RU2325759C1 - Radio communication adaptive system - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention may be used for transmission of discrete information in troposcatter links. Adaptive system of radio communication on the transmitting side consists of the following: time multiplex unit, probing mode control unit, probing commands combination unit, probing commands decoder, manipulator of information signals, frequency synthesizer, combination unit of optimal frequency number commands, combination unit of frequency coherence band commands, unit of transmission signals combination, probing signals manipulator, selector of probing commands and probing commands coder, on the receiving side adaptive system of radio communication consists of unit of optimal frequency selection, unit of frequency coherence band commands combination, unit of frequency coherence band estimate, frequency mixer, frequency synthesizer, probing mode control unit, unit of probing commands combination, decision-making unit, unit of channel power budget reserve measurement, probing commands coder, unit of optimal frequency number commands combination and demodulator.

EFFECT: increases noise-immunity and availability ratio.

2 dwg

Description

FIELD OF THE INVENTION

The invention relates to radio communications and can be used to transmit discrete information in tropospheric communication lines.

State of the art

A known adaptive radio communication system comprising, on the transmitting side, a sensing instruction encoder, a sensing instruction decoder and serially connected temporary compression unit, an information signal manipulator and a transmission signal combining unit, the other input of which is connected to the frequency synthesizer via the sensing command manipulator, and the other input of the frequency synthesizer is connected with the control input of the information signal manipulator, and on the receiving side there is an encoder for sensing commands and series-connected mixtures spruce frequency and a demodulator, the input of the frequency mixer is connected to the input of the optimum frequency selection unit, and the other input of the frequency mixer connected to the output of the frequency synthesizer (USSR Author's Certificate №291347, Cl. H04V 3/04, publ. 1971). The disadvantages of this adaptive radio communication system are: limitation of noise immunity during fast fading due to the need to reduce the sounding period; inefficient use of the time-frequency resource, since the choice of frequencies for sounding and operation of a radio station does not take into account the dynamics of changes in the physical parameters of the troposphere, for example, its structural characteristics and size of inhomogeneities.

Another adaptive radio communication system is known, which is distinguished by increased noise immunity during fast fading due to the implementation of a variable sounding period based on an estimate of the channel’s energy potential reserve (USSR Author's Certificate No. 562928, class Н04В 7/12, publ. 1977). This adaptive radio communication system is the closest in technical essence to the proposed invention and contains, on the transmitting side, a sensing instruction encoder, a sensing instruction decoder and serially connected time compression unit, an information signal manipulator and a transmission signal combining unit, the other input of which is connected to the output of the frequency synthesizer via a sensing command manipulator, the other output of the frequency synthesizer being connected to a control input of the information signal manipulator, as well as probing command lecturer, optimal command number unit command combining unit and series-connected sensing command combining unit and sensing mode control unit, while some outputs of the sensing command decoder are connected to the inputs of the sensing command combining unit, and the other outputs are connected to the probing command unit combining unit the control input of the frequency synthesizer, the additional input of which is connected to the output of the sounding mode control unit, the other input of which is connected to tional entry temporary seal unit, and the output of the encoder sensing instruction signal input connected to the manipulator sensing commands via the selector sensing commands control input of which is connected to an additional output of the block time multiplexing.

On the receiving side, the radio communication system comprises a sensing instruction encoder, a frequency mixer and a demodulator connected in series, while the input of the frequency mixer is connected to the input of the optimal frequency selection unit, and the other input of the frequency mixer is connected to the output of the frequency synthesizer, and also contains a channel energy storage margin measuring unit , a unit for combining commands of the optimal frequency number and a series-connected decision block, a unit for combining sounding commands and a sounding mode control unit moreover, the outputs of the unit for selecting the optimal frequency directly and through the unit for measuring the margin of the energy potential of the channel are connected to the inputs of the decision unit, some outputs of which are connected to the input of the frequency synthesizer through the unit of combining commands of the numbers of the optimal frequency, and the other outputs of the unit for decision making to the inputs of the encoder sensing commands, while one output of the sensing mode control unit is connected to another input of the frequency synthesizer, and the other output is optimally connected to the control input of the selection unit frequency.

