RU2682562C2 - Method of determining frequency in a matrix receiver - Google Patents

Abstract

FIELD: radio engineering.SUBSTANCE: invention relates to radio engineering, in particular to frequency measurement systems, and can be used in a matrix receiver of electronic intelligence. Method for determining the frequency in a matrix receiver is proposed. To clarify whether the signal belongs to a channel of the matrix receiver stage, the signal frequencies in the bands are measured from the edge of the operating frequency band to the middle of the channel (for the first and last channels of the receiver stage) and in the bands enclosed between the middle of the adjacent channels of the receiver stage (for the remaining channels of the stage) and comparing the numbers of the activated channel indicator of the stage with the measured frequency values.EFFECT: technical result consists in increasing the probability of unambiguous determination of the frequency both when a signal hits adjacent areas of adjacent frequency channels of one stage, and under conditions of receiving time-combined signals.1 cl, 3 dwg

Description

The invention relates to the radio and electronic industries and can be used in a matrix receiver of electronic intelligence to reduce the ambiguity of determining the frequency.

Given the high technical performance with relatively small mass and dimensions, matrix receivers are widely used in electronic intelligence tools. In the matrix receiver [1], the input signal, falling into the first stage, is divided into several frequency channels, in each of which it is transferred to the range of intermediate frequencies (IF) of the first stage. Further, the IF signal arrives at the next stage, where it is again divided by frequency into channels and in each channel it is transferred to the IF range of the second stage and so on until the last stage. Thus, the IF range after each stage is sequentially narrowed and, in addition, is transferred downward in frequency, which simplifies the final processing. Each frequency channel in all steps is equipped with an indicator indicating the number of the triggered channel. Given that, as a rule, the parameters of the received signal are a priori unknown, energy detectors are used as indicators, which form a sign of the presence of a signal when the signal energy value exceeds a predetermined detection threshold. The set of triggered indicators roughly determine the frequency of the received signal with an accuracy of half the channel bandwidth of the last stage. From the output of the last stage, the signal is usually fed to the processing, as a result of which the frequency in the intermediate frequency band of the last stage is measured with high accuracy. Comparing the measured value of the frequency in the IF range and the triggered indicators, the frequency of the received signal is specified.

The disadvantage of the matrix receiver is the ambiguity of determining the frequency. In accordance with the classification proposed in [2], the ambiguity may be due to the following reasons:

- the presence of spurious passband microwave filters (ambiguity of the first kind);

- low slope of the amplitude-frequency characteristics (AFC) of channel filters (second-order ambiguity);

- reception of time-aligned signals at two or more frequencies (ambiguity of the third kind).

An ambiguity of the second kind arises when strong signals get into adjacent areas of neighboring frequency channels. In FIG. 1, the signal is in the band of channel n, but since the bandpass filters do not have a perfectly rectangular frequency response, the same signal also falls into channel n + 1. If the signal is powerful, then the detectors in both channels are triggered. Since there is one signal in the IF range, but two detectors are triggered, determining the true frequency value is difficult. In FIG. 1, the true value of the frequency is shown by the solid line, and the false by the dotted line.

Varieties of the matrix receiver are known from the prior art in which the second kind of ambiguity is reduced by splitting the IF channels into two groups, for example, [3]. The first group consists of odd channels, the second - even. The signals from the outputs of the channels of the first group go to the first adder, from the outputs of the remaining channels to the second adder. The signals from the output of each adder are processed separately. Thus, when detectors are triggered in two adjacent channels belonging to different groups, the signal belonging to one of the channels is specified by the presence of a signal at the output of one of the adders.

The disadvantage of the device is as follows. In conditions of a complex signal environment, the probability of combining in time the sequences of signals emitted by various sources increases. Upon receipt of N time-aligned signals (N> 2) falling into the channels of one group, a third kind of ambiguity arises. In this case, at the output of one of the adders, N signals are present, and from 1 to N channel detectors are triggered. Accordingly, accurate determination of the frequencies of the received signals is difficult.

Known matrix receiver, which reduces the ambiguity of the third kind [4]. In the receiver, the first stage is supplemented with a functional unit, which, when detecting the simultaneous occurrence of signals in two frequency channels of the first stage, allows the determination of false frequency values due to the delay of the signal at the output of one channel of the first stage relative to the other. The node contains a combinational logic device, which, if necessary, connects a delay line in each channel with a fixed delay value. A signal passing without delay is processed first, and a delayed signal is processed second. Thus, the signal is assigned to one or another channel of the first stage of the matrix receiver.

