RU2217874C2 - Radar jamming device - Google Patents

Abstract

FIELD: radio engineering. SUBSTANCE: proposed device is used for jamming pulse Doppler and pulse radars. Desired jamming is attained due to high precision of determining carrier frequency of radar sounding signal and degree of fitness between parameters of signals received and those of radar to be jammed. To this end proposed jamming device using relevant connections is provided with newly introduced pulse length responding signal selector with N inputs and N outputs included in time interval measuring unit, N frequency channels, each incorporating series-connected mixer of signal- frequency estimating subsystem, intermediate-frequency amplifier, electronic selector switch, amplifier/limiter selector switch, frequency discriminator, voltage-controlled intermediate-frequency channel adjusting unit, electronic switching unit, mixer of input-signal frequency recovery subsystem, frequency-channel band filter, high-frequency preamplifier, balance modulator, output band filter, and also modulating-signal shaping device included in pulse generator and noise generator. EFFECT: enhanced spectral density of noise energy potential. 1 cl, 1 dwg

Description

 The invention relates to radio engineering and can be used for electronic suppression of pulse-Doppler and pulse radar stations.

 A known radio interference station with automatic tuning to the frequencies of the suppressed means [1], comprising a transmitting and receiving antenna, a transmit-receive switch, a pulse transceiver generator, a high-frequency amplifier (UHF), a receiver mixer, an intermediate frequency amplifier (UPC), a limiter, a discriminator, a modulator , local oscillator, high-frequency circuits, transmitter mixer, intermediate-frequency generator, modulator and frequency modulator, which alternately turns on the receiver and transmitter, which determines the frequency of the signal the enemy’s radar and automatically tunes the frequency of the transmitter to the frequency of the received signal.

 A disadvantage of the known jamming station (SP) is the low efficiency of its operation under the conditions of actual loading of the range by different radars, when, despite the presence of several radars operating at different frequencies in the antenna pattern of the antenna (BPS), only one of them will be suppressed. In addition, due to the use of only one informative feature (radiation frequency) when identifying the radar to be suppressed, the suppression of own electronic means (RES) is not ruled out.

 Also known is a multi-channel automated device for interfering with radar stations [2], which contains a series-connected receiving antenna, input switch, UHF, switch, output UHF and transmitting antenna, as well as a splitter, the input of which is connected to the output of UHF and the input of the switch, and N outputs connected to the corresponding inputs of the chains, each of which consists of a series-connected band-pass filter, detector, video amplifier (VUS), the driver of the control strobe switch key circuit, the second input of which is connected to the output of the corresponding band-pass filter, and the output is connected to the corresponding of the N inputs of the adder, the output of which is connected to the output of the switch and the first input of the output UHF, the second input of which is connected to the second output of the strobe generator, the first output of which is connected with the second input of the input switch.

 A disadvantage of the known device is the low spectral density of the interference energy potential, due to the lack of a fine structure of the received signal in the analysis device, insufficient accuracy of determining the carrier frequency and the need for using an oversized spectrum width of the modulating noise signal. An increase in the spectrum of emitted frequencies leads to inefficient use of the transmitter power, does not exclude the suppression of its own radar, and makes it difficult to ensure electromagnetic compatibility (EMC) with other RES.

 The closest in technical essence to the proposed device is an interference station [3], containing a receiving antenna, input key, UHF broadband, switch, splitter, bandpass filter, detector, video amplifier, control strobe driver, key switch switch, decoder, control and synchronization unit (BUS), the adder, the output of the UHF, the output channel switch, the strobe generator, the transmitting antenna and the unit for measuring time intervals.

 A known jamming station operates as follows.

 The signals received by the receiving antenna through the input switch, open in reconnaissance mode, amplified by the input UHF, in accordance with its carrier frequency, get together with the noise signal into one of the frequency channels, where they are detected, amplified, and fed to the channel control strobe driver and the time measurement unit channel intervals. In response to an incoming signal, the amplitude of which exceeds a certain threshold level of the driver of the control strobe, a switch of the key circuit is closed in this frequency channel.

