RU2734754C1 - Method for active monitoring of operating frequencies with identification of type of destructive effects - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to radio engineering and is intended for use in data transmission systems using frequency-adaptive operating mode or mode with pseudo-random tuning of operating frequency. In the method for active monitoring of operating frequencies with identification of the type of destructive actions, including, based on the conducted analysis of the communication channel quality, the permissible number of suitable operating frequencies is calculated, when the use of testing procedures still provides the required data transmission rate, if the total number of unusable frequencies exceeds the estimated allowable number, additionally, on each detected unusable operating frequency, transmitting a test signal, and on the receiving side, performing a structural analysis of features of its distortions at each operating frequency, on which it was transmitted, the results of the structural analysis are compared to the pre-prepared reference values, based on the results of comparison with which a decision is made on the form of destructive action and if necessary change parameters and operating modes of the data transmission system.

EFFECT: technical result consists in increase in data transmission speed in a noise-protected radio line with pseudo-random tuning of operating frequency by determining the type of destructive effect.

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Description

The invention relates to the field of radio engineering and is intended for use in data transmission systems using frequency-adaptive modes of operation or modes with pseudo-random tuning of the operating frequency.

There is a known method of active control of operating frequencies, see [Egorov VV, Katanovich AA, etc. Method of active control of operating frequencies. RF patent No. 2447579 on application No. 2010101884/08 dated 21.01.2010].

In the known method, the message at the operating frequency is transmitted in full, except for the last information packet, and the last packet of each message is transmitted at one of the spare frequencies, while on the receiving side, according to the number of errors corrected by the correcting code, the degree of suitability of this spare frequency to change the operating frequency is determined, and thus, the spare frequencies are arranged in a variation series that determines the priorities in the use of frequencies.

The disadvantage of this method is that its implementation involves an indirect analysis of operating frequencies based on the correcting ability of the code, which does not allow identifying the type of destructive effect and, therefore, changing the algorithm of the data transmission system, which, with an increase in the number of unusable frequencies, leads to a decrease in the data transmission rate.

A known method for determining the best frequency based on preliminary sensing, described in [Dvornikov SV, Pshenichnikov AV, Manaenko SS Statistical characteristics of noise-immune radio lines with frequency resource control / Information technology. - M .: 2019. No. 1. S. 35-40].

In the analogous method, the information source sequentially sends at each of the possible frequencies a previously prepared test data unit known at the receiving side. In this case, the data transmission systems at the receiving and transmitting sides are tuned from frequency to frequency synchronously. The information receiver estimates the parameters of the communication channel at the corresponding frequency and informs the transmitting side about the quality of the communication channel through the feedback channel. After obtaining the necessary statistics for the entire allocated frequency resource, a decision is made on the choice of an operating frequency for data transmission.

The disadvantage of the analogous method is that the determination of the suitability / unsuitability event of the operating frequency does not allow identifying the type of destructive effect and, therefore, changing the algorithm for the operation of the data transmission system, which, with an increase in the number of unusable frequencies, leads to a decrease in the data transmission rate.

The closest in technical essence (prototype) to the claimed is the method of active control of operating frequencies, described in [SV Dvornikov, AV Pshenichnikov, etc. Method of active control of operating frequencies. RF patent No. 2710027 dated 12.24.2019].

In the prototype method, the information source sequentially sends at each of the possible frequencies a previously prepared test data block known on the receiving side, while the data transmission systems on the receiving and transmitting sides are reconstructed from frequency to frequency absolutely synchronously, the information receiver estimates the parameters of the communication channel for corresponding frequency and through the feedback channel informs the transmitting side about the quality of the communication channel, after obtaining the necessary statistics on the entire allocated frequency resource, a decision is made on the choice of the operating frequency for data transmission. In this case, the transmitting side is informed about the quality of the channel at the frequency at which the prepared test block was received, and, at the moment when the prepared test block is received at the current frequency, the transmitting side is simultaneously informed about the quality of the channel at the previous frequency.

The disadvantage of the prototype method is that the determination of the suitability / unsuitability event of the operating frequency does not allow identifying the type of destructive effect and, therefore, changing the algorithm of the data transmission system, which leads to a decrease in the data transmission rate with an increase in the number of unusable frequencies.

The aim of the invention is to create a method for active control of operating frequencies with identification of the type of destructive effects.

