RU2726221C1 - Method of determining parameters of frequency-coded signals in an autocorrelation receiver - Google Patents

Abstract

FIELD: radio engineering and communication.SUBSTANCE: invention relates to radio engineering, particularly to methods and equipment for radio monitoring of radio-frequency sources. Said technical result is achieved by the fact that the received signal is filtered, delayed for a given time, the signal with its delayed copy is multiplied, the difference frequency of the signal is evaluated, the signal component at the difference frequency and the low-frequency component of the signal are picked up and obtained by the AFS. Obtained signal spectra are compared with given threshold values and the results of comparison are used to decide on the type of the received radar signal. If a decision is made to receive frequency-coded signals (FCS), then the main lobe of the AFS of the low-frequency component of the signal is selected, from which the duration of one discrete signal code is determined. Received signal is delayed for a time equal to the duration of one discrete code, the received signal with a delayed copy is multiplied and an AFS of the signal obtained after multiplication is obtained, from which the number of discrete samples, pulse duration and width of the signal spectrum are determined.EFFECT: technical result is the possibility of determining the presence of FCS and their parameters in an autocorrelation receiver (ACR).1 cl, 1 dwg

Description

The invention relates to the field of radio engineering, in particular, to methods and techniques for radio monitoring of radio emission sources.

A known method of receiving and processing frequency-manipulated signals [Zimarin V.I., Illarionov B.V., Koziratsky A.Yu., Kozlov S.V. Devices for receiving and processing signals / Textbook. - Voronezh: VUNC Air Force "VVA", 2015. - p. 189-192]: using a radio path, a demodulator, a solver and a clock generator.

The closest in technical essence (prototype) is a method for determining the types of radar signals in an autocorrelation receiver (ACP) [Likhachev VP, Veselkov AA, Nguyen Chong N. Characteristics of detection of linearly-frequency-modulated, phase-code-manipulated and simple radio pulses in an autocorrelation receiver / Likhachev V.P., Veselkov A.A., Nguyen Chong N. // Radio engineering, 2018, No. 8. - from. 71-76], which consists in checking the presence or absence of amplitude-frequency spectra (ASF) of the low-frequency component, which at the difference frequency of the resulting signal after multiplication and similar signal components at twice the frequency after multiplication with its delayed copy at a given threshold.

The disadvantages of the prototype method are the restriction on the types of signals (LFM, PCM and simple radio signals), the presence of which is determined, and the low probability of determining the presence of frequency-coded signals (CHKS) and the accuracy of determining its parameters.

The technical result of the invention is the ability to determine the presence of CHKS and its parameters in the automatic transmission.

The specified technical result is achieved by the fact that the received signal is filtered, delayed for a predetermined time, the signal is multiplied with its delayed copy, the difference frequency of the signal is estimated, the signal component at the difference frequency and the low-frequency component of the signal are extracted, their ASFs are obtained, the obtained signal spectra are compared with the specified threshold the values and according to the results of the comparison decide on the type of the received radar signal, according to the invention, in addition, if a decision is made to receive the frequency response, then the main lobe of the ASF of the low-frequency component of the signal is selected, by which the duration of one discrete signal code is determined, the received signal is delayed for a time equal to the duration one discrete code, multiply the received signal with a delayed copy and get the ASF received after multiplying the signal, which determines the number of samples, the pulse duration and the width of the signal spectrum.

The essence of the invention lies in the fact that if a decision is made to receive a frequency response, then the main lobe of the ASF of the low-frequency component of the signal is selected, according to which the duration of one discrete code of the signal is determined, the received signal is delayed for a time equal to the duration of one code discrete, the received signal is multiplied with a delayed copy and receive the ASF obtained after multiplying the signal, which determines the number of samples, the pulse duration and the width of the signal spectrum.

