RU56090U1 - INTERFERENCE TRANSMITTER - Google Patents

Abstract

The utility model relates to radio engineering and can be used in pulse and masking jamming stations to suppress radar (RL) homing heads (GSP) of anti-ship missiles (RCC), radar stations (radar) with fast tuning of the carrier frequency from pulse to pulse at short and long distances located between the jammer and the radiation source. The technical result from the use of the proposed utility model consists in concentrating the entire radiated power of the interference transmitter in a narrow frequency band of one channel and the possibility of suppressing the radiation source not only along the main but also on the side lobes of the BOTTOM, as well as closing the distance interval between the interference transmitter and the suppressed radar or radar, due to the formation and radiation of anticipatory aiming at the frequency masking interference. The interference transmitter contains a receiving antenna, a broadband noise source, a pulse detector, a modulator, a transmitting antenna, a power amplifier, the first input of which is connected to the output of the output adder, and the second to the output of the modulator, the output of the power amplifier is connected to the input of the transmitting antenna, n-channel formation sights on the frequency of masking interference, each of which consists of a channel bandpass filter, a channel detector and a channel gating device, the output of which is connected to the input corresponding to the channel number output adder, adjustable attenuator, microwave amplifier, power divider, input adder, multi-channel frequency-selective splitter, meter of input signal repetition period, anticipatory pulse shaper, and a directional coupler and coincidence circuit are included in each channel for generating interference-frequency masking interference, the output of the receiving antenna, through a series-adjustable attenuator connected, a microwave amplifier, a power divider, is connected to the first input of the input adder, to w the input of which is connected to the output of a broadband noise source, and to its output is the input of a multi-channel frequency-selective splitter, each output of a multi-channel frequency-selective splitter from the first to the n-th channel through a series-connected channel filter, a directional channel coupler, a channel gating device respectively, to the input, from the first to the n-th output adder, the second output of the power divider through series-connected

a pulse detector and a measuring period of the input signal repetition period, connected to the input of the forward pulse shaper, the output of which is connected to the modulator input, the second input of the adjustable attenuator, and the second inputs of the matching circuits of each channel, the first inputs of which are connected through the channel detectors to the second outputs of the directional channel couplers , and the outputs to the second inputs of the channel gating devices. Fig. 1.

Description

The utility model relates to radio engineering and can be used in pulse and masking jamming stations to suppress radar (RL) homing heads (GOS) of anti-ship missiles (RCC), radar stations (radars) with fast tuning of the carrier frequency from pulse to pulse at short and long distances located between the jammer and the radiation source.

In the book of A.I. Paly [Radio electronic warfare, M. Military Publishing House, 1989, p. 37, Fig. 2.12a], a block diagram of a transmitter for masking radar interference is taken as an analogue. It consists of a broadband noise source connected through a power divider to the inputs of a number of (n) power amplifiers, the outputs of which are connected through an adder to the input of the transmitting antenna. Overlapping the entire frequency range by noise interference can be carried out not continuously in time, but discretely by pulses. This type of interference is called noise covering noise — the noise pulse covers the radar signal reflected from the target. This is a very effective method of radar suppression of both radar detection and radar tracking, since the interference signal always enters the radar range gate and causes transient processes in the receiver circuits. The disadvantage of this interference is that it can be attenuated in the radar receiver using an amplitude limiter. For electronic suppression of the radar, along with transmitters of obstructive interference, transmitters of impact noise interference are used. These transmitters can also use direct noise interference techniques.

However, the use of special operating modes by modern radars makes it possible to increase the level of noise immunity of their receivers and makes it difficult for radio-electronic suppression (REP) systems to create false targets on radar indicators. Radar equipment with fast tuning of the carrier frequency from pulse to pulse, which impedes the REP equipment, due to the lack of appropriate devices in their composition, the formation of response interference to each input sounding pulse, should be referred to such modes of functioning of the radar equipment.