The technical result of the proposed method is to increase the speed of data transmission in a noise-immune radio line with pseudo-random tuning of the operating frequency by determining the type of destructive effect.

The claimed technical result is achieved by the fact that in the method of active control of operating frequencies with identification of the type of destructive effects, the information source sequentially sends at each of the possible operating frequencies a previously prepared test data unit known on the receiving side, while the data transmission systems at the receiving and transmitting sides are rebuilt from frequency to frequency absolutely synchronously, the information receiver estimates the parameters of the communication channel at the corresponding operating frequency and informs the transmitting side about the quality of the communication channel, after obtaining the necessary statistics for the entire allocated frequency resource, a decision is made on the choice of the operating frequency for data transmission, the transmitting side is informed about quality of the channel at the frequency at which the prepared test block was received, while, at the moment when the prepared test block is received at the current operating frequency, the transmitting side is simultaneously informed about the quality of the channel on the the previous operating frequency and differs in that, on the basis of the analysis, the allowable number of suitable operating frequencies is calculated, at which the application of testing procedures still provides the required data transfer rate, if the total number of unusable frequencies exceeds the calculated allowable amount, then additionally at each identified unusable operating frequency a special test signal is transmitted, and on the receiving side a structural analysis of the features of its distortions is performed at each operating frequency at which it was transmitted, the results of the structural analysis are compared with previously prepared reference values, based on the results of comparison with which a decision is made on the type of destructive effect, and, if necessary , change the parameters and operating modes of the data transmission system.

Thanks to the new set of essential features in the claimed method, it is possible to identify the parameters of organized interference at operating frequencies and change the operating mode of data transmission systems to one that can increase the noise immunity of signals with pseudo-random tuning of the operating frequency, knowing the specific type of destructive effect, and thereby reduce the effect of exposure interference, which together allows you to increase the speed of data transmission and achieve a technical result. So, in analogous methods and in the prototype, the data transfer rate is increased by rejecting frequencies, the level of interference at which exceeds the allowable for distortion-free data transmission. In the case when, under the influence of organized interference, the number of rejected frequencies increases, then the data transmission rate decreases (since the number of suitable operating frequencies decreases). The mode of operation with software tuning of the operating frequency with its advantages is also violated. Thus, having determined the type of organized interference, for example, noise interference in part of the band, to increase the noise immunity of signals with pseudo-random tuning of the operating frequency, such operating modes can be used (developed in the monograph [Borisov V.I., Zinchuk V.M., Limarev A .E. Interference immunity of radio communication systems by expanding the spectrum of signals by the method of pseudo-random tuning of the operating frequency // edited by V.I. Borisov; 2nd ed., Revised and supplemented - Moscow: RadioSoft, 2008. - 512 p.]) : frequency diversity of information symbols, adaptive gain control, increase in the size of the transmission alphabet.

The claimed method is illustrated by drawings, which show:

FIG. 1 - time-frequency matrix, explaining the principle of active control of operating frequencies, implemented in the claimed method and the prototype method;

FIG. 2 - time fragment of the functioning of the data transmission system with the implementation of the proposed method.

здесь верхний индекс указывает частоту, на которой передают тестовый блок данных. При этом передачу тестового блока производят последовательно на всех возможных для работы системы передачи данных частотах. Таким образом, осуществляют тестирование рабочих частот. В ходе тестирования определяют факт пригодности/непригодности каждой рабочей частоты путем подсчета количества ошибочно принятых элементов тестового блока. Недостаток способа-прототипа заключается в том, что если выявленное количество непригодных для работы частот превысит некоторое допустимое значение, то применение процедур предварительного тестирования становится нецелесообразным, так как его применение не обеспечивает заявленный технический результат. Кроме того, способ-прототип не позволяет определить характер деструктивных воздействий на канал связи и, следовательно, своевременно изменить параметры и режим работы системы передачи данных в целях повышения скорости передачи данных.The essence of the concept of the proposed method is based on the implemented features of the prototype method. In the prototype method (see Fig. 1), the information source sequentially sends a pre-prepared test data block at each of the possible frequencies for operation

here the superscript indicates the frequency at which the test data block is transmitted. In this case, the transfer of the test block is carried out sequentially at all frequencies possible for the operation of the data transmission system. Thus, testing of operating frequencies is carried out. During testing, the fact of suitability / unsuitability of each operating frequency is determined by counting the number of erroneously received elements of the test block. The disadvantage of the prototype method is that if the identified number of unusable frequencies exceeds a certain allowable value, then the use of preliminary testing procedures becomes impractical, since its use does not provide the claimed technical result. In addition, the prototype method does not allow to determine the nature of destructive effects on the communication channel and, therefore, to timely change the parameters and operating mode of the data transmission system in order to increase the data transmission rate.