The disadvantage of this device is the small maximum possible number of simultaneously received signals (two), for which the ambiguity of the third kind is reduced. Also, when a signal is taken from the delay line in the channel in which it operates, the signal is lost for processing (the signal is skipped). In addition, the delay line has a fixed delay value, therefore, if the duration of the signals is much shorter than the delay time, the time resource is inefficiently used - signal processing is performed much later than their end. This increases the time before responding.

Closest to the proposed method for determining the frequency in the matrix receiver is the method described in [5]. The specified method, selected as a prototype, allows to reduce the ambiguity of the third kind and ensures the absence of delay and skipping signals, as well as reducing the time before taking response actions. The method is based on the specification of the belonging of each received signal to one or another channel of the matrix receiver stage. To do this, measure the signal frequency in the range of operating frequencies of the receiver stage and compare the numbers of the triggered indicators of the channel channels with the measured frequency values. The measurement is performed using a frequency measuring device (UCH) connected to the corresponding stage. When comparing the numbers of the triggered indicators of the receiver channels and the frequency values determined by the UCH, the frequencies of the received signals are refined, which reduces the ambiguity of the frequency measurement. The maximum possible number of simultaneously processed signals, for which the ambiguity is reduced, corresponds to the number of UCH channels. The signal delay is determined by the inertia of the devices used and is negligible for the tasks to be solved. Signal skipping due to parallel viewing and the absence of delay lines is excluded. The absence of a signal delay ensures the minimum time before taking a response.

The disadvantage of this method of determining the frequency is the ambiguity of the second kind, caused by the distribution of the spectrum of modulated signals between adjacent channels when the signals hit the adjacent areas of the adjacent frequency channels, which leads to the determination of two frequencies.

The aim of the invention is to simultaneously reduce the ambiguity of determining the frequency in the matrix receiver when a signal hits the adjacent areas of adjacent frequency channels of one stage (second-order ambiguity) and the frequency ambiguity due to the reception of time-aligned signals (third-order ambiguity).

The technical result consists in providing an increased likelihood of a unique determination of the frequency both when a signal hits the adjacent areas of adjacent frequency channels of one stage, and under conditions of receiving time-aligned signals.

This result is achieved by the fact that in the matrix receiver for the first and last channels of the receiver stage, the signal frequencies in the bands from the edge of the working range of the stage frequencies to the middle of the channel are additionally measured, and for the remaining channels of the receiver stage, the signal frequencies in the bands enclosed between the middle of adjacent channels are additionally measured steps of the receiver, and compare the numbers of triggered indicators of the channel channels with the measured frequency values.

Measuring the frequency of signals in the bands enclosed between the midpoints of adjacent channels of the receiver stage can reduce the ambiguity of the second kind. When a signal enters the adjacent region of adjacent channels of a stage, additional frequency measurements are performed to determine whether the signal belongs to one of two channels in adjacent regions of the channels. When comparing the numbers of the triggered indicators of the receiver channels and the additionally measured frequency value, a false frequency value is excluded.

When two signals of different frequencies get into the same channel of the receiver and different channels of the UCH, the signals are recognized and the frequency is correctly determined. Thus, the method also provides a reduction of the third kind of ambiguity.

In FIG. 1 shows the case of a powerful signal falling into an adjacent region of neighboring channels.

In FIG. 2 shows the frequency plan of the matrix receiver stage, in which additional frequency measurements are performed.

In FIG. 3 is a structural diagram of a frequency measuring device.

The invention is illustrated using figure 2. On the upper axis, the channel bandwidth of one of the steps of the matrix receiver is conventionally shown. From FIG. 2 shows that the frequency response of the channels have slopes, which distinguishes them from perfectly rectangular and leads to the emergence of ambiguity of the second kind. The lower axis shows the bandwidths in which additional measurements of frequency values are performed.

The method can be implemented using a K - channel frequency measurement device (UCH), which performs measurements in the operating frequency range of the receiver stage.

The UCH connected to the input of the jth stage of the matrix receiver consists of an amplifier-limiter 1, processing channels 2.1-2.K and a processing device 6. The input of the device is the input of an amplifier-limiter 1, the output of which is connected to the inputs of the processing channels 2.1-2.K . Each channel 2.i (i = 1 ... K) contains a series-pass bandpass filter 3.i, which forms the channel bandwidth Δƒ _i , a frequency-dependent device 4.i, which has a frequency response slope in the band Δƒ _i , and detector 5.i. The outputs of the channels are connected to the input of the processing device 6. In this case, the number of channels U of the UCH is one more than the number of channels of the receiver stage, and the joints of the channels of the UCH correspond to the midpoints of the channels of the step.