It is known that to determine the type of the received radar signal, the received signal is filtered, delayed for a predetermined time, the signal is multiplied with its delayed copy, the difference frequency of the signal is estimated, the signal component at the difference frequency and the low-frequency component of the signal are extracted, their ASFs are obtained, the level of which is determined by the type of the original signal [Likhachev V.P., Veselkov A.A., Nguyen Chong N. Characteristics of detection of linearly-frequency-modulated, phase-code-manipulated and simple radio pulses in the autocorrelation receiver / Likhachev V.P., Veselkov A.A., Nguyen Chong N. // Radio Engineering, 2018, No. 8. - from. 71-76]. The initial frequency response is characterized by the presence of a component at the difference frequency and a low-frequency component. Considering the result of determining the presence of a frequency response, various processing procedures are used and its time-frequency parameters are determined: the main lobe of the ASF of the low-frequency component of the signal is selected, by which the duration of one discrete code of the signal is determined, the received signal is delayed for a time equal to the duration of one code discrete, the received signal is multiplied with delayed copy and receive the ASF of the signal obtained after multiplication, by which the number of samples is determined, knowing the number of samples and the duration of one code sample determine the pulse duration and the width of the signal spectrum. This achieves the technical result indicated in the invention.

The method of determining the parameters of the frequency response in the automatic transmission can be implemented, for example, using a device, a diagram of which is shown in the figure, where it is indicated: 1.1 and 1.2 - bandpass filters; 2 - delay line; 3.1 and 3.2 multipliers; 4 - low pass filter; 5.1, 5.2 and 5.3 - blocks for obtaining the signal spectrum; 6.1 and 6.2 - threshold devices; 7 - decision block; 8 - meter frequency-time characteristics of the CHKS; 9 - spectrum allocation unit, designed to highlight the main lobe of the ASF of the low-frequency component of the signal; 10 - adjustable delay line. The purpose of the remaining elements of the device is clear from their names.

которая может быть, задана, например, предельной шириной спектра сигналов радиоэлектронных систем в заданном частотном диапазоне радиотехнического мониторинга [Радиоэлектронные системы; Основы построения и теория. Справочник. / Под ред. Я.Д. Ширмана. - М.: Радиотехника, 2007. - с. 297]. Выделенный сигнал задерживается в линии задержки 2 на время, определяемое как

и перемножается с его задержанной копией. Полосовым фильтром 1.2 выделяется составляющая сигнала на разностной частоте [Лихачев В.П., Веселков А.А., Нгуен Чонг Н. Характеристики обнаружения линейно-частотно-модулированных, фазо-кодо-манипулированных и простых радиоимпульсов в автокорреляционном приемнике / Лихачев В.П., Веселков А.А., Нгуен Чонг Н. // Радиотехника, 2018, №8. - с. 71-76]. Низкочастотным фильтром 4 выделяется низкочастотная составляющая на выходе перемножителя 3.1. Для сигналов на выходе фильтров 1.2 и 4 получают АЧС, максимальные значения которых сравниваются в пороговых устройствах 6.1 и 6.2 соответственно. Пороговое значение G_П может быть определено, например, по критерию Неймана-Пирсона при заданной вероятности ложной тревоги и вероятности правильного обнаружения [Смирнов Ю.А. Радиотехническая разведка - М.: Воениздат, 2001. - с. 237-240]. Принятые в пороговых устройствах 6.1 и 6.2, решения подаются на первый и второй входы блока принятия решения 7. Блок принимает решение о наличии ЧКС, если в двух входах сигнал "есть". Если принято решение о наличии ЧКС, то на выходе блока принятия решения 7 появляется сигнал, по которому включается работа измерителя 8. В блоке выделения спектра 9 производится выделение главного лепестка АЧС низкочастотной составляющей сигнала [Сергиенко А.Б. Цифровая обработка сигналов. СПб.: Питер, 2005. - с. 313-372], по ширине половины уровня максимума которого в измерителе 8 определяется длительность одного дискрета кода сигнала τ_д, затем подается полученное значение τ_д в регулируемую линию задержки 10, по которому устанавливается длительность задержки сигнала. Сигнал на выходе 1.1 задерживается в 10 на время, определяемое как τ_з2=τ_д и перемножается с задержанной копией в перемножителе 3.2. Для сигнала на выходе 3.2 получают АЧС, по которому в измерителе 8 определяется число дискретов, зная число дискретов и длительность одного дискрета кода определяют длительность импульса и ширину спектра ЧКС [Авиационные радиолокационные комплексы и системы / Под ред. П.И. Дудника - М.: ВВИА им. проф. Н.Е. Жуковского, 2006. -с. 326-332].The device operates as follows: the received signal is input to a band-pass filter 1.1 with a passband