The book [Yu.M. Perunov, K.I. Fomichev, L.M. Yudin, Radio-electronic suppression of information channels of weapon control systems, M., "Radio Engineering", 2003, p. 85, Fig. 3.13] shows the structural diagram of the transmitter sighting noise

interference with multi-channel frequency-selective systems, taken as an analog. The block diagram of the transmitter consists of a receiving antenna, a multi-channel filter receiver, a noise source, a microwave amplifier, and a transmitting antenna. This transmitter during the duration of the input radar pulse generates and radiates in the direction of the suppressed radar frequency-targeted noise interference. The jammer operates as follows. When a radar probe signal arrives at the receiving antenna from its output, the signal is fed to the input of a multi-channel splitter. The channels of the splitter are tuned to certain sections of the frequency range. Each frequency channel is a band-pass filter, in series with which a detector and a channel switch are connected. Channel switches are controlled by the received signal from the radar. Signals from a broadband noise source through a multi-channel splitter are fed to a band-pass filter and then to the second input of the switch. If the frequency of the input signal received from the radar and the frequency of the noise source coincide, the switch opens for a time equal to the duration of the input signal and passes noise interference to the input of the adder. From the output of the adder, the noise source signals are fed to the input of the amplifier on the TWT and then from its output to the transmitter antenna, aimed at the suppressed radar.

The advantage of the transmitter of targeted masking interference is its ability to suppress radar receivers at large and small distances.

Despite the fact that the sighting interference transmitter is capable of tuning to the carrier frequency of the radar in a time not exceeding the radar pulse duration, it cannot mask the range interval with noise due to the delay between the reflected probe pulse and the radiated noise. In addition, due to the lack of amplification devices in the receiver, it has low sensitivity.

As a prototype, as the closest to the claimed circuit design, the spurious targets generator using a set of narrow-band noise described in the book [Yu.M. Perunov, K.I. Fomichev, L.M. Yudin, Radio-electronic suppression of information channels is selected weapon control systems, M., "Radio Engineering", 2003, p. 357, Fig. 16.1]. The block diagram of a generator designed to create spurious radar targets with fast frequency tuning described in this book contains a receiving antenna, the output of which is connected to a pulse detector and the first input of the channel splitter, to the second input of which a broadband noise source is connected in the entire frequency range of frequency tuning suppressed radar. The outputs of the channel separator through bandpass filters, detectors and gating devices are connected in series to the inputs

the adder, the output of the latter is connected to the first input of the pulse modulator, the second input of which is connected to the output of the generator of false targets at the video frequency, the input of the latter is connected to the output of the pulse detector, the output of the pulse modulator is connected to the input of the power amplifier, the output of which is connected to the input of the transmitting antenna.

This generator for creating false radar targets with fast frequency tuning generates false targets with a noise spectrum using a set of band-pass filters to determine the frequency of the suppressed radar and generate a noise signal at the corresponding frequency. In this interference generator, the signal of the suppressed radar is received by the receiving antenna and transmitted to the first input of the channel splitter, to the second input of which a broadband noise source is connected in the entire frequency range of the frequency tuning. From the output of the channel splitter, the input signal through a bandpass filter tuned to its frequency, is fed to the first input of the gating device and detector. The detected input signal is supplied to the second input of the gating device, opens it, as a result of which a noise signal located within the passband of the filter is fed to the input of the adder and then to the first input of the pulse modulator. A pulse detector located at the output of the receiving antenna, emits pulses of the suppressed radar and synchronizes the generator of false targets. At the output of this generator, video pulses are formed. Each video pulse is used to open the power amplifier and modulate the noise received from the output of the adder. At each moment of the formation of a false target, all filters whose outputs are in the open state give out their noise with a spectral width equal to the passband of the filter. Thus, at the output of the power amplifier, many false targets, similar to true ones, are simultaneously generated at all frequencies of the received signals.

The disadvantages of the considered generator, taken as a prototype, include:

- the gating devices in each switched-on channels remain open for an indefinite period of time and the output power in this case is divided proportionally between the channels, the more open channels, the less the radiated interference power and therefore, the suppression efficiency of the radiation source decreases accordingly, this is especially typical when suppressing RL GSP RCC at short distances, when the level of the reflected sounding radio signals with approaching the jammer increases sharply;

- the relatively low sensitivity of the input path of the receiving device, due to the lack of amplifiers in its structure, does not allow

suppression of radar or radar along the side lobes of the antenna pattern (BOTTOM);

- the range interval between the radar or radar and the jammer cannot be masked by the interference, due to the delay between the reflected probe radio signal and the radiated interference.