When connecting a UCH to any receiver stage, the ambiguity of the frequency measurement in the next stage is eliminated. To completely eliminate the ambiguity, each stage, except the last, must be connected to one device. In the last stage, the device is not required.

When a signal enters the adjacent region of adjacent receiver channels, the signal frequency is measured by the ultra-high frequency. This clarifies the number of the triggered channel detector at the receiver stage and reduces the second-order ambiguity.

When two signals of different frequencies hit the same receiver channel and different UCH channels, signal recognition and the correct determination of the frequency without ambiguity are also performed. The same positive effect is retained when a larger number of different frequency signals are received, provided that no more than one signal enters each UCH channel. However, when two or more signals enter the band of one UCH channel connected to the first stage, the signals do not differ using the UCH. Thus, a UIC allows one to eliminate the third kind of ambiguity when receiving up to K + 1 different-frequency signals provided that the signals get into different UICH channels.

The frequency measurement device operates as follows. The signal from the input of the device enters the amplifier-limiter 1, eliminating the dependence of the signal on the amplitude so that signals of the same level arrive at the inputs of channels 2.1-2.K. From the output of the amplifier-limiter 1, the signal branches into channels 2.1-2.K. The frequency ranges of the channels Δƒ ₁ -Δƒ _{K are} formed by input bandpass filters 3.1-3.K. In each channel, passing through the ROM 4.i, depending on the frequency, the signal acquires the corresponding amplitude and is detected by the detector 5.i. The detected signals arrive at the processing device 6, which performs an analog-to-digital conversion to measure the amplitude of the signal in each channel 2.i, correlates this amplitude with the frequency table for each channel, and provides the signal frequency measured with a given accuracy. The numbers of the triggered channel indicators of the receiver are compared with the frequencies determined by the UCH. As a result, the frequencies of the received signals are refined, which increases the probability of a unique determination of the frequency.

The frequency-dependent device can be made in the form of a filter, the slope of the frequency response of which falls on the channel bandwidth Δƒ _i . Given the work in the microwave range, the detector can be performed on a pin diode. The processing device is digital and includes analog-to-digital converters that digitize the signal at the input. After digitization, the processing device digitally measures the amplitude of the signal in each channel, correlates this amplitude with the frequency table and provides the signal frequency measured with a given accuracy. The implementation of the remaining elements of the device is possible using a widespread electronic component base [6].

Information sources

1. Lenshin A.V. On-board systems and electronic suppression systems. Voronezh: Scientific. book, 2014.590 s.

2. Podstrigayev A.S., Likhachev V.P. The ambiguity of determining the frequency in the matrix receiver // Journal of Radio Electronics: electronic journal, 2015. No. 2. 19 sec

3. Patent RU 155553 U1, IPC Н04В 15/06. The receiving device / A.I. Toothless, A.S. Podstrigayev; Applicant and patent holder Open Joint Stock Company “Bryansk Electromechanical Plant”. - No. 2014151261/08; declared 12/17/2014; publ. 10/10/2015, Bull. No. 28. - 11 p.

4. Patent RU 2422845 C2, IPC G01S 7/285. Matrix Receiver / B.D. Anokhin, E.V. Anokhin, V.G. Kildyushevskaya, Fawzi Simohammed; patent holder of the Federal Aviation Technical University VPO “Military Aviation Engineering University” (Voronezh) of the Ministry of Defense of the Russian Federation. - No. 2009131254/09; declared 08/17/2009; publ. 02/27/2011, Bull. Number 18. - 11 p.

5. Patent RU 2587645 C1, IPC G01R 23/00. A method for determining the frequency in a matrix receiver and a device for its implementation / A.S. Podstrigayev, V.P. Likhachev; Applicant and patent holder Open Joint Stock Company “Bryansk Electromechanical Plant”. - No. 2015118979/28; declared 05/20/2015; publ. 06/20/2016, Bull. Number 17. - 10 s.

6. Catalog “PLATAN. Electronic Components ”[Electronic resource] // URL: http: //www.platan.ru/company/catalogue.html.

Claims (1)

A method for determining the frequency in a matrix receiver, in which the signal belonging to one or another channel of a stage of a matrix receiver is specified, characterized in that for the first and last channels of a stage of the receiver, signal frequencies are additionally measured in the bands from the edge of the working frequency range of the stage to the middle of the channel, and for the remaining channels of the receiver stage additionally measure the frequency of the signals in the bands enclosed between the middle of the adjacent channels of the receiver stage and compare the numbers of triggered indicators Catch steps with measured values of frequencies.

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