In the claimed method, initially, similar to the prototype method, an analysis of the suitability of operating frequencies is performed. In the case when the number of detected unusable operating frequencies becomes more than the allowable one, a test signal is additionally used, which is transmitted sequentially at each identified unusable operating frequency. The structure of the test signal is known on the receiving side, which makes it possible to identify structural distortions occurring in the channel. Then the revealed structural distortions are compared with the reference values, which are preliminarily formed as a result of exposure to a special test signal during its transmission in a channel with various types of destructive effects. Thus, they form a base of reference values, which allows identifying the type of destructive effect based on the results of the analysis of structural distortions of the test signal. Based on the results of the identification, the type of destructive effect is determined and a decision is made to change the parameters and operating modes of the data transmission system.

A distinctive feature of the developed method is the choice of intervals of operation T _ri and analysis of T _ai (see Fig. 2), which is carried out on the basis of the statistical parameters of radio communication channels [Dvornikov S.V., Pshenichnikov A.V., Manaenko S.S. Statistical characteristics of noise-immune radio lines with frequency resource management / Information technology. - M .: 2019. №1. S. 35-40]. This approach provides periodic control of the used operating frequencies over the entire time interval of the operation of the data transmission system, which makes it possible to increase the data transmission rate. That is, the analysis time T _a2 (see Fig. 2) increases by the duration of the test message only in the worst case, when the number of operating frequencies affected by the organized interference exceeds the threshold required for timely data transmission. Otherwise, data transmission would not be feasible and the mode of operation with pseudo-random tuning of the operating frequency would be completely violated (T _r3 would _tend to zero), (see Fig. 2).

And since in a radio channel, for example, decameter communication, the set of types of destructive influences is limited [Pshenichnikov A.V. Models and methods of noise protection: monograph. - SPb .: 2017. - 132 p.], Then in most cases they will be identified. Knowing the type and nature of the destructive impact, you can appropriately change the parameters and operating modes of the data transmission system, which are described in detail in [Borisov V.I., Zinchuk V.M., Limarev A.E. Noise immunity of radio communication systems by expanding the spectrum of signals by the method of pseudo-random tuning of the operating frequency // Ed. IN AND. Borisov; 2nd edition, rev. and add. - M .: RadioSoft, 2008. - 512 p.]. Thus, the achievement of the claimed technical result is ensured.

The implementation of the proposed method is as follows.

1. The information source sequentially sends at each of the possible frequencies a previously prepared test data unit known on the receiving side.

The implementation of these procedures is known and described in the prototype method (RF patent for invention 2710027 dated 12.24.2019), as well as in the article [Dvornikov S.V., Pshenichnikov A.V., Manaenko S.S. Statistical characteristics of noise-immune radio lines with frequency control resource / Information technology. -M .: 2019. №1. S. 35-40].

The order and principle of formation of digital streams in the form of pulse sequences is known, see [Gerasimenko VG, Tupota VI, Tupota AV. Method of transmitting discrete information in a radio link with pseudo-random tuning of the operating frequency. Patent No. 2228575 for application No. 2002117818/09 dated 02.07.2002.].

2. The data transmission system at the receiving and transmitting sides is tuned from frequency to frequency absolutely synchronously. The implementation of these procedures for radio lines with frequency hopping is known, described in the prototype and, for example, in [Gerasimenko VG, Tupota VI, Tupota AV Method of transmitting discrete information in a radio link with pseudo-random tuning of the operating frequency. Patent No. 2228575 for application No. 2002117818/09 dated 02.07.2002.], As well as in the monograph [Borisov V.I., Zinchuk V.M., Limarev A.E. Noise immunity of radio communication systems by expanding the spectrum of signals by the method of pseudo-random tuning of the operating frequency // Ed. IN AND. Borisov; ed. 2nd, rev. and add. -M .: RadioSoft, 2008. - 512 p.].

