RU2163053C2 - Radio link - Google Patents

Abstract

FIELD: radio communications; space and ground passive sonars; frequency-reuse radio communication systems. SUBSTANCE: proposed link has on sending end main-message signal generator, power splitter, first and second amplitude modulators, paraphase amplifier, and transmitting system; on receiving end it has receiving antenna, adder, subtractor, synchronous detector, amplitude limiter, demodulator, narrow- band low-frequency filter, and polarization changer. Newly introduced on sending end are frequency synthesizer, decoder, standard generator, pseudo- random sequence generator, synchronizer, and adder; introduced on receiving end are standard generator, clock generator, frequency synthesizer, divider, shift register, code converter, synchronizer, n switches, n band filters, adder, frequency mixer for first and second band filters, processing unit, and low- frequency filter. EFFECT: increased amount of data transmitted, reduced time taken for transmitted data retrieval, improved immunity to lumped and impulse noise. 4 dwg

Description

 The proposed device relates to the field of radio communications and can be used in space and ground-based radio communication systems with frequency reuse.

 Known devices using polarization modulation of a radio signal, in particular with elliptical polarization of the wave by changing the parameters of the polarization ellipse (G.K. Gusev, A.D. Filatov, A.P. Sopolev. Polarization modulation. M .: Sov. Radio, 1974, p. 63-161).

 The disadvantage of these devices is that they can be used in conditions where the propagation parameters of the signals along the path and the relative position of the transmitting and receiving antennas are constant, since 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 orthogonality in polarization of two simultaneously transmitted signals with circular or linear polarization. This orthogonality is supported by an automatic target 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 with mutually orthogonal polarization of the wave. A receiving device providing 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 claimed object is a "Radio communication device with frequency reuse" according to copyright certificate N 1385305, adopted as a prototype.

 But this device has a low noise immunity with respect to concentrated and pulsed interference, as well as a significant search time for received information.

To increase the noise immunity with respect to concentrated and impulse noise and to reduce the information search time, to a device containing a main message signal generator on the transmitting side, the main input of which is supplied with basic information S _о , and the output is connected to the input of a power splitter, two outputs of which are connected respectively, with the first inputs of the first and second amplitude modulators, the second inputs of which are connected respectively to the first and second transmitting antenna feeds, at On my side of the first and second receiving antenna drivers are connected respectively to two inputs of a polarization rotation device, two outputs of which are connected respectively to two inputs of the first adder and two inputs of a subtractor, a synchronous detector, one of whose inputs is connected to the output of the amplitude limiter, and the output of a synchronous detector through a narrow-band low-pass filter, a demodulator of main messages is connected to the control input of the polarization rotation device, the output of which is lower aetsya General information S _est, introduced at the transmitting end a frequency synthesizer whose output is connected to the second input key messages signal generator, and the n inputs of a frequency synthesizer connected respectively to the n outputs of the decoder, whose input is connected to the first output of the generator cap, a second output connected to the first inputs of the adder and synchronizer. Additional information S _add is supplied to the second input of the synchronizer, the output of the synchronizer is connected to the second input of the adder, the output of which is connected to the input of the paraphase amplifier, the reference generator, the output of which is connected to the input of the PSP generator.

On the receiving side, a reference oscillator, the output of which is connected to one of the inputs of the frequency synthesizer and through the pulse shaper, to one of the inputs of the synchronizer, the second input of which is connected to the first input of the shift register and the output of the processing unit, the output of the synchronizer through the divider is connected to the second input shift register, n outputs of which are connected respectively to the control inputs of n keys and n inputs of the code converter, n outputs of which are connected respectively with n inputs of the frequency synthesizer, the output is The input is connected to the heterodyne input of the mixer, the signal input of which is connected to the output of the second adder, n inputs of the second adder are connected respectively to the outputs of n band filters, the input of each of which is connected respectively to the outputs of one of the n keys, the inputs of which are connected to each other and to the output of the amplitude limiter, the first band-pass filter, the input of which is connected to the output of the subtractor, and the output - with one of the inputs of the synchronous detector, the second band-pass filter, the input of which is connected to the output of the first th adder, and an output - to the input of the amplitude limiter, a low pass filter having an input connected to the output of the synchronous detector, and an output - to the input of the processing unit, the output of which is removed more information S _ext.

