RU69362U1 - REMEMBER AND FREQUENCY PLAYBACK - Google Patents

Abstract

The utility model relates to radio engineering and can be used in jamming stations to suppress active radar means.

The technical problem solved by the utility model is to increase the accuracy of remembering and reproducing the frequency of input wideband long-pulse signals, with complex types of in-pulse modulation, as well as the possibility of unlimited storage and replication of technical parameters of stored signals.

The frequency storage and reproduction device comprises an input and output frequency converters, a tunable local oscillator unit and a delay line, an output adder, input and output high-frequency amplifiers and power dividers, a control and monitoring unit, and an input high-frequency amplifier, an input power divider, a line delays, input frequency converter connected in series, output adder, frequency converter, power divider, high-frequency amplifier connected in series, re the tunable local oscillator unit is connected with its outputs to the second inputs of the input and output frequency converters, the first output of the control and control unit is connected to the second input of the delay line, the second output of the control and control unit is connected to the input of the tunable local oscillator unit, it also includes an instant frequency detection receiver, four-channel frequency-selective splitter of signals, a digital cell for storing and reproducing the frequency of the first channel, a digital cell for storing and reproducing the frequency of the second channel, a digital cell for storing and reproducing the frequency of the third channel, a digital cell for storing and reproducing the frequency of the fourth channel, a detector, a video amplifier, while the second output of the input power divider is connected to the input of the receiver for instantaneous determination of frequency, the output of which is connected to the first input of the unit control and monitoring, the output of the input frequency converter is connected to the input of a four-channel frequency-selective signal splitter, the first output of which is connected to the first input of the digital cell for storing and reproducing the frequency of the first channel, the second, third and fourth outputs of the four-channel frequency-selective splitter of signals are connected to the first inputs of the second, third and fourth digital cells for storing and reproducing the frequencies of the second, third and fourth channels, respectively, second, third ,

the fourth inputs of the digital memory cells and frequency reproduction of all four channels are connected to the third, fourth and fifth outputs of the control and monitoring unit, respectively, the outputs of four digital memory cells and frequency reproduction are connected to the inputs of the output adder, the second output of the output power divider is connected through a series-connected detector and video amplifier to the second input of the control and monitoring unit, each digital cell for storing and reproducing the frequencies of the first, second, third its and the fourth channel contains a channel power divider, the first output of which through a series-connected channel detector, a channel video amplifier, a comparator is connected to the first input of the storage device, the second output of the channel power divider is connected through a series-connected first channel frequency converter and an analog-to-digital converter with a second input storage device, the second input of the first channel frequency converter is connected to the first output of the channel hetero the input of which is connected to the third output of the control and monitoring unit, the second inputs of the analog-to-digital converter and digital-to-analog converter are connected to the fifth output of the control and monitoring unit, the third input of the storage device is connected to the fourth output of the control and monitoring unit, the first input is digital the analog converter is connected to the output of the storage device, the output of the digital-to-analog converter is connected to the first input of the second channel frequency converter, the second input of which is connected It is connected to the second output of the channel local oscillator, the output of the second channel frequency converter is the output of a digital cell for storing and reproducing frequency. Fig. 1

Description

The proposed utility model relates to radio engineering and can be used in means of active interference to suppress radar stations.

There is a station of multiple response interference described in the book [1] (S.A. Vakin, L.N. Shutov, Fundamentals of Radio Countermeasures and Radio-Technical Intelligence. M.: “Soviet Radio”, 1968, fig. 2.23, fig. 2.24, p. 123-125).

This station, built on the principle of multiple relay broadcasts of the suppressed radar, contains a receiving antenna, a frequency storage circuit (SZCH), a receiver, a delay circuit (SZ), a modulator, a high-frequency amplifier, a terminal amplifier, a transmitting antenna.

