RU2368062C1 - Device for modulation-demodulation of troposphere station - Google Patents

Abstract

FIELD: physics, radio engineering.

SUBSTANCE: device for modulation-demodulation of troposphere station. Invention is related to the field of radio engineering, namely to facilities of troposphere radio communication and may be used in troposphere stations on lines of troposphere communication with improved throughput capacity. Device for modulation-demodulation of troposphere station comprises modulator that consists of digital demultiplexer, n six-bit series-parallel converters, n six-bit units of relativity converters validity (RCV), n six-bit digital-analog converters (DAC), n phase modulators and summator; demodulator comprising unit of optimal signal summation, n selective filters, n phase detectors, n six-bit analog-digital converters (ADC), n six-bit RCV units, n six-bit parallel-series converters and digital multiplexer, and also comprises unit of reference frequencies intended for creation of bearing frequencies used for functioning of modulator or demodulator. The novelty in device of troposphere station modulation-demodulation is making modulator and demodulator multi-channeled, including above-mentioned units, and also application of new algorithm of modulation and demodulation based on principle of digital information processing, which includes separation of digital flow into subflows (subchannels), transformation of absolute values of signal phase into relative ones and combination of information processed in each channel into single modulated group flow in process of transmission and reverse transformation in process of reception, which helped to provide for transmission of information along troposphere channel with higher speed.

EFFECT: provision of possibility to increase speed of discrete information transfer along troposphere communication channels.

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Description

The invention relates to the field of radio engineering, and in particular to tropospheric radio communications, and can be used in tropospheric stations on tropospheric communication lines with increased throughput.

Known tropospheric stations designed to provide stable communication in the centimeter wave range, which incorporate modulation-demodulation devices that provide a limited (up to 2 Mbit / s) transmission rate of discrete information in the tropospheric communication channel [1, 2, 5].

However, at present, due to the rapid development and widespread introduction of digital transmission systems, ever higher information transfer rates are required via tropospheric communication channels.

It is known that for transmitting discrete information, signals in the form of segments of harmonic oscillations are most often used. In such signals, either the amplitude, the frequency, or the phase is used as a modulating parameter. Hence the amplitude, frequency and phase modulation is called.

To ensure the possibility of transmitting information at a higher speed in the same frequency band and with the same noise immunity without increasing power, phase modulation, which is supposed to be used in the proposed modulation-demodulation device of the tropospheric station, has the greatest advantage.

Known amplitude modulator, which contains two phase modulators, an output adder and a reference generator [2]. However, this device has the disadvantage that in order to achieve this goal, a modulation method based on the expansion of the frequency range is used.

Of the known considered modulation-demodulation devices, the closest to the proposed invention is a modulation-demodulation device containing a group of transmit frequency converters (modulator) and reception (demodulator), as well as a block of reference (carrier) frequencies described in [4].

A disadvantage of the known device is that in it the modulator and demodulator are single-channel and are designed for one specific group transmission speed, which limits the possibility of using it as a modulation-demodulation device of a tropospheric station.

The aim of the invention is to provide the possibility of increasing the transmission rate of discrete information on tropospheric communication channels.

