becomes zero. If there is a mismatch in the other direction (angle a is negative), this component will be positive, the irradiators will be turned in the opposite direction.

 The low-pass narrow-band filter 17 has a bandwidth significantly smaller than the spectrum bandwidth of the function f (t), so that it can only transmit slowly changing signals due to changes in the overlapping of the antennas.

 The control device 18 of the position of the axes of polarization of the irradiators of the receiving antenna using the voltage supplied from the filter 17, eliminates the mismatch between the polarization of the incoming signals and the polarization of the irradiators of the receiving antenna. In this case, the control system operates on a received signal that carries information about the transmitted messages.

But this prototype device has small functionality, since there is the possibility for the simultaneous transmission of only two main message sources S _o and additional S _d .

To eliminate this drawback, a prototype device containing a source of basic information on the transmitting side, a power splitter, the two outputs of which are connected respectively to the inputs of the first and second amplitude modulators, the second inputs of which are connected to the outputs of the paraphase amplifier, the input of which is supplied with the first additional information, and the outputs of the amplitude modulators are connected to the irradiators of the transmitting antenna, on the receiving side there are two irradiators (pathogens) of the receiving antenna through the rotation device along The polarization is connected to the inputs of the adder and subtractor, the output of which is connected to the signal input of the synchronous detector, the second (reference) input of which is connected through the amplitude limiter to the output of the adder, the output of the synchronous detector through a narrow-band low-pass filter is connected to the control input of the polarization rotation device, the driver is introduced on the transmitting side generator, whose output is connected to the input of the first signal generator (first phase manipulator), a phase shifter 90 ^o, whose input is connected to the output of the master for generators and a second signal generator (second phase arm), whose input is connected to the output of the phase shifter 90 ^o and an adder, two inputs of which are connected to the outputs of the first and second oscillator signal, and an output connected to the input of the splitter output and two encoder RPM, the outputs of which respectively connected to the second inputs of the first and second signal generators, on the receiving side of the reference oscillator, the input of which is connected to the output of the amplitude limiter, two multipliers, the first inputs of which are connected between each other and with the output of the amplitude limiter, and the output of each of the multipliers is connected in series with the low-pass filter and the OFM decoder and a 90 ^o phase shifter, the input of which is connected to the output of the reference oscillator and the second input of the second multiplier, and the output is connected to the second input of the first multiplier.

In FIG. 2 shows a functional diagram of the proposed device, where designations are given: from 1 to 18, such as in the prototype device; 19 master oscillator; 20 adder; 21 phase shifter 90 ^o ; 22 second signal generator; 23, 24 first and second OFM encoders; 25, 30 first and second multipliers; 26, 31 of the first and second low-pass filters; 27, 32 first and second OFM decoders; 28 phase shifter 90 ^o ; 29 shaper reference oscillations.

 The proposed device has the following connections.

On the transmitting side, the master oscillator 19, the output of which is connected to the inputs of the first signal generator 1 and the phase shifter 21 by 90 ^o , the output of which through the second signal generator 22 is connected to one of the inputs of the adder 20, the second input of which is connected to the output of the first signal generator 1, and the output of the adder 20 is connected to the input of the power splitter 2, the two outputs of which are connected respectively to the inputs of the first 3 and second 4 amplitude modulators, the second inputs of which are connected to the outputs of the paraphase amplifier 5, the outputs of the amplitude m modulators are respectively connected with the first 6 and second 7 irradiators transmit antenna 8 and the first 23 and second 24 encoders RPM, outputs connected respectively to second inputs of the first 1 and second 22 signal generators.

 On the receiving side, the first 9 and second 10 exciters of the receiving antenna 11 are connected through the polarization control device 18 to the inputs of the adder 12 and subtractor 13, the output of which through the synchronous detector 14 and the narrow-band low-pass filter 17 is connected to the control input of the polarization control device 18, the output of the adder 12 through an amplitude limiter 15 is connected to the reference input of the synchronous detector 14, with the inputs of the first 25 and second 30 multipliers and the input of the reference oscillator 29, the output of which is connected to the second input of the second multiplier 30 through a phase shifter 29 and to a second input of the first multiplier, the output of which through the first LPF 26 is connected to an input of first decoder 27 RPM, and the output of the second multiplier 30 through a second LPF 31 is connected to the input of the second decoder 32 GMM.

The proposed device operates as follows. The master oscillator 19 generates an initial sinusoidal oscillation with the required parameters - frequency, amplitude, stability, etc. which is then fed to the input of the first 1 signal generator directly and to the input of the second 22 through the phase shifter 21 by 90 ^° .

Information signals S ₀ and S ₀₁ to be transmitted are respectively supplied to the inputs of the first 23 and second 24 OFM encoders (relative phase shift keying), in which when a single symbol arrives, the phase is rotated by 180 ^o and when the zero symbol arrives, the phase remains unchanged. From the outputs of the first 23 and second 24 OFM encoders, the phase-converted information symbols arrive at the second inputs of the first 1 and second 22 signal generators, which can be represented as phase manipulators. In the signal generators 1 and 22, the phase of the sinusoidal oscillations of the carrier frequency, which is fed to their first inputs from the master oscillator 19, is manipulated according to the law of information signals S ₀ and S _01, respectively. From the outputs of the generators 1 and 22, the phase-manipulated signals are fed to the adder 20, the output of which, thus, results in a carrier frequency oscillation with a constant amplitude, phase-shifted by 0 ^o , 90 ^o , 180 ^o , 270 ^o .