The input radio signal received by the antenna is fed simultaneously to the input of the receiver and the SZCh, which remembers the frequency of the input signal for a given time. From the output of the SZCH, the stored signal, which is a harmonic oscillation with a frequency approximately equal to the carrier frequency of the radar radiated, is fed to the input of a high-frequency amplifier. From the output of the receiver, the signal goes to the input of the SZ, which provides a delay of the received pulse for a given time. From the SZ output, the signal goes to the input of the modulator, which forms a series (burst) of pulses from each input signal, and transfers them to the other input of the high-frequency amplifier, opening it for the duration of the modulation pulses. The terminal amplifier performs the function of amplification, from the output of which interference pulses arrive at the transmitting antenna.

If the repetition rate of the probe pulses is constant, and the storage time of the carrier frequency in the SZCH is significantly longer than the duration of the input pulse, then depending on the amount of delay it is possible to create

radar screen false marks, both delayed relative to the target, and anticipatory.

The analog block diagram does not allow to effectively suppress radar with broadband signals with intrapulse frequency modulation or phase shift keying. So, for example, to create a leading range of interference by simple pulsed radar stations, interference stations using an analogue device for storing and reproducing the frequency of input signals are widely used. However, in relation to the suppression of broadband radar with linear frequency modulation (LFM), this method does not provide effective removal of the range strobe radar with intrapulse frequency modulation, due to inconsistency in the frequency of the reproduced radar pulse with the frequency of the input probe signal.

A device for generating signals of the operating frequencies of a transceiver of a radar station [2] (utility model certificate No. 17106, MPK7 Н03В 19/00, 21/00, publication date: March 10, 2001), comprising a mixer, the output of which is through a filter tuned to the central probing frequency signal f ₀ is connected to the output device, a first input connected to the source signal of the first heterodyne frequency f _r1, a second input via a filter tuned to the first intermediate frequency fp41, connected to the output of the second mixer input coupled s with the source signal of the second local oscillator outputs a frequency f _r2, and the oscillator whose frequency is equal to the second intermediate frequency f _p42, a source signal of the first local oscillator f _r1, is connected via a filter to the output of frequency multiplier N2 multiplicity connected the input to the output of the reference generator module comprising a power adder, the output of which is connected to the output of the module, and the inputs are connected through controlled key devices to the outputs of generators stabilized by resonators on surface acoustic waves, it inputs the key device controls connected to the outputs of the decoder, the input digital signal is coupled to an input device, a source of the second local oscillator f _r2, a multiplier multiplicity frequency N3, the output of which a filter is connected to the input of the second mixer and an input coupled to the oscillator output, stabilized resonator on surface acoustic waves and tuned to a subharmonic frequency of the second local oscillator, and the signal source of the second intermediate frequency is a frequency divider whose output is Inonii with the input of the second mixer and an input connected to the oscillator output, stabilized resonator surface acoustic wave and configured to subharmonic second intermediate frequency. This device is accepted as the second analogue.

The disadvantages of the second analogue are the same as those of the first one - it does not allow for high-precision reproduction of the carrier frequency of the input signals, multiple reading of the stored information to generate advanced leading interference to protect the space in front of the object where the jamming station is located.

The closest, according to the technical design of the proposed utility model, taken as a prototype, is a frequency determination and reproducing device [3], (utility model certificate No. 30214, IPC7 H01K 3/00, G01S 7/38, publication date: 20.06 .2003, Bull. No. 17), containing the first and second frequency converters and a local oscillator unit, a high-frequency input amplifier and a frequency-selective signal splitter, the output of which is connected to the second input of the first frequency converter, a power divider, in series, One of which is connected to the output of the first frequency converter, the first output is connected to the masking noise synthesizer, and the second to the controlled delay line, the outputs of the controlled delay line and the masking noise synthesizer are connected to the inputs of the adder, the output of which is connected to the second frequency converter selective signal splitter and high-frequency output amplifier, the second output of the masking noise synthesizer is connected to the input of the local oscillator unit, the third output of the synthesizer masking noise is connected to the blanking input of the controlled delay line, the control inputs of the masking noise synthesizer and the controlled delay line are connected to the output of the control device.

Common signs of the claimed device with the prototype is the presence of frequency converters, input and output high-frequency amplifiers, an adder, a unit of local oscillators, a control device, a delay line.

