RU2633984C1 - Method for assessing the interference immunity of radio communication lines of the receiving radio center - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: power levels of the signal are measured in the absence of interference and in the event of interference for any of the operating radio lines of the receiving radio center, the interference power level is calculated, and then the communication distance with correspondents is calculated, at which the information can be transmitted under interference conditions with a given quality for each of correspondents transmitters power gradations. The decision on interference immunity of radio communication lines is taken based on the results of comparison of communication distances with correspondents true values with the calculated values of communication distances, taking into account the correspondents transmitters power gradation.

EFFECT: ability to assess the interference immunity of radio links of the receiving radio center by comparing the true values of the communication distances with the calculated values, taking into account the correspondents transmitters power gradation.

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Description

The invention relates to telecommunications, to methods for assessing the noise immunity of radio communication lines (LRS) and can be used in organizing communications at new and existing receiving radio centers (PRC).

A known method for evaluating the information capabilities of a communication system (patent RU No. 2225074, H04L 29/02, 09/10/2005. Bull. No. 200525).

The essence of the known method is that as a universal generalized parameter characterizing the information capabilities of the communication system, use the cybernetic power of the communication system, obtained by multiplying the amount of information expressed by the number of information messages in the communication system both during storage and in the process transmission within the system, to the performance of the communication system, averaged over a given time interval.

The disadvantage of this method is that it does not allow to determine the degree of closeness of a communication system to its maximum capabilities for transmitting information and cannot be used to compare the information efficiency of communication systems with different topologies in different operating conditions.

There is a method of assessing the quality of radio communications, described in the training manual "Adaptive automated military radio communications systems." Yu.P. Kilimnik, E.V. Lebedinsky, V.K. Prokhorov, A.N. Balls. - YOU, 1978, 284 p. (see p. 19-21).

The essence of the known method lies in the fact that they receive signals of discrete messages (telegraph and telecode) and quantify the probability of erroneous reception of signal elements of discrete messages as the ratio of the number of distorted elements (pulses, transmissions) to the total number of transmitted elements.

The disadvantage of this method is that it allows you to determine the noise immunity only in conditions of direct suppression of radio lines. And procedures for assessing the quality of radio communications are possible only after demodulation of the received signals.

As a prototype, “Method for assessing the effectiveness of radio suppression of a satellite communication signal by interfering with the receiving systems of repeaters and a device for its implementation” was selected according to the RF patent No. 2420760, published on 02.27.2010, Bull. No. 6, by application 2009143758/09, 11/26/2009

The prototype method consists in measuring the carrier (central) frequency and the power level of the satellite signal in the absence of interference and when exposed to interference using a satellite jamming station.

Based on these data, the power ratio and the detuning of the carrier (central) frequency of the satellite signal in the absence of interference and when exposed to interference are calculated. Compare the obtained value of the detuning of the carrier (central) frequency with an acceptable value of the detuning of the carrier (central) frequency and, if the obtained value of the detuning exceeds the permissible value, decide on adjusting the frequency of the satellite signal when exposed to interference. The obtained value of the ratio of the power of the satellite signal in the absence of interference and when exposed to interference is compared with the acceptable value of the indicated powers and the results of comparison with the acceptable value are used to evaluate the radio interference suppression of the satellite signal when exposed to interference at the input of the relay receiving system.

The disadvantage of this method is that it allows you to evaluate the noise immunity of the LRS only in conditions of their direct suppression.

The purpose of the proposed method is to expand the scope of its application, namely, to provide the opportunity to evaluate the noise immunity of the LRS PRC by comparing the true values of the communication distances with the calculated values of the communication distances, taking into account the gradations of the power of the transmitters of the correspondents.

This goal is achieved by measuring the signal power level in the absence of interference and when exposed to interference, on the basis of these data calculate the power ratio and, based on the results of the comparison, decide on the noise immunity of the LRS.

At the same time, the signal power levels at the PRC are measured in the absence of interference and under the influence of interference for any of the operating LRS PRC. The interference power level is calculated, and then the distance of communication with correspondents is calculated at which information can be transmitted under the influence of interference with a given quality for each of the gradations of the power of the correspondent transmitters. And the decision on the noise immunity of the LRS is made by comparing the true values of the communication distances with the correspondents with the calculated values of the communication distances, taking into account the gradations of the power of the transmitters of the correspondents.

Thanks to the new set of essential features in the claimed method, the scope of its application is expanded due to procedures for calculating the level of interference power, calculating the distance of communication with correspondents, in which information can be transmitted under the influence of interference with a given quality for each of the gradations of the power of the correspondent transmitters, and comparing the true values communication distances with correspondents with calculated values of communication distances, taking into account gradations of transmitter power in.

The claimed method is illustrated by drawings, which show:

FIG. 1 is a diagram of the implementation of a method for evaluating the noise immunity of an LRS PRC.

The implementation of the proposed method is illustrated in FIG. one.

In FIG. 1 shows a source of interference (IP), which through a radio channel at a distance of D4 (suppression path) acts on the receiving ends of the LRS PRC (in Fig. 1 this is radio station (r / st) No. 4). In FIG. 1 shows: LRS No. 1, the length of which is D1; LRS No. 2, the length of which is D2; LRS No. 3, the length of which is D3.

At the receiving end of all radio communication lines, station No. 4 from the PRC is located, which in turn conducts work on LRS No. 1 with station No. 1, in Station No. 2 with station No. 2, and Station No. 3 with station Number 3.

On the receiving path r / st No. 4, when it is operating on the LRS No. 1, it is affected by interference of the FE (radio suppression path with a length of D4).