 In the device for measuring the time intervals of the channels, the signals are selected by the pulse repetition period. Based on the results of the analysis of these measurements and the measurement of the duration of the radar signals in the control and synchronization unit, frequency channel control signals are generated that determine the width of the interference spectrum and the temporal parameters of the interference signal.

 The disadvantage of the prototype is the lack of adaptation of the interference parameters to the signal parameters of the suppressed radar, including to a change in its mode, which is associated with insufficient accuracy and efficiency of measuring the parameters of radar signals and the need in connection with this to emit an excess interference spectrum equal in width to at least the passband of the channel band-pass filter, regardless of the spectral width of the probe signal of the suppressed radar. As a result, the spectral density of the energy potential of the interference decreases, and the possibility of providing an EMC device with other RES in the group becomes significantly more complicated.

 The problem solved by the invention is the creation of an interference device with high spectral density, which ensures the adaptation of the interference parameters to the parameters of the suppressed radar and provides electromagnetic compatibility of the device with other electronic means.

 The solution to this problem is achieved by the fact that in a device containing a receiving antenna, an input switch, a broadband UHF, a splitter, an adder, frequency channels with bandpass filters, detectors, video amplifiers, input and output channel switches, and also a time interval measurement unit, containing composed of a signal selector for the pulse repetition period with N inputs and N outputs, a control and synchronization unit (BUS), an UHF output and a transmitting antenna, the output of the input switch being the first input connected to the output of the receiving antenna, connected to the input of the broadband UHF, the output of which is connected to the input of the splitter, N outputs of which are connected to the corresponding inputs of N bandpass filters, the outputs of which are connected to the first inputs of the input channel switches and detectors corresponding to the channel, the outputs of which are connected to the inputs of the video amplifiers connected by their outputs to the corresponding inputs of the selector by the pulse repetition period, N outputs of which are connected to the corresponding given frequency channel the first input of the control and synchronization unit, N first outputs of which are connected to the control input of the corresponding input channel switch, N second outputs - to the control input of the output channel switch, and the output of the latter is connected to the adder input corresponding to the given frequency channel, the output of which is connected to the input of the output of the UHF the output of which is connected to the transmitting antenna, a modulating signal generating device has been introduced, which includes pulse and noise generators, as well as a mixer odsystems for determining the frequency of the input signal, an intermediate frequency amplifier (VHF), a voltage controlled oscillator (VCO), an electronic switch that alternately switches the signals of the VHF and VCO supplied to its first and second inputs, an amplifier-limiter, a frequency discriminator, an inverter the frequency channel, providing the formation of voltage tuning frequency VCO, comparing the output voltages of the frequency discriminator, the formation and transmission of the error signal compared to voltage to the corresponding input of the BUS, as well as the electronic switch, to the information input of which the output of the VCO is connected, a reference generator, the output signal of which is fed to the second inputs of the mixers of the subsystems for determining and reproducing the frequency of the input signal, a bandpass filter, a preliminary UHF, balanced modulator, the first and second inputs of which respectively receive signals from the outputs of the preliminary UHF and the device for generating modulating signals, the frequency and time parameters of which are set are supplied with voltage from the corresponding seventh and sixth outputs of the busbar, the remaining outputs of which are connected to the control inputs of the electronic switch and switch, and a signal selector for duration is included in the time interval measurement unit, connected by N inputs to the output of the corresponding video amplifier, and outputs to N second inputs BUS

 The newly introduced elements and communications make it possible to increase the accuracy of measuring the carrier frequency of the probing radar signals and to increase the degree of correspondence of the received signals to the parameters of the signals to be suppressed by the radar.

