RU2732486C1 - Method for radio suppression of cognitive radio communication systems - Google Patents

Abstract

FIELD: radio equipment.

SUBSTANCE: invention relates to radio engineering, namely to artificial interference generation, and can be used for radio suppression (RS) of cognitive radio communication systems (RCS), information on used working frequencies of which is unknown and cannot be determined. RCS RS method consists in analysing frequency band ΔF, receive signals from radiation sources in frequency band ΔF within a cycle time Tp, the frequency band ΔF is divided into N subbands with frequency intervals Δƒ_n in accordance with operating frequency subbands of allowed radio electronic devices operating in frequency band ΔF, in all subbands of frequency band ΔF, with the exception of subbands in which currently permitted radioelectronic equipment is operating, and subbands which are programmed in accordance with the electromagnetic environment, which are optimal for jamming, emitting pulse interference signals of a certain duration and power such that a RCS decision is made on inadmissibility of operation at said frequencies, and for radio exchange of RCS there selected are pre-programmed subbands, in which interference signal is absent, upon detection of RCS operation in subbands free from interference radiation, transmitting transmission mode and structure modulating voltage control signals are generated, modulating, amplifying and emitting impact interference signals, wherein new subbands proposed for RCS operation are programmed.

EFFECT: technical result of this invention is broader functional capabilities of the system of electronic suppression by hindering or disrupting training of cognitive radio communication systems.

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Description

The invention relates to radio engineering, namely to the technique of creating artificial interference and can be used for radio suppression (RP) of cognitive radio communication systems (CRS), information about the used operating frequencies of which is not known and cannot be determined.

A known method of generating interference, described in the book [1]. The method includes detecting radiation of a radio electronic device (RES), separating a signal, amplifying and processing it, technical analysis of the parameters of the detected signal and selection of the interference structure, amplification and emission of interference signals into the air.

The disadvantage of the analogue lies in the fact that this method will provide effective suppression of the communication system in the event that the radio communication system uses a single carrier frequency for its operation. In the case of work of workover, which constantly assess the surrounding electromagnetic environment (EMO) and adapt the parameters of the transmitted signals each time according to the results of the analysis of the EMO, the interference is emitted at one frequency, and the work of the radio emission source is carried out at another.

A known method of generating radio interference [2]. This analogue includes receiving a signal from a radiation source, determining the frequency and structural parameters of this signal (carrier frequency, transmission duration, moments of the beginning and end of the transmission of a neighboring "friendly transmitter"), formation of the structure of the modulating interference voltage, modulation of the exciter signal with the received modulating voltage, amplification and radiation broadcast a jamming radio signal only after the end of the work of a neighboring transmitter.

The disadvantage of this method is that it allows you to suppress communication systems operating only in the simplex mode of receiving and transmitting messages and does not take into account the possibility of the DAC to adapt the parameters of signal transmission each time according to the results of the analysis of the EMO.

The known method of the RP of communication channels (CC) [3]. The method includes receiving signals from radiation sources, determining their parameters, measuring the total time during which there is no reception of signals at the operating frequencies of radiation sources in a given time interval, distributing the time resource of the RF between the operating frequencies of the radiation sources subject to the RF. Formation of the structure of control signals that set the operating mode of the transmission control device and the structure of the modulating voltage, modulation of exciter signals, their amplification in the interference transmitter and emission into the air in the mode specified by the signal of the transmission control device according to the time resource of the RP, during an interval equal to the time of absence of reception on suppressed frequency.

The disadvantage of this method lies in the fact that it allows you to effectively carry out the RP of only those communication systems that use a fairly limited number of operating frequencies for data transmission, and the information on the degree of their load is fully known.

The known method of RP KS [4]. In the method, signals from radiation sources are received in a certain frequency band for a certain time cycle at each operating frequency of the radiation source, their parameters are determined and, based on the measured parameters of the received signal, signals are generated to control the transmission mode and the structure of modulating voltages, modulate, amplify and emit interference signals ...

The disadvantage of this method is that it has a limited area of application, since it provides an effective RP of the CS only if, during the considered time cycle, all values of the operating frequencies of the radiation source are revealed and does not provide optimal conditions for suppressing cognitive radio systems.

The closest in technical essence to the claimed method is the RP KS method [5].

In the prototype method, signals from radiation sources are received in a frequency band for a certain time cycle, and at each operating frequency of the radiation source, the time during which the signal exists at each frequency is measured. The minimum value is selected from the number of measured time intervals, signals are generated to control the transmission mode and the structure of the modulating voltages, modulate, amplify and emit interference signals during a certain time cycle, and the frequency band is divided into N subbands with equal frequency intervals, and the interference signal is successively radiated to each of the subbands starting from the first, while the duration of emission of the interference signal is chosen so that for the minimum value of the emission time, the interference signal is emitted on each subband.

The disadvantage of the prototype method is that, when working in the RNC frequency band, its efficiency decreases, since RRS is able to learn and adapt to changes in EMO in real time. Also, this approach will not allow permitted RES to work.

The technical result of this invention is to expand the functionality of the electronic suppression system by hindering or impairing the learning of cognitive radio communication systems.