In addition, in FIG. 1 dashed lines show non-suppression zones for radio stations whose power is P _C 1 and P _C 2.

The essence of the proposed method is as follows.

For example, when working r / st No. 1 on LRS No. 1 with r / st No. 4 PRTS.

At the stage of operation of LRS No. 1, in the absence of interference from the SP on the receiving path of radio station No. 4, the levels of received radio emissions from radio station No. 1 are measured.

Procedures for measuring signal power are known, for example, see RF patent No. 2420760, published on 02.27.2010, Bull. No. 6, by application 2009143758/09, dated November 26, 2009

The measured signal power values P _C 1 for LRS No. 1 are stored.

After that, at the input of the receiving path r / st No. 4, the levels of received radio emissions are measured under conditions of setting interference IP.

As an example in FIG. 1 shows the reception conditions of the radio frequency station No. 4 of radio emission, representing an additive mixture of the signal power of the radio frequency channel No. 1 P _C 1 and the power of the IP R _IP , respectively, R _C 1 + P _IP .

The measured value P _C 1 + P _SP stored.

Then calculate the value of P _PI according to the following formula:

On the basis of the calculated value of _PI R, the distance of communication with correspondents is calculated at which information can be transmitted under the influence of interference with a given quality for each of the gradations of the power of the correspondent transmitters, i.e. _Since the distance D 1 for gradation power transmitters correspondent P _Since the distance D 1 and _C 2 for transmitter power gradation correspondents R _S 1 according to the formula

Here R _{P VX} is the power at the input of the receiving path of the suppressed r / st, which will be equal to the calculated value of the power of the IP according to the formula (1).

TO _P - suppression coefficient representing a minimum required power ratio R _SP interference to the desired signal power P _C at the receiver input, at which the predetermined (allowable) damage (radio quality). The concept and procedure for determining the acceptable value of the suppression coefficient are known (see page 55, AV Lenshin. On-board systems and electronic suppression systems. - Voronezh: Scientific Publishing and Printing Center, 2014. - 590 pp.).

P _C is the radiated power of the communication transmitter.

G _C - gain of the transmitting antenna p / st communication.

G _{PR C} - gain of the receiving antenna in the direction of the p / st connection.

Formula (2) is obtained from the expression (3.78) (see p. 228, A. Lenshin. On-board systems and electronic jamming systems. - Voronezh: Scientific Publishing and Printing Center, 2014. - 590 p.). Given the fact that the value of the interference signal will be calculated by the formula (1).

For correspondents who use r / st for communication with the CCP with different gradations of power, for example P _C 1 and P _C 2, in accordance with formula (2), the limiting values of communication distances (values D _C 1 and D _C 2, which are boundary values for non-suppression zones) at which information can be transmitted under the influence of interference with a given quality, i.e. with a given value To _P. In FIG. 1 shows non-suppression zones, respectively, for P _C 1 and P _C 2, provided that P _C 1 <P _C 2. Here, the value of D _C 1 corresponds to the non-suppression zone for power P _C 1, and the value of D _C 2 corresponds to the non-suppression zone for power P _C 2.

The shift of the center of the non-suppression zones is due to the difference in the distance to the SP (see p. 228-229, AV Lenshin. On-board systems and electronic jamming systems. - Voronezh: Scientific Publishing and Printing Center, 2014. - 590 pp.).

The decision on the noise immunity of the LRS is made by comparing the true values of the communication distances with the correspondents with the calculated values of the communication distances, taking into account the gradations of the power of the transmitters of the correspondents. For the one illustrated in FIG. 1 example is compared: the values of D1 and D _C 1 (power r / st No. 1 is equal to P _C 1); values of D2 and D _C 2 (power r / st No. 2 is equal to R _C 2); the values of D3 and D _C 2 (power p / st No. 2 is equal to P _C 2).

Since D1 <D _C 1, then LRS No. 1 is not suppressed, because D3 <D _C 2, then LRS No. 3 is not suppressed, and since D2 <D _C 2, then LRS No. 2 will be suppressed (shown by the dotted line in Fig. 1). Comparison procedures are known, for example, see RF patent No. 2419968 of 08/03/2009, published on 05/27/2011.

Thus, in the inventive method, when it is implemented by performing procedures for calculating the level of interference power, calculating the distance of communication with correspondents, in which it is possible to transmit information under the influence of interference with a given quality for each of the gradations of the power of the transmitters of the correspondents, comparing the true values of the communication distances with correspondents with the calculated values of communication distances, taking into account the gradations of the power of the transmitters of the correspondents, the goal of the proposed method is achieved, consisting in extension of its use. Namely, in providing the opportunity to assess the noise immunity of the LRS PRC by comparing the true values of communication distances with the calculated values of communication distances, taking into account the gradations of the power of the transmitters of the correspondents.

Claims (1)

A method for evaluating the noise immunity of radio links of a receiving radio center (PRC), which consists in measuring the signal power level in the absence of interference and when exposed to interference, on the basis of these data calculate the power ratio and make a decision on the noise immunity of radio links based on the results of comparison, characterized in that measure the signal power levels at the PRC in the absence of interference and when exposed to interference for any of the operating PRC radio links, calculate the interference power level, and then calculate the communication distance with correspondents, in which it is possible to transmit information under the influence of interference with a given quality for each of the gradations of the power of the correspondent transmitters, and the decision on the noise immunity of radio links is made by comparing the true values of the communication distances with the correspondents with the calculated values of the communication distances taking into account the gradations of the power of the correspondent transmitters .

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