The indicated adaptive radio communication system does not take into account the dynamics of changes in the structural characteristics and size of inhomogeneities of the troposphere. As a result, the frequencies for sounding should be chosen with a fixed step, guaranteed to exceed the size of the frequency coherence interval necessary for a given period of time. As a result, the probability of skipping the optimal frequency increases and the duration of the sounding time increases. This, in turn, leads to a decrease in the time resource for transmitting the signals of the information graph, a decrease in the noise immunity and the availability factor of the radio channel.

Disclosure of invention

The aim of the invention is to increase noise immunity and availability.

The technical result is expressed in a more rational use of the time-frequency resource of an adaptive radio communication system based on the dynamics of changes in the physical parameters of the troposphere (structural function of the refractive index C _n and the size of the inhomogeneities L _s ), which lead to a change in the frequency coherence band of the tropospheric channel

In order to achieve a technical result, an adaptive radio communication system comprising, on the transmitting side, a sensing instruction encoder, a sensing instruction decoder and serially connected a temporal multiplexing unit, an information signal manipulator and a transmission signal combining unit, the other input of which is connected to the output of the frequency synthesizer via a sensing command manipulator, the other output of the frequency synthesizer is connected to the control input of the information signal manipulator, as well as a sensing command selector, a unit for uniting the optimal frequency number commands and the sounding command combining unit and the sounding mode control unit connected in series, while one of the sensing command decoder outputs is connected to the inputs of the sensing command combining unit, and the other outputs through the optimal frequency number combining unit to the control input of the frequency synthesizer, the additional input of which is connected to the output of the sounding mode control unit, the other input of which is connected to the additional input of the temporary densification, and the output of the probe command encoder is connected to the signal input of the probe command manipulator via the probe command selector, the control input of which is connected to the additional output of the temporary compression unit.

On the receiving side, the radio communication system comprises a sensing instruction encoder, a frequency mixer and a demodulator connected in series, while the input of the frequency mixer is connected to the input of the optimal frequency selection unit, and the other input of the frequency mixer is connected to the output of the frequency synthesizer, and also contains a channel energy storage margin measuring unit , a unit for combining commands of the optimal frequency number and a series-connected decision block, a unit for combining sounding commands and a sounding mode control unit moreover, the outputs of the unit for selecting the optimal frequency directly and through the unit for measuring the margin of the energy potential of the channel are connected to the inputs of the decision unit, some outputs of which are connected to the input of the frequency synthesizer through the unit of combining commands of the numbers of the optimal frequency, and the other outputs of the unit for decision making to the inputs of the encoder sensing commands, while one output of the sensing mode control unit is connected to another input of the frequency synthesizer, and the other output is optimally connected to the control input of the selection unit frequency on the transmission side combining unit commands entered coherence frequency band, the inputs of which are connected to additional inputs of the sensing instruction decoder, and an output - to the third auxiliary input of the frequency synthesizer; on the receiving side, a frequency coherence band estimation unit and a frequency coherence band unit combining unit are introduced, the first input of the frequency coherence band estimation unit being connected in parallel with the input of the mixer and with the input of the optimal frequency selection unit, and the second input is connected to the additional output of the sensing mode control unit, the outputs of the unit for estimating the frequency coherence band are connected in parallel with the inputs of the unit for combining the commands of the frequency coherence band and additional inputs of the encoder sensing commands and the output combining unit commands the frequency coherence bandwidth connected to an additional input of the frequency synthesizer.

Brief Description of the Drawings

Figure 1 shows the structural diagram of the transmitting part, and figure 2 is a structural diagram of the receiving part of the adaptive radio communication system.