This goal is achieved in that in a tropospheric station modulation-demodulation device comprising a modulator, a demodulator and a block of reference frequencies, characterized in that the modulator is multi-channel and consists of a digital demultiplexer, n six-bit serial-parallel converters, n six-bit truth blocks of the relativity converter ( IPO), n six-bit digital-to-analog converters (DACs), n phase modulators and one adder, with the first, second and nth outputs of the digital demul Ixlexers are connected respectively to the inputs of the first, second and nth six-bit serial-parallel converters, the output of the first six-bit serial-parallel converter of the modulator is connected to the input of the first six-bit IPO block, the output of which through the first six-bit DAC is connected to the input of the first phase modulator, the output of the second six-bit a series-parallel converter is connected to the input of the second six-bit block IPO, the output of which is through the second the digital digitizer is connected to the input of the second phase modulator, the output of the nth six-bit serial-parallel converter of the modulator is connected to the input of the nth six-digit IPO block, the output of which is connected to the input of the nth phase modulator through the nth six-digit DAC, the outputs of the first, second and the n-th phase modulators are connected respectively to the first, second and n-th inputs of the adder, and the adder output is the output of the modulator to the transmitter, the input of which is the input of the digital demultiplexer; the demodulator is multi-channel and consists of a block of optimal signal addition, n selective filters, n phase detectors, n six-bit analog-to-digital converters (ADC), n six-bit IPO blocks, n six-bit parallel-serial converters and a digital multiplexer, while the first, second and The nth outputs of the block of optimal addition of signals of the demodulator are connected to the inputs of the first, second, and nth selective filters, the output of the first selective filter is connected to the input of the first a phase detector, the output of which is through the first six-bit ADC, the first six-bit block of the IPO demodulator and the first parallel-serial converter is connected to the first input of the digital multiplexer of the demodulator, the output of the second selective filter is connected to the input of the second phase detector, the output of which is through the second six-bit ADC, the second six-bit block IPO and the second parallel-serial converter is connected to the second input of the digital demodulator multiplexer, the output of the nth selectively about the filter is connected to the input of the nth phase detector, the output of which is through the nth six-bit ADC, the nth six-bit block of the IPO demodulator, the nth six-bit parallel-serial converter is connected to the nth input of the digital demodulator multiplexer, while the output of the digital multiplexer is the output of the demodulator, the inputs of which are the inputs of the optimal signal addition block, to which the outputs of the receiving paths are connected; the block of reference frequencies is common to the modulator and demodulator and is designed to form a spectrum of carrier frequencies used to ensure the functioning of the modulator and demodulator, and the first, second, and nth control outputs of the block of reference frequencies are connected to the control inputs of the first, second, and nth, respectively phase modulators and phase detectors.

Comparative analysis with the prototype shows that the inventive modulation-demodulation device for the tropospheric station is characterized by the presence of new units that are part of the modulator and demodulator, their implementation of multi-channel instead of single-channel, as in the prototype, as well as a change in the connections between the other elements of the device.

Thus, the claimed device meets the criteria of the invention of "novelty." A comparison of the proposed solution with other technical solutions shows that the blocks included in the modulation-demodulation device of the tropospheric station are widely known and additional creativity is not required for their implementation [1, 2, 3].

However, when they are introduced in this connection with the other elements into the inventive device, the above blocks exhibit new properties, which leads to a significant (from 2 Mbit / s to 34 Mbit / s) increase in the rate of transmission of discrete information over tropospheric communication channels. This allows us to conclude that the technical solution meets the criterion of "significant differences".

This solution is significantly different from the known solutions in the art. The claimed solution explicitly does not follow from the prior art, has an inventive step and is industrially applicable both in tropospheric stations and in other means of communication, for example, in wire means of channel formation.

The drawing shows a structural electrical diagram of a modulation-demodulation device of the tropospheric station.

The tropospheric station modulation-demodulation device comprises a modulator 1, consisting of a digital demultiplexer 4, n six-bit series-parallel converters 5, n six-bit IPO blocks 6, n six-bit DACs 7, n phase modulators 8 and an adder 9, demodulator 2, consisting of block 10 optimal signal addition, n selective filters 11, n phase detectors 12, n six-bit ADCs 13, n six-bit blocks IPO 14, n six-bit parallel-series converters 15 and a digital multiplexer 16, and that also contains a block of 3 reference frequencies, designed to form the carrier frequencies used to ensure the functioning of the modulator 1 and demodulator 2.

The first output of the digital demultiplexer 4 of modulator 1 through the first 5 ₁ six-bit serial-parallel converter, the first 6 ₁ six-bit IPO block, the first 7 ₁ six-bit DAC and the first 8 ₁ phase modulator are connected to the first input of the adder 9. The second output of the digital demultiplexer 4 through the second 5 ₂ six-bit serial-to-parallel converter, the second six-bit block _{2 June} IPO, the second six-bit DAC _{2 July} and _August 2nd second phase modulator is connected to the second input of the adder 9, and the n-th output digital Desmoulins tipleksora 4 through the n-th six-bit serial-to-parallel converter 5, _n, n-th six-bit block 6 IPO _n, n-th six-bit DAC 7, _n and n-th phase modulator 8 _n is connected to the n-th input of the adder 1. When the modulator 9 this input of the digital demultiplexer 4 is the input of the modulator 1, the output of which is the output of the adder 9 of the modulation-demodulation device of the tropospheric station.