To achieve the specified technical result in the known method of the RP KS, including the analysis of the frequency band ΔF, receiving signals from radiation sources in the frequency band ΔF during the time cycle T _p , dividing the frequency band ΔF into N subbands with equal frequency intervals, generating control signals for the transmission mode and the structure of modulating voltages, modulation, amplification and emission of interference signals. In this case, the frequency band ΔF is divided into N subbands with frequency intervals, in accordance with the operating frequency subbands of the permitted radio electronic means operating in the frequency band ΔF. In all sub-bands of the frequency band ΔF, with the exception of the sub-bands in which authorized radio electronic means are currently operating and the sub-bands optimal for jamming, determined by software in accordance with the electromagnetic environment, pulsed interference signals of a certain duration and power are emitted, so that the DAC is received the decision on the inadmissibility of working at these frequencies, and for the radio exchange of the DAC, pre-defined software sub-bands were selected, in which there is no interference signal. Upon detection of the fact of operation of the DAC in subbands free from interference radiation, signals are generated to control the transmission mode and the structure of modulating voltages, modulate, amplify and emit targeted interference signals, while the programmed definition of new subbands intended for the DAC operation is performed.

FIG. 1 shows a diagram of the organization of the RP DAC.

The method is implemented as follows.

At the initial moment of time SP 5 (by the interference station) (Fig. 1), the frequency band ΔF is analyzed during the time cycle T _p , as a result of which the frequency band ΔF is divided into N sub-bands in accordance with the operating frequency sub-bands of the permitted RES 3 and 4 ( Fig. 1). Further, SP 5 programmatically determines the subbands that are optimal for setting sighting interference and planned for the operation of DACs 1 and 2. For the remaining subbands of the frequency bands ΔF, with the exception of those in which permitted RES, for example, 3 and 4, are operating at the moment in question, pulsed interference signals of a certain duration and power, so that DAC 1 and 2, it was decided that it is impossible to work at these frequencies. In this regard, the DAC is left with a choice only between those sub-bands that have been identified by the SP 5 for the work of the DAC. When the SP 5 detects the operation of the KSR 1 and 2 at predetermined programmed frequencies, the SP 5 detects the fact of radiation, generates control signals for the transmission mode and the structure of modulating voltages, modulates, amplifies and emits targeted interference signals. At the same time, SP 5 makes a programmatic definition and reassignment of new subbands intended for the work of the DAC and an analysis of the EMO is carried out. When detecting the fact of radiation of the DAC at a new frequency, the procedure is repeated until, after analyzing the EMO, the DAC signal by the interference station is not detected. In this regard, the DAC is deprived of the training opportunity, which ensures the radio suppression of the communication channels of the DAC radiation source in the frequency band ΔF.

Thus, dividing the frequency band ΔF into N subbands with frequency intervals, in accordance with the operating frequency subbands of the permitted radio electronic means operating in the frequency band ΔF; emission of impulse interference signals of a certain duration and power in all sub-bands of the AF frequency band, with the exception of the sub-bands in which the permitted radio-electronic means are currently operating and the sub-bands optimal for jamming, determined by software in accordance with the electromagnetic environment, so that the DAC is decided on the inadmissibility of working at these frequencies; selection for radio traffic of the DAC of predetermined program subbands, in which there is no interference signal; upon detection of the fact of operation of the DAC in subbands free from interference radiation, signals for controlling the transmission mode and the structure of modulating voltages are generated, and targeted interference signals are modulated, amplified and emitted; programmed definition of new subbands intended for the operation of the DAC allows achieving a technical result, which consists in expanding the functionality of the electronic suppression system by complicating or disrupting the learning of cognitive radio communication systems.

Literature

1. Paliy A.I. Electronic warfare - 2nd ed., Revised. and add. - M .: Military publishing house, 1989 - 319 p.

2. European patent EP 0293167 A2 dated 30.11.88.

3. Patent RU 2104616 dated 02/10/1998

4. Patent RU 2450458 from 10.05.2012

5. Patent RU 2638940 dated 19.12.2017

Claims (1)

The method of radio suppression of cognitive radio communication systems (CRS), which consists in the fact that the frequency band ΔF is analyzed, the signals of the radiation sources in the frequency band ΔF are received during the time cycle T _p , the frequency band ΔF is divided into N subbands with equal frequency intervals, control signals are generated by the transmission mode and the structure of the modulating voltages, modulate, amplify and emit interference signals, characterized in that the frequency band ΔF is divided into N subbands with frequency intervals in accordance with the operating frequency subbands of permitted radio electronic means operating in the frequency band ΔF in all subbands of the frequency band ΔF, with the exception of sub-bands in which permitted radio electronic means are currently operating, and sub-bands optimal for jamming, determined by software in accordance with the electromagnetic environment, emit impulse interference signals of a certain duration and power in such a way that the DAC is resolved not about the inadmissibility of working at these frequencies, and for the radio exchange of the DAC, predefined software subbands were selected, in which there is no interference signal, upon detection of the fact of DAC operation in subbands free of interference radiation, signals for controlling the transmission mode and the structure of modulating voltages are generated, modulate, amplify and emit targeted interference signals, while making a programmatic definition of new subbands intended for the operation of the DAC.

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