RU2680106C1 - Frequency measuring device in matrix receiver - Google Patents

Abstract

FIELD: electrical engineering; radio engineering.SUBSTANCE: invention relates to the radio engineering and electronic industries and can be used in electronic intelligence to reduce the ambiguity in determining the frequency with the reception of two and more time-synchronized signals of different frequencies. Frequency measuring device comprises amplifier-limiter (1), processing channels (2), calibration channels (6) and processing device (8). Each processing channel (2) comprises series-connected bandpass filter (3), frequency-dependent device (4), and detector (5). Corresponding calibration channel (6) is connected to each processing channel (2). Each calibration channel (6) contains detector (7). Processing unit (8) calculates the difference of the output signals of each channel pair (2, 6) and compares it with the frequency table.EFFECT: introduction of calibration channels improves the accuracy of frequency determination.1 cl, 1 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 when receiving two or more time-aligned multi-frequency signals.

Given the high technical performance with relatively small mass and dimensions, matrix receivers are widely used in radio intelligence stations and jamming stations. In the matrix receiver [1], the input signal, falling into the first stage, is divided into several frequency channels and transferred to the range of intermediate frequencies (IF) of the first stage. The IF signal then goes to the next stage, where it is again divided by frequency and transferred to the IF range of the second stage and so on to 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. 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, during 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], when two or more time-aligned signals of different frequencies are received (for definiteness, we consider the signals to be narrow-band, i.e., such that the signal spectrum completely falls into the channel band of the last stage) due to the described matrix structure the receiver there is an ambiguity in determining the frequency of the third kind. The ambiguity lies in the fact that when signals are received at the input of an N-stage matrix receiver A, a lot of indicators are triggered, as a result of which several variants of determined frequencies are possible. Moreover, their maximum number is X = A ^N. It can be seen from the expression that the ambiguity in determining the frequency increases with an increase in the number of steps used. The emergence of an ambiguity of the third kind is possible in conditions of a complex signal situation (during an air raid, the creation of deliberate interference, the simultaneous operation of a large number of closely spaced electronic means, etc.)

The prior art device for measuring frequency (UICH) in a matrix receiver, which reduces the ambiguity of the third kind [3]. UCH is a functional unit that complements the first stage of the receiver and allows to detect false frequencies when detecting simultaneous signals in two frequency channels of the first stage due to the delay of the signal at the output of one channel of the first stage relative to the other. UICH 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 the described UIC is the small maximum possible number of simultaneously received signals (two), for which the ambiguity of the third kind is reduced. Also, while receiving a signal 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 device for measuring the frequency in the matrix receiver is a UCH described in [4]. The specified UIC, 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. A UCH connected to the input of the stage of the matrix receiver measures the frequency of the signal in the operating frequency range of this stage. UCH contains the amplifier-limiter, the processing channels and the processing device. Each processing channel contains a series-pass bandpass filter, a frequency-dependent device, and a detector. The inputs of the processing channels are connected to the outputs of the amplifier-limiter, and from the outputs of the channels the signal is supplied to the processing device. The principle of operation of this UICH 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, first, using the amplifier-limiter eliminate the dependence of the signal on the amplitude. As a result, the inputs of the channels receive signals of the same level. In each channel, depending on the frequency, using a frequency-dependent device, the signal acquires the corresponding amplitude and is then detected by the detector. The detected signals are fed to a processing device that performs an analog-to-digital conversion to measure the signal amplitude in each channel, correlates this amplitude with a frequency table for each channel and provides the signal frequency measured with a given accuracy in the range of operating frequencies of the receiver stage. 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 reduces the ambiguity of determining the frequency. 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 UIC is as follows. The frequency table of the processing device contains the measured values of the signal amplitude at the output of each channel. It is believed that the transmission coefficient of the channel is constant over time. However, for example, during long-term operation, UCH is heated (especially when used as part of on-board electronic equipment). As a result, the frequency response of limiting amplifiers and bandpass filters is changed, which means that the accuracy of measurements is reduced. The “aging” of the electronic components of limiter amplifiers also leads to a change in frequency response over time. Thus, the change in the accuracy of the ultrahigh frequency measurements as a function of time and temperature is not taken into account.