The implementation of the invention

The adaptive radio communication system comprises, on the transmitting side, a temporary compaction unit 1, a sensing mode control unit 2, a sensing command combining unit 3, a sensing command decoder 4, an information signal manipulator 5, a frequency synthesizer 6, an optimal frequency number combining unit 7, a band command combining unit frequency coherence 8, a transmission signal combining unit 9, a sensing signal manipulator 10, a sensing command selector 11, a sensing command encoder 12, the first input of a temporary control unit 1 is the first input of the transmitting part of the described adaptive radio communication system, the second input of the temporary sealing unit 1 is connected to the first output of the sounding mode control unit 2, the first output of the temporary sealing unit 1 is connected to the first input of the sensing command selector 11, and the second output is connected in series through the first input of the information signal manipulator 5 is connected to the first input of the transmission signal combining unit 9, the output of which is the output of the transmitting part of the adaptive radio communication system ; sensing command encoder 12 sequentially through the second input of the sensing command selector 11, the second input of the sensing signal manipulator 10 is connected to the second input of the transmission signal combining unit 9; the input of the probe command decoder 4 is the second input of the transmitting part of the adaptive radio communication system, the first outputs of the probe command decoder 4 are connected to the inputs of the probe team 3; the output of which is connected to the input of the probe mode control unit 2; the second output of the sounding mode control unit 2 is connected to the first input of the frequency synthesizer 6; the second outputs of the probe command decoder 4 are connected to the inputs of the unit combining the teams of the optimal frequency number 7, the output of which is connected to the second input of the frequency synthesizer 6; the third (additional) outputs of the probe command decoder 4 are connected to the inputs of the unit for combining commands of the frequency coherence band 8, the output of which is connected to an additional input of the frequency synthesizer 6, and the first and second outputs of the latter are connected respectively to the second input of the information signal manipulator 5 and to the first input of the manipulator sensing signals 10.

On the receiving side, the adaptive radio communication system comprises an optimum frequency selection block 13, a frequency coherence band unit combining unit 14, a frequency coherence band estimating unit 15, a frequency mixer 16, a frequency synthesizer 17, a sensing mode control unit 18, a sensing unit combining unit 19, an acceptance unit solutions 20, the unit for measuring the energy potential reserve of channel 21, the sensing instruction encoder 22, the unit for combining commands of the optimal frequency number 23, demodulator 24, the first input of the frequency mixer 16 being is Busy input receiving portion of the proposed adaptive radio system, the output frequency of the mixer 16 is connected to the input of a demodulator 24 whose output is the first output of the receiver system; the first input of the optimal frequency selection block 13 is connected in parallel with the first inputs of the frequency coherence band estimator 15 and the frequency mixer 16, the first outputs of the optimal frequency selection block 13 are connected to the first inputs of the decision block 20, and the second outputs are through the channel energy reserve measuring unit 21 with the second inputs of the decision block 20; the first outputs of the decision block 20 are connected in parallel with the inputs of the unit for combining sensing commands 19 and the second inputs of the encoder of sensing commands 22; the second outputs of the decision block 20 are connected to the inputs of the block combining commands number optimal frequency 23, the output of which is connected to the third input of the frequency synthesizer 17; the output of the unit for combining sounding commands 19 is connected to the input of the sounding mode control unit 18; the outputs of the unit for estimating the frequency coherence band 15 are connected in parallel with the inputs of the unit for combining the commands of the frequency coherence band 14 and the first (additional) inputs of the probe command encoder 22, the output of which is the second output of the receiving part of the adaptive radio communication system; the output of the unit for combining commands of the frequency coherence band 14 is connected to the first (additional) input of the frequency synthesizer 17, the output of which is connected to the second input of the frequency mixer 16; the first, second, and third outputs of the sounding mode control unit 18 are connected respectively to the second input of the frequency synthesizer 17, to the second input of the frequency coherence band estimator 15 and to the second input of the optimal frequency selection unit 13; the third output of the sensing mode control unit 18 is the third output of the receiving part of the adaptive radio communication system.

Adaptive radio communication system operates as follows.