In FIG. 2, 3 shows a functional diagram of the proposed device, where it is indicated:
1 - signal generator of the main messages,
2 - power splitter,
3, 4 - the first and second amplitude modulators,
5 - paraphase amplifier,
6, 7 - the first and second transmitting antenna feeds,
8 - transmitting antenna,
9, 10 - the first and second pathways of the receiving antenna,
11 - receiving antenna,
12 - the first adder
13 is a subtractive device,
14 - synchronous detector,
15 is an amplitude limiter,
16 - demodulator of the main messages,
17 - narrowband low-pass filter,
18 - device rotation polarization,
19 - transmitter frequency synthesizer,
20 - decoder,
21 - generator PSP,
22 - reference generator of the transmitter,
23 - the first band-pass filter,
24 - low pass filter,
25 is a processing unit,
26 is a second band-pass filter,
27 - reference generator of the receiver,
28 - shaper of clock pulses,
29 - synchronizer,
30 is a divider
31 - shift register
32 - code converter,
33 - receiver frequency synthesizer,
34 - 34n - keys,
35 - 35n - bandpass filters,
36 is a second adder,
37 - mixer
38 - transmitter adder,
39 - transmitter synchronizer.

 The proposed device has the following functional relationships.

The transmitting device - the signal generator main posts 1, a first input of which is fed the basic information S _est its output connected to the input of the power splitter 2, the two outputs of which are connected respectively to the first inputs of the first 3 and second 4 of the amplitude modulator, the second inputs of which are connected respectively with the first and the second outputs of the paraphase amplifier, the outputs of the first 3 and second 4 amplitude modulators are connected respectively to the first 6 and second 7 irradiators of the transmitting antenna 8, the reference generator 22 voim output connected to the input of the generator SRP 21, one of which is connected to the inputs the outputs of the adder 38 and the synchronizer 39, to the second input of which is supplied to the additional S _extra information synchronizer output 39 via the adder 39 via the adder 38 is connected to the input of paraphase amplifier 5, the second output the generator PSP 21 is connected to the input of the decoder 20, n outputs of which are connected respectively to n inputs of the frequency synthesizer 19, the output of which is connected to the input of the signal generator of the main messages 1.

The receiving device - the first 9 and second 10 exciters of the receiving antenna 11 through the polarization rotation device 18 are connected respectively to two inputs of the first adder 12 and two inputs of the subtracting device 13, the output of the subtracting device 13 through the first band-pass filter 23 is connected to one of the inputs of the synchronous detector 14, the second input of which is connected to the inputs of n keys 34 ₁ - 34 _n and to the output of the amplitude limiter 15, the input of which through the second band-pass filter 26 is connected to the output of the first adder 12. The output of the synchronous detector and 14 through a narrow-band low-pass filter 17 is connected to the control input of the polarization rotation device 18, and through a low-pass filter 24 is connected to the input of the processing unit 25, from the output of which additional information S _add is removed, and the second output of the processing unit is connected to the synchronizing inputs of the synchronizer 29 and shift register 31. The output of the reference generator 27 is connected to the inputs of the frequency synthesizer 33 and the clock shaper 28, the output of which through the synchronizer 29 is connected to the input of the divider 30. The output of the divider 30 and is connected to the input of the shift register 31, the n outputs of which are connected respectively to the control inputs of the n keys 34 ₁ - 34 _n, respectively, and the n inputs of the code converter 32, the n outputs of which are connected to the n inputs of the frequency synthesizer 33, the output of which is connected to the heterodyne input of the mixer 37. The outputs of the n keys 34 ₁ - 34 _n through the corresponding band-pass filters 35 ₁ - 35 _{n are} connected respectively to the n inputs of the second adder 36, and the output of this adder is connected to the signal input of the mixer 37, the output of which is connected to the input of the demodulator 16, with the output of which is removed basic information S _DOS .

 According to the materials of domestic and foreign literature, signals with an extended spectrum of the class of discrete frequency (DF) and discrete composite frequency (frequency-manipulated) phase-shift signals (DSC-FM, DSC-FM) are of some interest.

 The main difference between the PM and the phase-shifted signals, the FM, is that for the same base, the FM signals have a smaller region of strong correlation compared to the FM signals. (The region of strong correlation is understood as the time-frequency domain of signal integration implemented in the apparatus taking into account the well-known assumptions in the sense of Fourier transforms for finite signals).