 The positive effect is to increase the efficiency of the device for creating interference by increasing the spectral density of the energy potential of the interference and increasing the degree of adaptation of its frequency and time parameters to changing the parameters of the signals to be suppressed radar. The specified set of distinctive features is new, since the well-known literature on the issues of radio-electronic suppression of airborne radars was not given.

 The drawing shows a structural electrical diagram of the proposed device to create radar interference.

The device contains a receiving antenna 1 for receiving signals emitted by the radar, its output is connected to the first input of the input switch 2; the antenna may be, for example, a mirror, horn or vibrator;
input switch 2 - for connecting the receiving path to the intelligence mode under the influence of the control signal of the control and synchronization unit 9, its output is connected to the input of the UHF 3; the switch can be made in the form of microassemblies on pin diodes [4, p.222];
UHF 3 - to amplify the signals received by the receiving antenna 1, it can be performed, for example, in the form of a cascade connection of low-noise transistors [5, p. 291];
a splitter 4 for supplying an input signal to the outputs of the bandpass filters 5, N of its outputs are connected to the N inputs of the bandpass filters 5, the splitter can be made in the form of a multi-pole device of a parallel type, the strip design of such a splitter is given, for example, in [6, p.119] ;
input band-pass filters 5 - to separate the input signals by the carrier frequency, their outputs are connected to the inputs of the detectors 6 and input switches 10 of their frequency channels, the filters can be made on the basis of LC elements, spiral resonators, comb structures [7, p.22] ;
detector 6 - for detecting a signal of a given frequency channel, its output is connected to the input of video amplifier 7; it can be performed, for example, based on point microwave diodes [5, p.23];
video amplifier 7 - to amplify the detected signal, its output is connected to the corresponding inputs of the signal selectors for a repetition period of 8 ₁ and pulse duration 8 ₂ block 8 measuring time intervals;
block 8 measuring time intervals - to highlight the signals with the given pulse parameters, its constituents 8 ₁ and 8 ₂ establish the fact of the presence in the frequency channels of the signals with the specified time values, including the repetition period (selector 8 ₁ ) and duration (selector 8 ₂ ) pulses; its N first and N second outputs are connected to N first and N second inputs of the BUS 9 corresponding to a given frequency channel; selection devices 8 ₁ and 8 _{2 of} block 8 can be performed, for example, in the form of detectors of time interval selectors [8, p. 522, 553];
control and synchronization unit 9 - for controlling the operation of frequency channels and generating interference parameters, its first output is connected to the control input of the input switch 2, N second, third, fourth, fifth, seventh and sixth outputs are connected to the control inputs of the output channel switch 25, input channel switch 10, the electronic switch 13, the electronic switch 18, the noise generator 26 is ₁ pulse generator 26 ₂ WCD may be configured as a set of analog-to-digital and digital to analog converters and microprocessors corresponding architecture [9, p.158, 162];
input channel switch 10 - for unlocking the frequency channel, its output is connected to the input of the mixer 11 of the subsystem for determining the carrier frequency of the received signal, the switch can be performed, for example, based on switching pin diodes [4, p.222];
mixer 11 of the subsystem for determining the frequency of the signal — for converting the signal from the switch 10 to an intermediate frequency, the mixer can be made, for example, based on crystalline, tunneling inverted or parametric diodes [5, p.221];
UPCH 12 - to amplify the intermediate frequency signal supplied to its input from the mixer 11, the output of the UPCH is connected to the first input of the electronic switch 13, the amplifier, depending on the requirements and linearity of the path, can be performed on bipolar or field-effect transistors [10, p. 286, 306];
electronic switch 13 - for sequential alternating connection to the intermediate frequency path of the signals arriving: at the first input from the output of the amplifier 12 and to the second input from the output of the voltage controlled generator 17, the output of the switch 13 is connected to the input of the amplifier-limiter 14, the switch 13 can be made, for example, based on switching pin diodes [4, p. 222];
limiter amplifier 14 — for amplification and limitation of the signals arriving at its input from the output of the electronic switch 13, it can be performed, for example, on pnp transistors [11, p.349];
frequency discriminator 15 - for detecting the signals coming from the output of the amplifier-limiter 14, the output of the discriminator 15 is connected to the input of the IF channel tuning unit 16, the discriminator can be performed, for example, based on a double-circuit filter circuit in the load of the collector or anode circuit of the amplifier-limiter 14 [12, p.401];