The first output of the block 10 of the optimal addition of the signals of the demodulator 2 through the first 11 ₁ selective filter, the first 12 ₁ phase detector, the first 13 ₁ six-bit ADC, the first 14 ₁ six-bit block IPO and the first 15 ₁ six-bit parallel-serial converter connected to the first input of the digital multiplexer 16 The second output of block 10 of the optimal signal addition through the second 11 ₂ selective filter, the second 12 ₂ phase detector, the second 13 ₂ six-bit ADC, the second 14 ₂ six-bit block IPO and the second 15 ₂ six-bit in parallel the serial converter is connected to the second input of the digital multiplexer 16 of the demodulator 2, and the nth output of the optimal signal addition unit 10 through the nth selective filter 11 _n , the nth phase demodulator 12 _n , the nth six-bit ADC 13 _n , n nd six-bit block 14 _n IPO and n-th six-bit parallel-to-serial converter 15 is connected to the _n n-th input of a digital multiplexer 16, the demodulator 2. this unit 10 inputs the optimum summation signal demodulator 2 are the inputs of the demodulator 2, the output of which is output qi rovogo multiplexer 16.

The first, second, and nth control outputs of the reference frequency unit 3 are connected to the control inputs of the first, second, and nth phase modulators 8 of modulator 1 and phase detectors 12 of demodulator 2, respectively.

Digital demultiplexer 4 of modulator 1 is designed to separate a group digital signal of E3 format with a transmission speed of 34.368 Mbit / s coming from the output of external channelization equipment formed by the principle of temporary separation of channels (SAC) into sixteen digital streams of E1 format with a lower transmission rate of 2.048 Mbit / from. Isolation occurs by the method of polling a group signal at the corresponding, previously known, point in time. A pre-known point in time is calculated due to a pre-known sequence of formation of a group signal operating in synchronization with a demultiplexer.

Synchronization is carried out by identifying pre-known digital combinations of the sequence of the service clock of the E3 stream.

A six-bit serial-parallel converter 5 of the modulator 1 is designed to convert six consecutive bits of information into a sequence of six-bit parallel packets.

The six-bit block IPO 6 modulator 1 is used to convert the absolute values of the primary signal into a value that carries encoded information about the changes contained in the subsequent six-bit package relative to the previous six-bit package. The need for this conversion is associated with the subsequent use of this signal to modulate the carrier in phase. This action can only be performed using the law of relativity (difference of values), since the absolute value of the signal phase is random and cannot be calculated.

The six-bit DAC 7 is designed to convert digital six-bit packages into a system of discrete combinations of various amplitudes. Moreover, the maximum number of such parcels is sixty-four (2 ⁶ = 64).

Phase modulator 8 serves to modulate the carrier according to the law of phase change by amplitude discrete bursts. Moreover, the maximum number of combinations of parcels is equal to sixty-four (2 ⁶ = 64).

The adder 9 is designed for peer-to-peer addition of the spectra of individual signals into a common group spectrum of signals.

Individual elements of the modulator 1 can be made in accordance with the technical solutions according to the invention described in [2].

Block 10 of the optimal signal addition of the demodulator 2 is intended for addition with the function of selecting signals from alternative receiving paths into a single group receiving signal. The selection function is implemented by evaluating the quality of the receiving signal from each alternative receiving path with assigning a priority score using, for example, the value of the signal for automatically adjusting the gain of each of the paths. Addition takes into account the priority score according to the principle: the higher the score, the higher the contribution of this receiving path to the total value of the output signal.