The aim of the invention is to reduce the dependence of the accuracy of the measurements UICH from time and temperature.

The technical result consists in increasing the accuracy of determining the frequency by the frequency measuring device, which refines the values of the frequencies determined by the matrix receiver when receiving a plurality of time-aligned signals.

This result is achieved by the fact that a calibration channel is additionally added to each processing channel to the known UCH. The calibration channel includes a detector. The input of the calibration channel is connected to the output of the bandpass filter. The channel output is connected to the input of the processing device. In this case, the number of inputs of the processing device in comparison with the embodiment of the UICH without calibration channels increases by 2 times. The processing device determines the difference (by subtraction or division) between the signals from the outputs of each channel pair formed by the main and calibration channels. Since the transmission coefficients of both channels differ only by the transmission coefficient of the frequency-dependent device, and the transmission coefficients of the limiting amplifier and the band-pass filter are common for them, when calculating the difference (difference or quotient) between the signals from the outputs of the calibration and main channels, the influence of instability of transmission coefficients an amplifier-limiter and a band-pass filter on the accuracy of the measurements UICH is eliminated. Thereby, the dependence of the accuracy of the ultrahigh frequency measurements on time and temperature decreases.

In FIG. 1 is a diagram of a frequency measuring device.

The frequency measuring device (Fig. 1) consists of an amplifier-limiter 1, processing channels 2.1-2.K, calibration channels 6.1-6.K and a processing device 8. The input UCH is the input of the amplifier-limiter 1, the output of which is connected to the inputs of the channels processing 2.1-2.K. Each processing 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, having a frequency response slope in the band Δƒ _i and detector 5.i. The inputs of the calibration channels 6.1-6.K are connected to the outputs of the bandpass filters 3.1-3.K of the corresponding processing channels 2.1-2.K. Each calibration channel 6.i contains a detector 7.i. The outputs of the processing channels 2.1-2.K and calibration channels 6.1-6.K are connected to the inputs of the processing device 8.

UICH works as follows. The signal from the input of the UIC is fed to the amplifier-limiter 1, which eliminates the dependence of the signal on the amplitude so that signals of the same level arrive at the inputs of the processing channels 2.1-2.K. From the output of the amplifier-limiter 1, the signal branches into processing channels 2.1-2.K. The frequency ranges of the processing channels Δƒ ₁ -Δƒ _{K are} formed by input bandpass filters 3.1-3.K. In each processing 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. From the output of the bandpass filter 3.i of each processing channel, the signal branches into the corresponding calibration channel 6.i, which contains the detector 7.i. The detected signals from the outputs of each pair of the processing channel 2.i and the calibration channel 6.i enter the processing device 8, which performs an analog-to-digital conversion to measure the amplitude of the signal in each channel. The processing device calculates the difference (difference or quotient) of the amplitudes of the digitized signals in each pair of channels 2.i and 6.i (i = 1 ... K), correlates the obtained value with a table of frequencies for each processing channel, and outputs the measured value with a given accuracy in the operating range receiver stage frequencies value of signal frequency. Unlike the prototype, for each frequency range Δƒ _{i, the} frequency table does not contain the amplitude of the signal at the output of the processing channel, but the difference in amplitudes between the signals at the outputs of the processing channel 2i and calibration channel 6.i.

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. The implementation of the remaining elements of the device is possible using a widespread electronic component base [5].

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. Pat. 2422845 Russian Federation, IPC G01S 7/285. Matrix receiver / Anokhin V.D., Anokhin E.V., Kildyushevskaya V.G., Simohammed Fausi; 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.

4. 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.

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

Claims (1)

A frequency measuring device in a matrix receiver comprising a limiter amplifier, processing channels and a processing device, wherein the output of the limiter amplifier is connected to the inputs of the processing channels, the outputs of the processing channels are connected to the inputs of the processing device, and each processing channel contains a series-pass bandpass filter dependent device and detector, characterized in that the corresponding calibration channel containing a detector is connected to the output of the bandpass filter of each processing channel, and you the course of each calibration channel is connected to the processing device.

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