block 16 tuning the IF path of the frequency channel - to generate a control voltage proportional to the mismatch between the frequency of the generator 17, controlled by the voltage, the input of which is connected to the output of the block 16, and the frequency of the input signal converted to the IF, the voltage corresponding to the frequency values of the mentioned signals comes from the output discriminator 15 to the input of block 16, a signal about the end of tuning of block 16 of the corresponding frequency channel is supplied from the second output to the third input corresponding to this channel 9 Lok control and synchronization unit 16 setting the inverter realization tract can be effected on the basis of, e.g., a digital AFC system, involving the use microassemblages plurality of digital processing, including analog-to-digital and digital-to-analog converters, comparators, differential amplifiers and integrators [13, p. 317];
voltage controlled oscillator (VCO) 17 — to generate intermediate frequency signals from the control voltage coming from the inverter’s tuning unit 16, from the VCO 17 output the signal is supplied to the second input of the electronic switch 13 and to the first input of the electronic switch 18, the VCO can be made , for example, based on a change in reactivity (varicap capacity) introduced into the circuit of a tunable generator [13, p. 308];
electronic switch 18 - for connecting the output signal of the VCO 17 to the first input of the mixer 20 of the signal frequency reproducing subsystem, the switch can be made, for example, based on switching pin diodes [4, p.222];
reference generator 19 - for generating highly stable harmonic oscillations, its output is connected to the second inputs of the mixer 11 of the signal frequency determination subsystem and mixer 20 of the playback subsystem, the generator can be performed, for example, based on an LC generator with quartz stabilization [14, p.303] ;
mixer 20 of the signal frequency reproducing subsystem - for converting the IF signal arriving at its first input into the frequency of the input signal of its frequency channel, the output of the mixer 20 is connected to the input of the bandpass filter 21, the mixer can be made, for example, based on crystalline, tunneling inverted or parametric diodes [5, p.221];
band-pass filter of the frequency channel 21 - for frequency selection of the signals of a given frequency channel arriving at its input from the output of the mixer 20, the output of the filter 21 is connected to the input of the preliminary UHF 22, the filter, depending on the range, can be based on LC elements, spiral resonators or comb structures [7, p.22];
preliminary UHF 22 - to amplify the RF signals coming from the output of the bandpass filter 21, the output of the UHF 22 is connected to the input of the balanced modulator 23, the UHF can be based on the serial connection of transistor stages [5, p. 291];
balanced modulator 23 - to modulate the harmonic microwave signal supplied to its first input from the output of the preliminary UHF, a noise signal fed to the second input of the modulator from the output of the noise generator 26 ₂ , the output of the modulator is connected to the input of the bandpass filter 24, the balanced modulator can be performed, for example, based on mixing microwave diodes connected in a balanced circuit [11, p.260];
output band-pass filter 24 - for selection of signals of a given frequency channel arriving at its input from the output of the balanced modulator 23, the filter output is connected to the second input of the output channel switch 25, the filter 24 can be made on the basis of LC elements, spiral resonators, comb structures [ 7, p.22];
output channel switch 25 - for connecting the path of the subsystem for reproducing the frequency of the signal effected by the control signal supplied to its first input from the second output corresponding to this frequency channel, control and synchronization unit 9, the output of the channel switch 25 is connected to one of the inputs corresponding to this frequency channel, adder 27, the switch 25 can be performed, for example, based on switching pin diodes [4, p.222];
a modulating signal generating device 26 for generating a noise signal with predetermined frequency and time characteristics;
noise generator 26 ₁ - for generating a noise modulating signal, across the width of the spectrum adequate to the signal being suppressed by the radar or its operation mode, under the influence of a control signal from the seventh output corresponding to this frequency channel, control and synchronization unit 9, the output of the noise generator 26 _{1 is} connected with the input of the pulse generator 26 ₂ , the noise generator 26 ₁ can be made, for example, based on noise diodes [15, p.114];
pulse generator 26 ₂ - for generating video pulses of a given duration under the influence of a control signal from the sixth output corresponding to a given frequency channel, control and synchronization unit 9, the output of pulse generator 26 _{2 is} connected to the second input of the balanced modulator 23, pulse generator 26 ₁ can be made, for example, based on transistor electronic keys [11, p. 340];
adder 27 - for supplying signals from frequency channels to the input of the output UHF 28, the adder can be performed, for example, based on broadband bridge circuits [15, p.157];
UHF output 28 - to amplify the interference signal coming to its input from the output of the adder 27, the UHF output is connected to the input of the transmitting antenna 29, UHF can be performed, for example, based on powerful transistors with broadband matching chains [16, p. 73];
transmitting antenna 29 - for the emission of interference signals arriving at its input from the output of the UHF 28, in the direction of the explored radar, the antenna can be, for example, a mirror, horn or vibrator.