Selective filter 11 is designed to highlight from the total group spectrum of the signal of the individual spectrum of the detected channel.

The phase detector 12 is designed to isolate (detect the carrier according to the law of phase change) amplitude discrete bursts. Moreover, the maximum number of combinations of parcels is equal to sixty-four

(2 ⁶ = 64).

The six-bit ADC 13 is designed to convert a system of discrete combinations of various amplitudes into six-bit digital packages. At the same time, the maximum number of parcels is sixty-four (2 ⁶ = 64).

The six-bit block 14 IPO demodulator 2 is designed to convert the relative (difference) values of the subsequent six-bit packages, relative to previous packages, the primary signal into absolute values.

A six-bit parallel-serial converter 15 of the demodulator 2 is designed to convert a sequence of six-bit parallel packets into a sequence of six single bits of information.

Digital multiplexer 16 is designed to combine sixteen digital E1 streams with a transmission rate of 2.048 Mbit / s into one group E3 stream with a transmission speed of 34.368 Mbit / s. The connection is carried out on the basis of the WRC with the transmission of information from each of the E1 streams to the corresponding, specially designated , time in the flow E3. For subsequent recognition, in the process of combining the E1 streams, service clock pulses with a previously known combination at a predetermined point in time are also generated.

The individual elements of the demodulator 2 can be made 6 in accordance with the technical solutions according to the invention described in [3].

The reference frequency block 3 is intended for the generation of harmonic oscillations with the frequencies necessary for the functioning of the modulator 1 and demodulator 2, as well as for the development of the necessary frequency stands, forming a common group signal spectrum from individual channel spectra, phase modulated according to the law of the primary signal with a transmission speed of 2.048 Mbit / s in modulator 1, and the reference frequencies of the supports necessary for the process of extracting modulated carrier channel signal spectra into an individual signal for subsequent demodulation in demodulator 2.

The modulation-demodulation device of the tropospheric station operates as follows.

On the transmission, a digital signal with a transmission rate of 34.368 Mbit / s from the channelization equipment is fed to the input of a digital demultiplexer 4 of modulator 1, which divides it into sixteen digital streams transmitted at a speed of 2.048 Mbit / s. From the outputs of the digital multiplexer 4, these streams in the form of six-bit parallel digital signals are fed to the inputs of the corresponding six-bit series-parallel converters 5, in which six consecutive bits of information are converted into a sequence of six-bit parallel packets, which then go to the inputs of the six-bit blocks 6 IPO. In blocks 6 IPO is the conversion of the absolute values of the phase of the primary signal into values that carry encoded information about the changes contained in the subsequent six-bit message relative to the previous six-bit message.

From the output of the six-bit blocks 6 IPO, the signals are fed to the inputs of the six-bit DAC 7, which turn them into a system of discrete signals and fed to the inputs of the phase modulators 8. In block 8, the carrier frequencies coming from the output of the block 3 of the reference frequencies are modulated according to the law of phase change by amplitude discrete parcels and then the signals are transmitted to the inputs of the adder 9, in which the spectra of individual signals are added to a common group spectrum of signals and its output to the inputs of the transmitter.

At the reception, the intermediate frequency signals from the output of several receiving paths are fed to the inputs of the optimal signal addition unit 10, which from the alternative receiving paths forms a single group receiving signal fed to the inputs of the selective filters 11. In the selective filters 11, side channels are filtered and selected from the common group the signal spectrum of the signals of the individual spectrum of the detected channels, which are then transmitted to the inputs of the phase detectors 12. In blocks 12, the allocation ( detection of the carrier according to the law of phase change) of the amplitude discrete bursts from the received signals and their transmission to the inputs of the six-bit ADC 13, which convert the system of discrete combinations of various amplitudes into six-bit digital bursts and transmit them to the inputs of the IPO blocks 14 of demodulator 2. In the IPO blocks 14, they are carried out processing in accordance with a given law, restoring and converting the relative (difference) values of subsequent six-bit packets relative to the previous primary signal into absolute s the beginning of the signals that are transmitted to the inputs of six-bit parallel-serial converters 15.