The disadvantage of the prototype is that its technical solution for constructing a frequency storage and reproduction device does not allow high-precision memory storage and reproduction of input broadband, long-pulse radar signals with complex types of intrapulse modulation, with tuning of the carrier frequency and repetition period.

For the optimal construction of active jam stations, the technical task of high-precision storage and reproduction of the input frequency of broadband, long-pulse radar signals with complex types of intrapulse modulation, with tuning of the carrier frequency and repetition period, as well as the possibility of unlimited storage and replication of technical parameters of stored signals, arose.

The solution to this technical problem is achieved by the fact that in the device for storing and reproducing the frequency, containing the input and output frequency converters, a tunable local oscillator unit and a delay line, an output adder, input and output high-frequency amplifiers and power dividers, a control and monitoring unit, high-frequency input amplifier, input power divider, delay line, input frequency converter, connected in series, output adder, frequency converter, power divider The high-frequency amplifier is connected in series, the tunable local oscillator unit is connected with the second inputs of the input and output frequency converters, the first output of the control and monitoring unit is connected to the second input of the delay line, the second output of the control and control unit is connected to the input of the tunable local oscillator unit, in addition included receiver of instant determination of frequency, four-channel frequency-selective splitter of signals, digital cell for storing and reproducing frequencies the first channel, a digital cell for storing and reproducing the frequency of the second channel, a digital cell for storing and reproducing the frequency of the third channel, a digital cell for storing and reproducing the frequency of the fourth channel, a detector, a video amplifier, wherein the second output of the input power divider is connected to the input of the receiver for instantaneous determination of frequency, the output of which is connected to the first input of the control and monitoring unit, the output of the input frequency converter is connected to the input of the four-channel frequency-selective a signal splitter, the first output of which is connected to the first input of the digital memory and frequency reproduction unit of the first channel, the second, third and fourth outputs of the four-channel frequency-selective signal splitter are connected to the first inputs of the second, third and fourth digital memory cells and the frequency reproduction of the second, third and the fourth channel, respectively, the second, third, fourth inputs of the digital memory cells and the frequency reproduction of all four channels are connected to the outputs of the block control and monitoring, respectively, the outputs of four digital memory cells and frequency reproduction are connected to the inputs of the output adder, the first output of the output power divider is connected through a series-connected detector and video amplifier to the second input of the control and control unit, each memory cell and the frequency reproduction of the first, second, third and the fourth channel contain a channel power divider, the first output of which through a series-connected channel detector, channel video an amplifier, a comparator is connected to the first input of the storage device,

the second output of the channel power divider is connected through a series-connected first channel frequency converter and an analog-to-digital converter with a second input of the storage device, the second input of the first channel frequency converter is connected to the output of the channel local oscillator, the input of which is connected to the third output of the control and monitoring unit, the second inputs of analog -digital converter and digital-to-analog converter are connected to the fifth output of the control and monitoring unit, the third input is memorable of the device is connected to the fourth output of the control and monitoring unit, the first input of the digital-to-analog converter is connected to the output of the storage device, the output of the digital-to-analog converter is connected to the first input of the second channel frequency converter, the second input of which is connected to the second output of the channel local oscillator, the output of the second channel the frequency converter is the output of a digital cell for storing and reproducing frequency.

The proposed device is illustrated by the drawing in FIG.

In the drawing, the numbers indicate:

1 - input high-frequency amplifier;

2 - input power divider;

3 - receiver for instant determination of frequency;

4 - control and monitoring unit;

5 - delay line;

6 - input frequency converter;

7 - tunable block of local oscillators;

8 - four-channel frequency-selective signal splitter;

9 - a digital cell for storing and reproducing the frequency of the first channel;

10 - a digital cell for storing and reproducing the frequency of the second channel;

11 - a digital cell for storing and reproducing the frequency of the third channel;

12 - a digital cell for storing and reproducing the frequency of the fourth channel;

13 - output adder;

14 - output frequency converter;

15 - output power divider;

16 - detector;

17 - video amplifier;

18 - output high-frequency amplifier;

19 - channel power divider;

20 - channel detector;

21 - the first channel frequency converter;

22 - channel local oscillator;

23 - channel video amplifier;

24 - a comparator;

25 - analog-to-digital Converter;

26 - storage device;

27 - digital-to-analog converter;

28 - second channel frequency converter.