3. The receiver of information evaluates the parameters of the communication channel at the appropriate frequency.

The implementation of these procedures for radio communication lines that implement the method of active control of operating frequencies is known and described in the prototype method and, in particular, in [SV Dvornikov, AV Pshenichnikov, etc. Method of active control of operating frequencies. RF patent for invention 2710027 dated 12.24.2019.], As well as in the article [Dvornikov S.V., Pshenichnikov A.V., Manaenko SS Statistical characteristics of noise-immune radio lines with frequency resource management / Information technology. -M .: 2019. №1. S. 35-40.].

4. The transmitting side is informed about the quality of the channel at the frequency at which the prepared test block was received, and at the moment when the prepared test block is received on the current frequency, the transmitting side is simultaneously informed about the quality of the channel on the previous frequency.

These procedures are similar to those used in the prototype method.

5. After obtaining the necessary statistics for the entire allocated frequency resource, a decision is made on the choice of an operating frequency for data transmission.

These procedures are similar to those used in the prototype method.

6. Evaluate the acceptable value of the usable frequencies at which the application of the test procedures provides the required data rate.

The specified procedure can be implemented on the basis of the formation of a vector of operating frequencies and is an implementation of the formation of a vector of binary numbers, where the element numbers correspond to the frequency number, and the value of the element reflects the event of suitability / unsuitability of the operating frequency, for example, 1 - the frequency is suitable, 0 - the frequency is unusable. The procedure for generating a vector of binary numbers is similar to the formation of sequences of binary numbers and is given in [SV Dvornikov, AV Pshenichnikov, and others. Method for active control of operating frequencies. RF patent for invention 2710027 dated 12.24.2019.]. On the basis of counting the single values of the vector elements, the number of suitable frequencies is determined, which is compared with the threshold value. The threshold value of suitable frequencies is determined based on the need to implement the algorithm for the functioning of the data transmission system [Borisov V.I., Zinchuk V.M., Limarev A.E. Noise immunity of radio communication systems by expanding the spectrum of signals by the method of pseudo-random tuning of the operating frequency // Ed. IN AND. Borisov; ed. 2nd, rev. and add. - M .: RadioSoft, 2008. - 512 p.], [Adaptive automated systems of military radio communication / Yu.P. Kilimnik, E.V. Lebedinsky, V.K. Prokhorov, A.N. Sharov. // Ed. A.N. Sharova. - L .: YOU, 1978. - 284 p.], [Pshenichnikov A.V. Models and methods of noise protection: monograph. - SPb .: 2017. - 132 p.].

7. If the total number of unusable frequencies exceeds the calculated permissible value, a special test signal is also transmitted at the unusable frequencies.

This procedure is implemented on the basis of transmitting a command to continue the analysis of frequencies and transmitting a test sequence. The command to continue the analysis procedure is formed by the method of forming a binary sequence of numbers, see [SV Dvornikov, AV Pshenichnikov, etc. Method of active control of operating frequencies. RF patent for invention 2710027 dated 12.24.2019.]. The test signal is generated based on the modulation of the test block. Modulation methods are known and are given, for example, in [B. Sklyar Digital communication. Theoretical foundations and practical application / Per. from English; Ed. A.V. Nazarenko. - M .: "Williams", 2003. - 1104 p.].

8. On the receiving side, a structural analysis of the features of the distortion of the test signal at each frequency at which it was transmitted is performed.

The implementation of this procedure can be implemented on the basis of the formation on the receiving side of the radio signal from the test block with the type of modulation identical to the transmitting side. Modulation methods are known and described, for example, in [B. Sklyar Digital communication. Theoretical foundations and practical application / Per. from English; Ed. A.V. Nazarenko - M .: "Williams", 2003. - 1104 p.].

The formation frequency is determined based on the filtering conditions and the linearity of the processing of the radio receiver paths, see, for example, in [GD Zavarzin, VA Martynov, BF Fedortsov. Radio receiving devices. - M. Military Publishing, 1973]. Further, the received and generated radio signals are subtracted at the processing frequency. The implementation of this procedure is advisable to implement on the methods of digital signal processing, presented, for example, in [Oppenheim AV, Shafer RV. Digital signal processing. - M .: Communication, 1979. - 416 p.]. Considering that this procedure imposes high requirements on the linearity of the radio receiver paths, it is advisable to carry out it before demodulation. Next, a spectral analysis of the signal obtained in this way is carried out. Methods of spectral analysis are known and are given, in particular, in [B. Sklyar Digital communication. Theoretical foundations and practical application / Per. from English; Ed. A.V. Nazarenko. - M .: "Williams", 2003. - 1104 p.]. Then the signal is compared with the reference types of signals and interference, see RF patent for invention 2525302 dated 08/10/2014.