 As noted by several authors, the multifrequency of the DF signals makes them very promising, since it becomes possible to "weighted" the distribution of the signal energy by frequency and time directly inside the frequency - time domain (FT).

 The proposed device operates as follows.

 The reference generator 22 generates sinusoidal oscillations of a certain frequency, which are supplied to the generator 21 to obtain a pseudorandom sequence signal (PSS) of the required structure.

 The generator 21, in addition to the PSP, generates installation pulses (Fig. 2, position 2), the beginning and period of which coincides with the beginning and period of the PSP (information pulses).

 The implementation of such generators is given in the book Petrovich N.T., Razmakhnin M.K. Communication systems with noise-like signals. M .: Sov. radio, 1969, p. 146.

 Setting pulses with a period T generated by the generator 21 are used for fast synchronization along the channel of additional polarization modulation. Moreover, T = nτ, where n is the number of frequency positions, τ is the duration of one frequency position (see Fig. 2).

 The signal in the form of a bandwidth from the generator 21 through two outputs (channel "1" and channel "0") is supplied to a decoder 20, in which the structure of the bandwidth is converted to the code necessary to obtain the desired frequencies in the synthesizer 19. The synthesizer 19 generates frequencies, such as shown in FIG. 4.

In FIG. Figure 4 shows the time-frequency plane, on which the energy distribution of the MPS-FM signal is highlighted by shading. Such a signal from the frequency synthesizer 19 is supplied to one of the inputs of the oscillation generator 1 of the main messages, to the second input of which the signal of the main messages is supplied, to the second input of which the signal of the main information S _main . In the generator 1, a signal is generated that is modulated in phase by the main message in each of the n frequency positions. This signal is fed to a power splitter 2, where its power is divided in half and each half is issued, respectively, by two outputs to amplitude modulators 3 and 4.

Additional information S _additional is supplied to one of the inputs of the synchronizer 39, and the installation pulses (see Fig. 1, pos. 2) from the PSP 21 generator are supplied to the second input.

In the synchronizer 39 is a tight synchronization of additional information S _additional installation pulses and a time delay to obtain a protective interval (Fig. 1, pos. 8).

 The guard interval is introduced to separate the signals along the channel of additional polarization modulation. For reliable separation of information, the guard interval should be approximately equal to five clock intervals. The signal from the output of the synchronizer (Fig. 1, pos. 8) is supplied to one of the inputs of the adder 38, to the second input of which the installation pulses are supplied from the generator 21. In the adder 38, two signals are added and as a result a signal is obtained, as shown in FIG. . 1, pos. 9.

 This signal from the output of the adder 38 is supplied to the paraphase amplifier 5.

In amplitude modulators 3 and 4, the amplitude of the incoming main signals changes out of phase according to the law of additional messages S _add , using the voltages taken from the paraphase amplifier 5. From the outputs of the amplitude modulators 3 and 4, the signal is supplied to the transmitters 6 and 7 of the transmitting antenna 8, respectively. 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 (with pathogens 9, 10), made similar to the transmitting antenna.

 The signals received by the receiving antenna 11 through the polarization rotation device 18 are fed to the inputs of the adder 12 and the subtractor 13. The adder performs partial smoothing of the amplitude modulation and this signal through a bandpass filter 26 having a passband ΔF = nΔf, where n is the number of frequency positions (equal to the number of elements of the SRP) and through the amplitude limiter 15 is supplied to one of the inputs of the synchronous detector 14 as a reference signal.

At the other input of this synchronous detector, a signal is received from the output of the subtractor 13 through a bandpass filter 23 having the same passband as filter 26. From the output of the synchronous detector 14 through the low-pass filter 24, the signal is fed to the processing unit 25, which extracts additional information S _additional . Installation pulses are removed from the other output of processing unit 25, the period of which is equal to the period of the memory bandwidth and the beginning of their periods coincides (see Fig. 1, positions 2, 4, 5, 6, 7). The set pulses are fed to the synchronization unit 29, where they synchronize the clock pulses generated by the clock generator 28 (Fig. 1, position 1) from the oscillations of the master oscillator 27. The clock pulses synchronized with the set pulses are sent to the divider 30, where dividing the clock so that in the period T there are n clock pulses (Fig. 1, position 3), which then is fed from the divider 30 to the shift register 31, to the synchronizing input of which the set pulses are received s. From the n outputs of the shift register 31, pulses are sent to the code converter 32, in which codes are generated and which are outputted to the frequency synthesizer 33 at the n outputs to generate n frequencies necessary as the local oscillator frequencies for the mixer 37. Clock pulses are fed to the clock input of the frequency synthesizer 33 from the generator 27.