This signal is fed to the input of a power splitter 2, where it is divided in half by power and by two outputs, fed respectively to the inputs of the first 3 and second 4 amplitude modulators, the second inputs of which are supplied in antiphase information symbols S _d from the outputs of the paraphase amplifier 5. Additional information S _d is fed to the input of the paraphase amplifier 5.

 The signal, modulated in amplitude in the amplitude modulators 3 and 4, is supplied from their outputs to the first 6 and second 7 irradiators of the transmitting antenna 8, which can be implemented as a mirror antenna with two irradiators or in the form of vibrator antennas with corresponding exciters. Irradiators 6 and 7 create fields with orthogonal to one another with linear or circular polarization.

 The signals emitted by the transmitting antenna 8 are received by the receiving antenna 11. Its irradiators (pathogens) 9, 10 have orthogonal linear or circular polarization. The receiving antenna 11 with irradiators 9, 10 is made similar to the transmitting antenna.

 The received signal from the irradiators 9, 10 through the control device 18 of the position of the polarization axes of the irradiators of the receiving system is fed to the inputs of the adder 12 and the subtractor 13.

 In the adder 12, the signal from the pathogens 9, 10 through the control device 18, the position of the polarization axes of the irradiators of the receiving antenna is fed to the inputs of the adder 12 and the subtractor 13.

 In the adder 12, the signal from the pathogens 9, 10 is summed with the simultaneous removal of amplitude modulation.

From the output of the adder 12, the signal with the amplitude modulation removed through the amplitude limiter 15 is fed to the input of the synchronous detector 14, as a reference signal to the input of the reference oscillator 29, where the fourth harmonic is extracted from this signal and fed to the multiplier, and the signal from master oscillator with a frequency equal to the fourth harmonic of the input signal. The result of multiplication through the low-pass filter is fed to the phase adjustment of the master oscillator. The signal from the output of the master oscillator through a divider of 4 is supplied as a reference to the multipliers 25 and 30, and to the multiplier 15 this signal is fed through the phase shifter 28 by 90 ^o (Yu. B. Okunev "Theory of phase difference modulation" M. "Communication", 1979 G. 69 (Fig. 2.14), the second inputs of the multipliers 25, 30 receives a signal from the amplitude limiter 15.

 From the outputs of the multipliers 25 and 30 through the low-pass filter 26 and 31, the signal is fed to the OFM 27 and 32 demodulators, respectively, at the output of which the transmitted information is highlighted.

 In the subtractor 13, the signal received by one irradiator is subtracted from the signal received by the second irradiator and, thus, the depth of amplitude modulation is increased. The difference signal from the subtractor 13 is fed to the signal input of the synchronous detector 14, the output of which is allocated additional information.

 From the output of the synchronous detector 14, the signal also goes to a narrow-band low-pass filter 17, in which a constant component is extracted, the sign of which depends on the sign of the angle of mismatch between the polarization of the incoming signals and the polarization of the irradiators of the receiving antenna. This constant component is supplied to the device 18 for controlling the position of the axes of polarization of the pathogens, with the help of which the irradiators are rotated so that the mismatch angle becomes zero. The low-pass filter 17 has a very narrow bandwidth, therefore, it only allows slowly changing signals due to changes in the position of the antennas.

 To transmit an ever-increasing amount of information, it is necessary to increase the transmission speed, as well as the number of radio channels, which in both cases leads to an expansion of the operating frequency band. And as you know, at present the range of radio frequencies, starting from the lowest VLF and ending with the highest microwave frequencies, is very overloaded. Therefore, the task of allocating any part of the radio frequency range is becoming increasingly problematic. The proposed device allows to some extent solve this problematic problem, in that it is possible to transmit information from three different sources, which is an advantage over the prototype device. YYY1

Claims (1)

A multichannel radio communication device containing a phase manipulator on the transmitting side, a power splitter whose outputs are connected to the inputs of the first and second amplitude modulators, the outputs of which are connected to the transmitting antenna feeds, and a phase-inverting amplifier, the outputs of which are connected to the second inputs of the amplitude modulators, and on the receiving side - a control unit for the position of the polarization axes of the receiving antenna feeds, the two inputs of which are connected to the receiving antenna feeds, and the control input is connected with the output of the first lowpass filter (LPF), the two outputs of the control unit the position of the axes of polarization irradiators receiving antenna connected to the corresponding input of the adder and subtractor, as well as a synchronous detector, the output of which is connected to the input of the first lowpass filter, second lowpass filter and phase shifter 90 ^o, wherein in that at the transmitting side administered serially connected driving oscillator, a phase shifter 90 ^o, the second phase manipulator, the adder, and the first and second coders introduced DPSK (RPM), The output of the master oscillator is connected to the input of the first phase manipulator, the second input of which is connected to the output of the first OFM encoder, the output of the first phase manipulator is connected to the adder input, the output of which is connected to the input of the power splitter, the output of the second OFM encoder is connected to the second input of the second phase manipulator, on the receiving side, the first and second multipliers are introduced, the inputs of which are connected to the output of the amplitude limiter, the output of which is connected to the input of the synchronous detector and the input of the reference oscillator, the output of which is connected to the second input of the second multiplier and through the phase shifter to the second input of the first multiplier, the output of which is connected to the input of the second low-pass filter, the first and second OFM decoders and the third low-pass filter are introduced, the output of the second low-pass filter is connected to the input of the first OFM decoder and the output of the second multiplier is connected through the third low-pass filter to the input of the second OFM decoder, the output of the subtractor is connected to the second input of the synchronous detector.

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