9. The results of the structural analysis are compared with previously prepared reference values.

This procedure is known and is given, for example, in the RF patent for invention No. 2525302 dated 08/10/2014. A distinctive feature of the implemented procedure is a comparison with the known spectral and energy characteristics of signals and interference, given, for example, in [B. Sklyar Digital communication. Theoretical foundations and practical application / Per. from English; Ed. A.V. Nazarenko. - M .: "Williams", 2003. - 1104 p.], And also in [Borisov V.I., Zinchuk V.M., Limarev A.E. Noise immunity of radio communication systems by expanding the spectrum of signals by the method of pseudo-random tuning of the operating frequency // Ed. IN AND. Borisov; ed. 2nd, rev. and add. - M .: RadioSoft, 2008. - 512 p.].

10. Based on the comparison results, a decision is made on the type of destructive impact.

On the basis of the characteristics identified in clauses 8, 9, the parameters of the impact are determined and compared with the known types of impacts, presented, in particular, [Borisov V.I., Zinchuk V.M., Limarev A.E. Noise immunity of radio communication systems by expanding the spectrum of signals by the method of pseudo-random tuning of the operating frequency // Ed. IN AND. Borisov; ed. 2nd, rev. and add. - M .: RadioSoft, 2008. - 512 p.], [Ivanov MS, Makarenko SI, Popov SA Noise immunity of communication systems with pseudo-random tuning of the operating frequency: monograph. - SPb .: own publishing house, 2013. - 166 p.].

11. Based on the results of claim 10, the parameters and modes of operation of the data transmission systems are changed.

The procedure for selecting parameters and modes of operation depending on the type of exposure is known and described, for example, in [Borisov V.I., Zinchuk V.M., Limarev A.E. Noise immunity of radio communication systems by expanding the spectrum of signals by the method of pseudo-random tuning of the operating frequency // Ed. IN AND. Borisov; ed. 2nd, rev. and add. - M .: RadioSoft, 2008. - 512 p.], [Adaptive automated systems of military radio communication / Yu.P. Kilimnik, E.V. Lebedinsky, V.K. Prokhorov, A.N. Sharov. // Ed. A.N. Sharova. - L .: YOU, 1978. - 284 p.], [Pshenichnikov A.V. Models and methods of noise protection: monograph. - SPb .: 2017. - 132 p.].

The simulation of the operation algorithm of the radio communication line based on the developed method revealed an increase in the analysis time T _{ai by} about 15-20% depending on the initial data, but at the same time, thanks to the new set of essential features in the claimed method, it became possible to increase the operation time T _ri of the transmission system data in conditions of a large number of unsuitable frequencies, which otherwise would mean a complete disruption of the data transmission system (T _ri → 0) and in the aggregate makes it possible to increase the data transmission rate in conditions of organized interference and achieve a technical result.

Claims (1)

A method for active control of operating frequencies with identification of the type of destructive effects, which consists in the fact that the information source sequentially sends at each of the possible operating frequencies a previously prepared test data block known on the receiving side, while the data transmission systems at the receiving and transmitting sides are rebuilt from the frequency to the frequency absolutely synchronously, the information receiver estimates the parameters of the communication channel at the corresponding operating frequency and informs the transmitting side about the quality of the communication channel, after obtaining the necessary statistics for the entire allocated frequency resource, a decision is made on the choice of the operating frequency for data transmission, the transmitting side is informed about the quality of the channel at the frequency at which the prepared test block was received, while at the moment when the prepared test block is received at the current operating frequency, the transmitting side is simultaneously informed about the quality of the channel at the previous operating frequency, different based on the analysis performed, the allowable number of usable operating frequencies is calculated, at which the application of testing procedures still provides the required data transfer rate, if the total number of unusable frequencies exceeds the calculated allowable number, then a test signal is additionally transmitted at each identified unusable operating frequency, and on the receiving side, a structural analysis of the features of its distortions is performed at each operating frequency at which it was transmitted, the results of the structural analysis are compared with previously prepared reference values, based on the results of comparison with which a decision is made on the type of destructive effect and, if necessary, the parameters and operating modes of the transmission system are changed data.

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