 A device for creating interference to radar stations works as follows.

The signals received by the receiving antenna 1, through the input switch 2 open in reconnaissance mode, amplified by the input UHF 3, through the splitter 4, in accordance with its carrier frequency, through one of the bandpass filters 5 fall into one of the frequency channels where the detector 6 is detected, amplified video amplifier 7 and fed to the unit 8 of the measurement timing signal for selection of the received signals with the parameters located within a predetermined range of change: the selector 8 ₁ - the period of repetition, the selector 8 ₂ - pulse Width in. The output signals of the selectors, containing encoded information about the frequency channel and the pulse parameters of the probing radar signals, make it possible, based on a set of informative features, to decide whether the received signals belong to a certain type of radar. According to the results of evaluating the temporal characteristics of the pulses and choosing the type of radar to suppress, the control voltage is supplied from the outputs 3 of block 9 to the second input of the input switch 10 of the corresponding frequency channel, the switch 10 is opened, and the signal from the output of the bandpass filter 5 is fed to a chain of series-connected mixer 11 the second input of which receives the signal of the reference oscillator 19, UPCH 12, electronic switch 13, amplifier-limiter 14, frequency discriminator 15. The output voltage of the discriminator, respectively The current frequency of the input signal is stored in block 16 of the tuning of the IF channel of the frequency channel. The stored voltage is compared with the output voltage of the frequency discriminator 15 when applied to its input in accordance with the command received from the fourth output corresponding to this frequency channel, the control and synchronization unit 9 to the control third input of the electronic switch 13, through the chain of devices 13, 14 of the VCO signal 17.

Upon completion of the process of tuning the IF path of the frequency channel (reducing the mismatch between the compared output voltages of the discriminator to a predetermined threshold) by a command from the output 5 of block 9 to the second control input of the electronic switch 18, the signal from the output of the VCO 17 goes to the first input of the mixer 20 of the playback subsystem frequency, the second input of which receives the signal of the reference oscillator 19. The reproduced input signal from the output of the mixer 20 is supplied through a band-pass filter of the frequency channel 21 and Tel'nykh UHF 22 to balanced modulator 23, to the second input of which is connected in series with a noise generator 26, the pulse generator ₁ and 26 _{2 of} the device 26 forming a modulating signal the modulation signal is supplied for formation of the interference signal. The parameters of the modulating signal according to the spectral composition and impulse characteristics are set according to the instructions of block 9 (outputs 7 and 6) in accordance with the identification of signals to be suppressed by the radar performed in the block. The interference signal from the output of the balanced modulator 23 passes through a band-pass filter 24, the output channel switch 25 and after summing in the adder 27 is amplified by the output UHF 28, then it enters the transmitting antenna 29 and is radiated in the direction of the suppressed radar.