The claimed device for storing and reproducing the frequency contains a series-connected input amplifier 1 of high frequency, the input of which is the input of the device for storing and reproducing the frequency, input power divider 2, delay line 5, input frequency converter 6, four-channel frequency-selective splitter 8 of the signals, input of receiver 3 instantaneous frequency determination is connected to the second output of the input power divider 2, the first input of the control and monitoring unit 4 is connected to the output of the receiver 3 m frequency determination, the first output of the control and monitoring unit 4 is connected to the second input of the delay line 5, the first output of the tunable local oscillator unit 7 is connected to the second input of the input frequency converter 6, the second output of the control and control unit 4 is connected to the input of the tunable local oscillator unit 7, outputs four-channel frequency-selective splitter of signals are connected to the first inputs of digital cells 9, 10, 11, 12 of storing and reproducing frequencies, respectively, the outputs are the third, fourth, fifth bl control and control 4 are connected to the second, third and fourth inputs of digital cells 9, 10, 11, 12 of storing and reproducing frequencies, respectively, the inputs of the output adder 13 are connected to the outputs of digital cells 9, 10, 11, 12 of storing and reproducing frequencies, respectively, the output of the output adder 13 is connected to the first input of the output frequency converter 14, the second input of which is connected to the second output of the tunable local oscillator unit 7, and the output is connected to the input of the output power divider 15, the second output of which through atelno connected detector 16 and the video amplifier 17 is connected to the second input of the control unit 4 and control, the first output of output power divider 15 is connected to the input of an amplifier 18, a high frequency, the output is the output of the last memory device and the playback frequency.

The digital cell 9 for storing and reproducing the frequency (CCL and HF) of the first channel contains a channel power divider 19, a channel detector 20, the first

channel frequency converter 21, channel local oscillator 22, channel video amplifier 23, comparator 24, analog-to-digital converter 25 (ADC), storage device 26 (memory), digital-to-analog converter 27 (DAC), the second channel frequency converter 28, while the first input of the channel power divider 19 is the input of the NRC and RF 9, the first output of which is connected to the input of the channel detector 20, and the second output is the first input of the first channel frequency converter 21, the second input of which is connected to the output of the local oscillator 22, the output of the channel detector 20 is connected through a series-connected channel video amplifier 23 and the comparator 24 to the first input of the memory 26, the second input of which is connected to the output of the ADC 25, and the third input is connected to the fourth output of the control and monitoring unit 4, the output of the first channel frequency converter 21 connected to the first input of the ADC 25, the second input of the DAC 27 and the fifth output of the control and monitoring unit 4 are connected to the second input of the ADC 25, the output of the memory 26 is connected to the first input of the DAC 27, the output of the digital-to-analog converter 27 is connected to the first the input of the second channel frequency converter, the second input of which is connected to the second output of the channel local oscillator, the output of the second channel frequency converter 28 is the output of a digital frequency storage and reproduction cell.

The algorithm of the claimed device for storing and reproducing frequencies (ultrasound and treble) depends on the selected interference modes. The effectiveness of imitating and masking interference by a pulsed and coherent-pulsed radar with tuning of the carrier frequency and the repetition period, including with broadband signals, largely depends on the accuracy of the reproduction of phase, frequency and time characteristics of the radar signals, as well as the selected method of storing and reproducing input information . A microwave radar signal is received and converted in frequency into a signal of a lower frequency (base) range using a fixed or frequency-tunable unit 7 local oscillators. From the output of the input frequency converter 6, the intermediate frequency (IF) signals with a 2Δf band are fed to the input of a four-channel frequency-selective splitter 8 of signals, from each output of which signals with a 2Δf / 4 band are distributed uniformly in frequency, starting from the lower value of the IF frequency at the output the first channel and ending with the upper value of the frequency of the inverter on the fourth channel, they are supplied to the first inputs of the DLC and HF.