At the receiving part of the radio communication system, the probing signals from the output of the high frequency path (not shown in FIG. 2) are fed to the first input of the frequency coherence band estimation unit 15 and the first input of the optimal frequency selection unit 13. The results of measuring the frequency coherence band are used to determine the tuning step ( separation) of the probing frequencies, and the results of choosing the optimal frequency and measuring the energy reserve of the channel in block 21 are used to decide on the frequency number of the transmitter but also about the sensing mode. If in the process of probing by the optimal frequency selection unit 13 the frequency is determined at which the radio signal has a maximum amplitude and the results of measuring the energy potential of the channel in block 21 indicate the presence of a margin, then a sounding off signal is generated in the decision block 20, depending on the number of the selected frequency. This signal is transmitted through the sensing command combining unit 19 to the input of the sensing mode control unit 18 and to the second inputs of the sensing command encoder 22, and through it to the transmitting part of the adaptive radio communication system, where this command is decoded by the sensing command decoder 4 and from its first outputs through sensing command combining unit 3 is fed to the input of the sensing mode control unit 2. The control signal from the first output of this unit enters the temporary compression unit 1, puts it in signal transmission mode in information traffic along the chain: the first input is the second output of the temporary compression unit 1, the information signal manipulator 5, the transmission signal combining unit 9. At the same time, the signal from the first output of the temporary compression unit 1 blocks the sensing command selector 11 during the transmission of information traffic signals.

In the absence of a supply of channel energy potential, the decision block 20 generates a sounding mode enable signal. This signal through the block combining the sensing commands 19 enters the control unit of the sounding mode 18 and the encoder of the sensing commands 22. The control unit of the sounding mode 18 generates the switching signals of the optimal frequency selection blocks 13 and the frequency coherence band estimation unit 15, as well as the blocking signal of the temporary compression block (not shown in figure 1) for the period of sounding. The unit for estimating the frequency coherence band 15 generates a signal corresponding to the current value of the troposphere coherence band, and through the unit for combining the frequency coherence band commands it feeds it to the first (additional) input of the frequency synthesizer 17. In the frequency synthesizer 17, the probing frequencies are formed in increments corresponding to the real value of the band frequency coherence. At the same time, the signals from the output of the frequency coherence band estimator 15 are fed to the first (additional) inputs of the sensing command encoder 22 for transmitting commands corresponding to the sounding mode enable signals, the frequency coherence band value, and tuning the frequency synthesizer of the transmitting part of the correspondent station to the selected frequency.

At the transmitting part of the adaptive radio communication system, the sensing command decoder 4 generates a sounding mode enable signal at the first outputs. This signal through the block combining the sensing commands 3 and the control unit of the sensing mode 2 puts the synthesizer into the sensing mode and locks the temporary compaction block 1 for the sensing period, which generates an unlock signal for the sensing command selector 11, which transmits the signals from the output of the sensing command encoder 12 to the second input of the manipulator sensing signals 10. At the second outputs of the decoder of sensing instructions 4, commands for tuning the frequency synthesizer 6 to the selected frequency are generated, which are combined through the unit Nia optimum frequency command numbers 7 and a second input of the frequency synthesizer 6 is mounted last current frequency. At the third (additional) outputs, the sensing command decoder 4 generates commands corresponding to the value of the measured frequency coherence band, which, through the unit for combining the commands of the frequency coherence band 8 and the third (additional) input of the frequency synthesizer 6, specify the frequency tuning step of the latter during the sounding process.

In the proposed adaptive radio communication system, in comparison with the prototype, sounding is carried out not only with a variable period, but also with a variable shift of the probing frequencies, which makes it possible to more rationally use the time-frequency resource and, as a result, increase the noise immunity and the availability factor of tropospheric radio communications. Indeed, if the frequency spacing for sounding is fixed, as occurs in the prototype, then its value should be large enough to correspond to the maximum frequency coherence band. However, due to a change in the structural function and the scale of tropospheric inhomogeneities, the frequency coherence band can change by more than an order of magnitude. In this case, the adaptive radio communication system at the stage of sensing and assessing the state of the radio channel can pass the optimal frequencies, as well as frequencies acceptable for the operation of the radio line in terms of the margin of energy potential. As a result, sounding cycles will be repeated more often and have a longer duration, which will lead to a limitation of the time resource for transmitting information traffic signals, and when limiting the transmission speed, to a decrease in reliability. At the same time, an increase in the duration of sounding periods leads to a decrease in the radio channel availability coefficient. On the contrary, when using variable shift, the determination of frequencies suitable for the operation of the radio link with the required noise immunity and the necessary supply of the channel’s energy potential occurs in one sensing cycle.