 The proposed device for creating radar interference allows to increase the accuracy of estimation and reproduction of the carrier frequency of the probing radar signal in comparison with the prototype 5-10 times (depending on the bandwidth of the frequency channel), thus providing a degree of adaptation to the parameters of the suppressed radar and improving the efficiency of the interfering signal by 7-10 dB.

 This makes it possible to optimize the width of the interference spectrum under conditions of changing signal parameters and operating modes of the radar to be suppressed, thereby increasing the spectral density of the energy potential of the emitted interference and providing a solution to the EMC device problem with other RES in the group.

Sources of information
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 2. US patent 3896439, IPC N 04 K 3/00, 1955.

 3. RF patent 2054806, IPC N 04 K 3/00, 1996.

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 5. I.M. Ainbinder. Input stages of radios. M .: Communication, 1973.

 6. Radio transmitting devices. Ed. O.A. Chelnokova, Moscow: Radio and Communications, 1982.

 7. G. Hansel. Filter calculation reference. M .: Sov. Radio, 1974.

 8. Ya. S. Yitzhoki, N.I. Ovchinnikov. Pulse and digital devices. M .: Sov. radio, 1973.

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 10. Yu.L. Simonov. Amplifiers of intermediate frequency. M .: Sov. radio, 1973.

 11. Handbook of electronic devices. Ed. D.P. Linda. T. 1, M .: Energy, 1978.

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Claims (1)

A device for interfering with radar stations, comprising a receiving antenna in series, an input switch, a high-frequency broadband amplifier (UHF), a splitter, N outputs of which are connected to the inputs of N input band-pass filters, connected by outputs to the inputs of input channel switches and detectors, N frequency channels , each of which includes a video amplifier connected to the detector output by an input, and an output bandpass filter and an output channel switch connected in series p, the output connected to the adder input corresponding to the given frequency channel, the output of which is connected to the input of the UHF output, the output connected to the input of the transmitting antenna, as well as a control and synchronization unit, a time interval measurement unit with a signal selector by the pulse repetition period with N inputs, each of which is connected to the output of the video amplifier of the corresponding frequency channel, and to N outputs, each of which is connected to the first input of the control and synchronization unit corresponding to a given frequency channel, characterized in that it includes a device for generating modulating signals, which includes a series-connected noise generator and a pulse generator, the control inputs of which are connected to the seventh and sixth outputs of the control and synchronization unit (BUS) corresponding to this frequency channel connected mixer of the subsystem for determining the frequency of the signal, the first input connected to the output of the input channel switch, an intermediate frequency amplifier (IF), electronic th switch, amplifier-limiter, frequency discriminator, tuner for the intermediate frequency path of the frequency channel, the control output of which is connected to the third input of the BUS, the generator controlled by voltage (VCO), the electronic switch, the control input of which is connected to the corresponding given frequency channel with the fifth output of the BUS, mixer of the subsystem for reproducing the frequency of the input signal, band-pass filter of the frequency channel, preliminary UHF, balanced modulator, the second input of which is connected to the output of the modulating signal generating device, and the output is connected to the input of the output bandpass filter, as well as a reference generator, the output of which is connected to the second inputs of the mixers of the subsystems for determining and reproducing frequency, and the output of the VCO is also connected to the second information input of the electronic switch, the control input of which is connected to the fourth output of the BUS, corresponding to a given frequency channel, the third output of which is connected to the control input of the input channel commutator ator, the first output of the busbar is connected to the control input of the input switch, and the signal interval measuring unit includes a signal selector by pulse duration, N inputs of which are connected to the output of a video amplifier of a given frequency channel, and N signal selector outputs by pulse duration - to the second N inputs control and synchronization unit of the corresponding frequency channel.