The technical result from the use of the proposed utility model consists in concentrating the entire radiated power of the interference transmitter in a narrow frequency band of one channel and the possibility of suppressing the radiation source not only along the main but also on the side lobes of the BOTTOM, as well as closing the distance interval between the interference transmitter and the suppressed radar or radar, due to the formation and radiation of anticipatory aiming at the frequency masking interference.

The solution of this technical problem is achieved by the fact that the generator of false targets using a set of narrow-band bandpass filters containing a receiving antenna, a broadband noise source, a pulse detector, a modulator, a transmitting antenna, a power amplifier, the first input of which is connected to the output of the output adder, and the second with the output of the modulator, the output of the power amplifier is connected to the input of the transmitting antenna, n-channels for generating interference-frequency masking interference, each of which consists of a band-pass filter and a channel, a channel detector, and a channel gating device, the output of which is connected to the input of the output adder input, an adjustable attenuator, a microwave amplifier, a power divider, an input adder, a multi-channel frequency-selective splitter, a meter of input signal repetition periods, and a forward pulse shaper are introduced and a directional coupler and a matching circuit are included in each channel for generating interference-frequency masking interference, with the output of the receiving antenna through the connections sequentially adjustable attenuator, microwave amplifier, power divider, connected to the first input of the input adder, the second input of which is connected to the output of the broadband noise source, and to its output is the input of a multi-channel frequency-selective splitter, each output of a multi-channel frequency-selective splitter from the first to n-th channel channel gating device, channel gating device, channel gating device, respectively, connected to the input, from the first to the n-th through a series-connected channel band-pass filter the output of the adder, the second output of the power divider coupled in series through a pulse detector and measuring the repetition period of the input signals coupled to an input pulse shaper preemptive whose output is connected to the input of the modulator, a second input controlled

attenuator, and the second inputs of the coincidence circuits of each channel, the first inputs of which through the channel detectors are connected to the second outputs of the directional channel couplers, and the outputs to the second inputs of the channel gating devices.

The input signal repetition period meter contains a video amplifier, driver, oscillator with quartz frequency stabilization, a selector, a pulse counter, a microprocessor, and the video amplifier input is an input signal period meter, the output of the video amplifier is connected to the input of the driver, the output of which is connected to the first input of the selector , the output of the oscillator with quartz frequency stabilization is connected in series with the second input of the selector, pulse counter, microprocessor, microprocessor output The processor is the output of the period meter of the input signals. The anticipatory pulse generator consists of a logical unit for comparing, processing and analysis and a storage device, the first input of the logical unit for comparing processing and analysis is the input of the anticipatory pulse generator, the second input of which is connected to the output of the storage device, the output of the logical unit for comparing, processing and analyzing is the input for the generator anticipatory pulses.

The claimed interference transmitter meets the criteria of the utility model “novelty” and “industrial applicability”, since the source of information is unknown, which would describe the set of features of the formula of the utility model, and the object of the utility model can be repeated many times using a well-known elemental Russian and foreign base.

A useful model is illustrated by the drawing in Fig., Which shows a block diagram of an interference transmitter. In the drawing, the numbers indicate:

1 - receiving antenna;

2 - adjustable attenuator;

3 - microwave amplifier;

4 - power divider;

5 - source of broadband noise;

6 - input adder;

7 - multi-channel frequency-selective splitter;

8 - pulse detector;

9 - meter periods of the sequence of input signals;

10 - shaper proactive pulses;

11-1 - band-pass filter of the first channel;

11-n - bandpass filter of the n-th channel;

12-1 - directional coupler of the first channel;

12-n - directional coupler of the n-th channel;

13-1 - detector of the first channel;

13-n - detector of the n-th channel;

14-1 a first channel match circuit;

14-n is the coincidence circuit of the n-th channel;

15-1 - a gating device of the first channel;

15-n - gating device of the n-th channel;

16 - output adder;

17 - modulator;

18 - power amplifier;

19 - transmitting antenna;

20 - video amplifier;

21 - shaper;

22 - oscillator with quartz frequency stabilization;

23 - selector;

24 - pulse counter;

25 - microprocessor;

26 is a logical unit for comparison, processing and analysis;

27 is a storage device.