In parallel-serial converters 15, the sequence of six-bit parallel packets is converted into a sequence of six single bits of information that are input to the digital multiplexer 16. In the digital multiplexer 16, the received sixteen digital streams E1 with a transmission rate of 2.048 Mbit / s are combined into one group stream E3 with a transmission speed of 34.368 Mbit / s and its output to the input of external channelization equipment.

The technical efficiency of the proposed modulation-demodulation device is to increase the throughput of the tropospheric communication lines by increasing the transmission rate of discrete information through the channels of the tropospheric station, which used the technical solutions of the present invention. This is achieved by making the modulator and demodulator blocks of the device multichannel, providing a line seal, followed by combining the channels into a single group stream.

A comparative analysis with similar solutions showed that in the proposed modulation-demodulation device of the tropospheric station several times (over ten times) increased throughput.

Information sources

1. A.M. Zaezdny, Yu.B. Okunev, L.M. Rakhovich. Phase difference modulation and its application for transmitting discrete information. - M.: Communication, 1967.

2. SU, copyright certificate No. 711662, cl. H03C 1/50, 1980.

3. SU, copyright certificate No. 325678, cl. H03D 3/06, 1972.

4. G.P. Divnogortsev, V.A. Novikov, and Yu.D. Farber. Telecommunication equipment. A manual for technical schools of communication. Second edition, revised and supplemented. - M .: Communication, 1970, pp. 10-26, 27 (Fig. B. 19) (prototype).

5. Tropospheric communication. L.I. Yakovlev G.V. Dedyukin, E.S. Kagramanov et al. - M .: Military Publishing House, 1984, p. 88-90.

Claims (1)

A tropospheric station modulation-demodulation device comprising a modulator, a demodulator and a block of reference frequencies, characterized in that the modulator is multi-channel and consists of a digital demultiplexer, n six-bit series-parallel converters, n six-bit truth blocks of the relativity transducer (IPO), n six-bit digital-to-analog converters (DAC), n phase modulators and one adder, while the first, second and nth outputs of the digital demultiplexer are connected respectively to the inputs of the first, second and nth six-bit serial-parallel converters, the output of the first six-bit serial-parallel converter of the modulator is connected to the input of the first six-bit IPO block, the output of which through the first six-bit DAC is connected to the input of the first phase modulator, the output of the second six-bit serial-parallel converter connected to the input of the second six-bit IPO unit, the output of which through the second six-bit DAC is connected to the input of the second phase modulator, the output of the nth six-bit serial-parallel converter of the modulator is connected to the input of the nth six-bit IPO block, the output of which through the nth six-bit DAC is connected to the input of the nth phase modulator, the outputs of the first, second, and nth phase modulators are connected respectively to the first, second and n-th inputs of the adder, and the output of the adder is the output of the modulator to the transmitter, the input of which is the input of the digital demultiplexer; the demodulator is multi-channel and consists of a block of optimal signal addition, n selective filters, n phase detectors, n six-bit analog-to-digital converters (ADC), n six-bit IPO blocks, n six-bit parallel-serial converters and a digital multiplexer, while the first, second and The nth outputs of the block of optimal addition of demodulator signals are connected to the inputs of the first, second, and nth selective filters, respectively, the output of the first select filter is connected to the input of the second phase a demodulator, the output of which through the second six-bit IPO block and the second six-digit DAC is connected to the second input of the demodulator multiplexer, the output of the nth selective filter is connected to the input of the nth phase demodulator of the phase demodulation block, the output of which is through the nth six-bit block of IPO and n- The sixth digit DAC is connected to the nth input of the demodulator multiplexer, while the multiplexer output is the output of the demodulator digital signal, the inputs of which are the inputs of the optimal signal addition block, to which By connecting the outputs of reception paths; the reference frequency block is common to the modulator and demodulator, designed to form a spectrum of carrier frequencies used for each of the channels of the modulator and demodulator, and the first, second, and nth control outputs of the reference frequency block are connected to the control inputs of the first, second, and n th phase modulators and phase demodulators.