The receiver 3 instant determination of frequency is a multi-channel receiver direct amplification containing low-noise microwave amplifiers, frequency

splitters and bandpass filters, detectors, logarithmic video amplifiers. From the output of the receiver, the measured frequency of the input signal is fed to the first input of the control and monitoring unit 4 in order to use its value for tuning the frequency of the tunable local oscillator unit 7. An adjustable delay line 5 included in the main channel of the receiving path is designed to compensate for delays when remembering the carrier frequency of the input signal, as well as to generate multiple false targets at the output of the interference transmitter at various bearings and distances from the jammer.

The functions of memorizing and reproducing the input signals are assigned to the DSC and HF. The greatest effect when using the DLC and HF compared with the analog devices of the prototype is achieved when processing signals with complex types of in-pulse modulation and long duration. Of great importance is the possibility of unlimited storage of stored signals and the introduction of additional modulation of any kind during their reproduction.

The input IF signal supplied to the input of the power divider 19 is divided into two parts, from the first output the signal is fed to the input of the channel detector 20 and then sequentially fed to the channel video amplifier 23, comparator 24 and to the first input of the memory 26. The video pulse supplied to the input of the comparator 24 with a pulse amplitude exceeding the threshold voltage level of the comparator, the comparator 24 is triggered and a pulse of positive polarity is formed at its output with a duration corresponding to the duration of the input pulse.

From the second output of the channel power divider 19, the input IF signal is fed to the first input of the first channel frequency converter 21, the second input of which is fed from the first output of the local oscillator 22. From the output of the first channel frequency converter 21 there is already a second IF signal, which is fed to the input ADC 25. ADC 25 can be of amplitude or phase type, that is, realizing quantization by the level of the current amplitude or phase of the signal (in our case, quantization by phase of the signal is used).

The operation of the ADC 25 is based on the principle of measuring the values of the phase difference, for example, through π / 2, relative to the signal of the channel local oscillator 22. At the output of the ADC 25, a positional four-bit parallel code of the phase difference of the input signal and the channel local oscillator is generated. The code is a pulse sequence, the desired frequency corresponds to the frequency difference between the base input IF signal and the signal of the local oscillator 22, tunable by the control and monitoring unit 4.

The storage device 26 provides for storing, storing and issuing arrays of data displaying samples of the recorded information of the input signal in accordance with the commands of the control and monitoring unit 4. When issuing the stored data in direct or reverse order, in relation to the order of their receipt, they are fed to the first input of the DAC 27.

The frequency is reproduced by supplying the stored four-bit parallel code sequences of the phase difference to the first input of the second channel frequency converter, the second input of which receives the frequency from the second output of the channel local oscillator 22. At the output of the second channel frequency converter 28, an analog signal of the first base IF is generated. The introduced recording and playback errors depend on the bit depth of the ADC and DAC and the sampling frequency of the signals over time.

From the output of the second channel frequency converter 28, the signal, depending on the base value of the inverter, is fed to one of the inputs of the output adder 13.

Similarly, the NNC and HF and other channels work.

From the output of the output adder 13, the signal is supplied to the first input of the output frequency converter 14, to the second input of which a signal is output from the output of the tunable unit 7 local oscillators. An microwave signal is generated at the output of the output converter 14, corresponding to the input microwave signal according to the parameters, which then goes to the input of the output power divider 15, from the second output of which the signal goes to the input of the detector 16 and then to the input of the video amplifier 17, from the output of the last signal goes to the second input unit 4 control and monitoring to confirm the passage of the reproduced signal. From the first output of the output power divider 15, the signal is fed to the input of the high-frequency output amplifier 18, the output of which is the output of the ultrasonic and RF.