Claims (1)

An adaptive radio communication system containing, on the transmitting side, a temporary compaction unit, a sounding mode control unit, a sounding command combining unit, a sounding command decoder, an information signal manipulator, a frequency synthesizer, an optimal frequency number command combining unit, a transmission signal combining unit, a sounding signal manipulator, a selector sensing commands, encoder of sensing commands, the first input of the temporary compression unit being the first input of the transmitting part of the adaptive system radio communications, the second input of the temporary seal unit is connected to the first output of the sounding mode control unit, the first output of the temporary seal unit is connected to the first input of the sensing command selector, and the second output is connected to the first input of the information signal manipulator, the output of which is connected to the first input of the transmission signal combining unit whose output is the output of the transmitting part of the adaptive radio communication system; the output of the probe command encoder is connected to the second input of the probe command selector, the output of which is connected to the second input of the sensing signal manipulator, and the output of the latter is connected to the second input of the transmission signal combining unit; the input of the probe command decoder is the second input of the transmitting part of the adaptive radio communication system, one of the outputs of the probe command decoder is connected to the corresponding inputs of the probe command combining unit, the output of which is connected to the input of the probe mode control unit; the second output of the sounding mode control unit is connected to the first input of the frequency synthesizer; other outputs of the probe command decoder are connected to the corresponding inputs of the command combining unit of the optimal frequency number, the output of which is connected to the second input of the frequency synthesizer; the first and second outputs of the latter are connected respectively to the second input of the information signal manipulator and to the first input of the sensing signal manipulator, and on the receiving side, an optimum frequency selection unit, a frequency mixer, a frequency synthesizer, a sounding mode control unit, a sounding instruction combining unit, a decision making unit, unit for measuring the energy potential of the channel, encoder for sensing commands, unit for combining commands of the optimal frequency number, demodulator, and the first input of the mixer is often t is the input of the receiving part of the adaptive radio communication system, the output of the frequency mixer is connected to the input of the demodulator, the output of which is the first output of the receiving part of the system; the first input of the optimal frequency selection unit is connected to the first input of the frequency mixer, one of the outputs of the optimal frequency selection unit is connected to the corresponding inputs of the decision unit, and the other outputs through the channel’s energy potential measuring unit, with the corresponding second inputs of the decision unit; part of the outputs of the decision block are connected in parallel with the corresponding inputs of the unit for combining the sensing commands and the corresponding inputs of the encoder of the sensing commands; the other outputs of the decision block are connected to the corresponding inputs of the unit of combining commands of the optimal frequency number, the output of which is connected to the third input of the frequency synthesizer; the output of the unit for combining sensing commands is connected to the input of the sensing mode control unit; the output of the encoder of the sensing commands is the second output of the receiving part of the adaptive radio communication system; the output of the frequency synthesizer is connected to the second input of the frequency mixer; the first and third outputs of the sensing mode control unit are connected, respectively, to the second input of the frequency synthesizer and to the second input of the optimal frequency selection unit; the third output of the sounding mode control unit is the third output of the receiving part of the adaptive radio communication system, characterized in that on the transmitting side a unit for combining frequency coherence band instructions is input, the additional outputs of the sensing instruction decoder are connected to the corresponding inputs of the unit for combining frequency coherence band commands, the output of which is connected with an additional input of the frequency synthesizer, and on the receiving side, a unit for combining frequency coherence band commands is introduced and a unit for estimating the frequency coherence band, and its first input connected in parallel with the first input of the mixer and with the first input of the optimal frequency selection unit, the outputs of the unit for estimating the frequency coherence band are connected in parallel with the corresponding inputs of the unit for combining the frequency coherence band commands and additional inputs of the probe command encoder, the output of which is the second output of the receiving part of the adaptive radio communication system; the output of the unit for combining commands of the frequency coherence band is connected to the first input of the frequency synthesizer, and the second output of the control unit of the sounding mode is connected to the second input of the unit for estimating the frequency coherence band.

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