which can be set, for example, by the maximum width of the spectrum of signals of electronic systems in a given frequency range of radio monitoring [Radio electronic systems; Fundamentals of construction and theory. Directory. / Ed. POISON. Shirman. - M .: Radio engineering, 2007. - p. 297]. The selected signal is delayed in delay line 2 for a time defined as

and multiplied with its delayed copy. Bandpass filter 1.2 isolates the component of the signal at the differential frequency [Likhachev VP, Veselkov AA, Nguyen Chong N. Detection characteristics of linearly-frequency-modulated, phase-code-manipulated and simple radio pulses in an autocorrelation receiver / Likhachev V.P. ., Veselkov A.A., Nguyen Chong N. // Radio engineering, 2018, No. 8. - from. 71-76]. The low-pass filter 4 is allocated low-frequency component at the output of the multiplier 3.1. For signals at the output of filters 1.2 and 4, ASFs are obtained, the maximum values of which are compared in threshold devices 6.1 and 6.2, respectively. The threshold value of G _P can be determined, for example, by the Neumann-Pearson criterion for a given probability of false alarm and the probability of correct detection [Smirnov Yu.A. Radio Engineering Intelligence - M.: Military Publishing House, 2001. - p. 237-240]. The decisions made in the threshold devices 6.1 and 6.2 are submitted to the first and second inputs of the decision block 7. The block makes a decision on the presence of a frequency response if there is an “if” signal in two inputs. If a decision is made on the presence of a frequency response, then at the output of decision block 7 a signal appears that triggers the operation of meter 8. In the spectrum allocation unit 9, the main lobe of the ASF is selected for the low-frequency component of the signal [A. Sergienko Digital signal processing. St. Petersburg: Peter, 2005 .-- p. 313-372], the width of the half maximum level of which in meter 8 determines the duration of one discrete signal code τ _d , then the obtained value τ _d is supplied to the adjustable delay line 10, which sets the duration of the signal delay. The signal at output 1.1 is delayed at 10 for a time, defined as τ _s2 = τ _d and multiplied with a delayed copy in the multiplier 3.2. For the signal at output 3.2, an ASF is obtained, according to which the number of samples is determined in meter 8, knowing the number of samples and the duration of one code sample, determine the pulse duration and the width of the frequency band spectrum [Aviation radar systems and systems / Ed. P.I. Dudnika - M.: VVIA them. prof. NOT. Zhukovsky, 2006.-p. 326-332].

Thus, in the proposed method for determining the parameters of the frequency response in the automatic transmission, the new significant features of the invention are newly introduced signal processing procedures.

The proposed technical solution is new, because from publicly available information there are no known methods that allow to detect and determine the time-frequency parameters of the frequency response in the automatic transmission.

The method can be successfully implemented on the basis of standard electronic devices and means.

Claims (1)

A method for determining the parameters of frequency-coded signals in an autocorrelation receiver, which consists in filtering the received signal, delaying it for a given time, multiplying the received signal with its delayed copy, estimating the difference frequency of the signal, extracting the signal component at the difference frequency and low-frequency component of the signal, obtaining their amplitude -frequency spectra (ASF), comparing the obtained signal spectra with predetermined threshold values and deciding on the type of received radar signal, characterized in that if a decision is made to receive a frequency-coded signal, the main lobe of the ASF of the low-frequency component of the signal is determined, which is used to determine the duration of one discrete code of the signal, delay the received signal for a time equal to the duration of one code discrete, multiply the received signal with a delayed copy and get the ASF received after multiplying the signal, which determines the number of samples, the duration heart rate and signal width.

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