The proposed device for storing and reproducing frequencies is implemented on well-known industrially produced elements and nodes, in particular:

- a multi-channel receiver for instant determination of frequency, containing:

- low-noise microwave amplifiers of type M421135, detectors;

- logarithmic amplitude video amplifiers based on operational amplifiers AD8041, AD640 of Analog Devises company, ADC types AD9057, of the same company [4, p.271-285];

- the Omul module, which performs phase modulation of the modulators and converts digital codes to analog microwave signals, the manufacturer is the domestic company Almaz-Fazotron;

- M41128 modules that perform the functions of fixed and tunable local oscillators, the manufacturer is the domestic company Almaz-Fazotron,

- in multi-channel digital frequency memory systems, matrix switches, multiplexers that convert serial code to parallel and demultiplexers are widely used to convert parallel code to serial, manufacturer ANALOG DEVISES [4, p.264-265],

- devices for calculating the frequency on FPGAs of the FLEX or MAX type by ALTERA [4, p.230-235].

- comparators, 521 series microcircuits, manufacturer of REPP for ALFA, Riga, Latvia [4, p.63 and 13],

- devices on a programmable substrate ЕРМ9320А-7, ЕРМ9400-15 and the MAX7000 series others, ALTERA company [4, pp. 230-232],

- ADC / DAC, microprocessor systems components, linear circuits, ANALOG DEVISES company [4, p.236-256].

The presented drawing and description of the proposed device for storing and reproducing frequencies allow, using the above element base, to manufacture it industrially and use for its intended purpose, which characterizes the proposed utility model as industrially applicable.

Claims (1)

A frequency storage and reproducing device comprising an input and output frequency converters, a tunable local oscillator unit and a delay line, an output adder, input and output high-frequency amplifiers and power dividers, a control and monitoring unit, while an input high-frequency amplifier, an input power divider, a line delays, the input frequency converter is connected in series, the output adder, the frequency converter, power divider, the high-frequency amplifier are connected in series, the traction unit of local oscillators with its outputs is connected to the second inputs of the input and output frequency converters, the first output of the control and monitoring unit is connected to the second input of the delay line, the second output of the control and monitoring unit is connected to the input of the tunable unit of local oscillators, characterized in that the receiver is additionally included in it instant frequency determination, four-channel frequency-selective splitter of signals, a digital cell for storing and reproducing the frequency of the first channel, a digital cell for washing and reproducing the frequency of the second channel, a digital cell for storing and reproducing the frequency of the third channel, a digital cell for storing and reproducing the frequency of the fourth channel, a detector, a video amplifier, while the second output of the input power divider is connected to the input of the receiver for instantaneous determination of the frequency, the output of which is connected to the first input control and monitoring unit, the output of the input frequency converter is connected to the input of a four-channel frequency-selective signal splitter, the first output for which it is connected to the first input of the digital memory cell and frequency reproduction of the first channel, the second, third and fourth outputs of the four-channel frequency-selective signal splitter are connected to the first inputs of the second, third and fourth digital memory cells and frequency reproduction of the second, third and fourth channels, respectively the second, third, fourth inputs of digital memory cells and frequency reproduction of all four channels are connected to the third, fourth and fifth outputs of the control unit control and monitoring, respectively, the outputs of four digital memory cells and frequency reproduction are connected to the inputs of the output adder, the second output of the output power divider is connected through a series-connected detector and video amplifier to the second input of the control and control unit, each digital cell for storing and reproducing the frequencies of the first, second, the third and fourth channels contains a channel power divider, the first output of which through a series-connected channel detector, channel vi a de-amplifier, a comparator is connected to the first input of the storage device, the second output of the channel power divider is connected through a series-connected first channel frequency converter and an analog-to-digital converter with the second input of the storage device, the second input of the first channel frequency converter is connected to the first output of the channel local oscillator, the input of which is connected with the third output of the control and monitoring unit, the second inputs of the analog-to-digital converter and digital-to-analog converter The device is connected to the fifth output of the control and monitoring unit, the third input of the storage device is connected to the fourth output of the control and control unit, the first input of the digital-to-analog converter is connected to the output of the storage device, the output of the digital-to-analog converter is connected to the first input of the second channel frequency converter, the second input of which is connected to the second output of the channel local oscillator, the output of the second channel frequency converter is the output of a digital storage and playback cell denia frequency.