From the n outputs of the shift register 31, in addition, the pulses are respectively supplied to the control inputs of the keys 34 ₁ - 34 _n , to the signal inputs of which the main information signal is supplied from the output of the amplitude limiter 15. The main information signal is through the public key 34 ₁ - 34 _n (keys open in a certain sequence, depending on the time of arrival of pulses from shift register 31) and a narrow-band filter 35 ₁ - 35 _n , having a passband Δf = ΔF / n, where n is the number of frequency positions (equal to the number of elements of the SRP), and ΔF - bandwidth pass Nia input of the receiver (in particular, filters 23 and 26) is supplied to the adder 36 and the output of the adder - the signal input of mixer 37.

 From the output of the mixer 37, the signal enters the demodulator 16, from the output of which the basic information is removed.

 Thus, the introduction of installation pulses transmitted through an additional channel allows them to quickly synchronize clock pulses at the receiver, which can significantly accelerate the search for information. In addition, the proposed device can improve noise immunity by n times compared with the prototype device (n is the number of frequency positions equal to the number of elements of the SRP).

 The implementation of the proposed device does not cause any difficulties, since all the blocks and nodes included in it are well known and widely published in the technical literature.

Claims (1)

 A radio communication line containing on the transmitting side a signal generator of the main messages, one of the inputs of which is the input of the main information, and the output is connected to the input of the power splitter, for the output of which are connected respectively to the first inputs of the first and second amplitude modulators, the second inputs of which are connected respectively to two the outputs of the paraphase amplifier, the outputs of the first and second amplitude modulators are connected respectively to the first and second irradiators of the transmitting antenna, at the receiving In the torone, the first and second drivers of the receiving antenna are connected to two inputs of the polarization rotation device, two outputs of which are connected respectively to the first and second inputs of the first adder and subtractor, an amplitude limiter whose output is connected to one of the inputs of the synchronous detector, the output of which is connected to a narrow-band low-frequency filter, and a demodulator, the output of which is the output of the basic information, characterized in that a frequency synthesizer is introduced on the transmitting side, the output of which connected to the input of the signal generator of the main messages, and n inputs of this frequency synthesizer are connected respectively to n outputs of the decoder, the input of which is connected to one of the outputs of the PSP generator, the input of which is connected to the output of the reference generator, and the output of the PSP generator is connected to the first inputs of the synchronizer and adder , additional information is supplied to the second input of the synchronizer, and the second input of the adder is connected to the output of the synchronizer, and the output of the adder is connected to the input of the paraphase amplifier, at the receiving The reference generator was introduced on the toron, the output of which is connected to the input of the frequency synthesizer and through the clock generator to the first input of the synchronizer, the second input of which is connected to the output of the processing unit and one of the inputs of the shift register, the second input of which is connected through the divider to the output of the synchronizer, n outputs the shift register are connected respectively to the control inputs of n keys and n inputs of the code converter, n outputs of which are connected respectively to n inputs of the frequency synthesizer, the output of which is connected n with the heterodyne input of the mixer, the inputs of n keys are connected to each other and with the output of the amplitude limiter, and the outputs of the keys, respectively, through n bandpass filters are connected to n inputs of the second adder, the output of which is connected to the signal input of the mixer, and the output of this mixer is connected to the input of the demodulator, the first band-pass filter, the input of which is connected to the output of the subtracting device, and the output is connected to the input of the synchronous detector, a low-pass filter, the input of which is connected to the output of the synchronous detector, and the output through bl ok of processing - with the second input of the synchronizer, the second bandpass filter, the input of which is connected to the output of the first adder, and the output - to the input of the amplitude limiter, additional information is removed from the output of the processing unit, the output of the narrow-band low-pass filter is connected to the control input of the polarization rotation device.

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