The inventive interference transmitter includes a receiving antenna 1, the output of which is connected to the first input of the adjustable attenuator 2, the second input of which is connected to the output of the anticipatory pulse shaper 10, the output of the adjustable attenuator is connected to the input of the microwave amplifier 3, the output of which is connected to the input of the power divider 4, the first output the latter is connected to the first input of the input adder 6, and the second output to the input of the pulse detector, the output of the source 5 of broadband noise is connected to the second input of the input adder, the input is multiple channel frequency-selective splitter 7 is connected to the output of the input adder 6, and the outputs from the first to the n-th are connected to the inputs of the bandpass filters 11-1 of the first and 11-n of the n-th channels, the outputs of which are connected to the inputs of the directional couplers 12-1 and 12-n, respectively, the first outputs of the directional couplers 12-1 and 12-n are connected to the first inputs of the gate devices 15-1 and 15-n, respectively, the outputs of the latter are connected to the first and n-th inputs of the output adder 16, the second outputs of the directional couplers 12 -1 and 12-n are connected to

the inputs of the detectors 13-1 and 13-n, respectively, the outputs of which are connected to the first inputs of the matching circuits 14-1 and 14-n, the outputs of which are connected to the second inputs of the gate devices 15-1 and 15-n, the second inputs of the matching circuits 14-1 and 14-n are connected to the output of the anticipatory pulse shaper 10, the input of which is connected to the output of the meter 9 of the input signal repetition periods, the input of which is connected to the output of the pulse detector 8, the first input of the power amplifier 18 is connected to the output of the output adder 16, and the second input to the output 17 modulator input connected to the output of generator 10 anticipatory pulses transmit antenna input 19 is connected to the output of the power amplifier 18. The input of the video amplifier 20 is the input of the meter 9 periods of the input signals and is connected to the output of the pulse detector 8, the input of the driver 21 is connected to the output of the video amplifier 20, and the output is connected to the first input of the selector 23, the second input of which is connected to the output of the generator 22 with quartz frequency stabilization, the output of the selector 23 is connected to the input of the counter 24 pulses, the output of the latter is connected to the input of the microprocessor 25, the output of which is the output of the meter 9 periods of the sequence of input signals. The first input of the logic unit 26 for comparison, processing and analysis is the input of the driver of pre-emptive pulses 10, the output of the logic unit 26 for comparison, processing and analysis is the output of the driver of the anticipatory pulses, the output of the storage device 27 is connected to the second input of the logic unit 26 for comparison, processing and analysis.

The inventive interference transmitter designed to suppress the radar of the GOS RPC or radar with the tuning of the carrier frequency from pulse to pulse works as follows.

With the arrival of the probing radio signal from the suppressed radar of the GSN RCC or radar with the tuning of the carrier frequency from pulse to pulse to the receiving antenna 1 of the interference transmitter, the signal from the output of the receiving antenna 1 through a series-connected adjustable attenuator 2, low-noise semiconductor amplifier 3, microwave divider 4, is fed to the first input of the input adder 6, the second input of which is followed by signals from a source 5 of broadband noise, from the output of the input adder 6, the signals are fed to the input of a multi-channel frequency-selector splitter 7. from the second output of the power splitter 4, the input signal is simultaneously fed to the input of the pulse detector 8, the detected signal from its output is fed to the input of the video amplifier 20, which is part of the meter 9 periods of the input signals and is its input. In the video amplifier 20, a voltage divider, a broadband amplifier,

which provide coordination of the input resistance and the necessary gain, which ensures the normal operation of the next node - the shaper 21, which generates pulses of a certain shape, duration, amplitude and controls the operation of the selector 23. To obtain pulses of the desired shape and duration in the shaper 21, a Schmidt trigger, amplifiers, limiters and other elements. The selector 23 is designed to transmit the signals of the oscillator 22 with quartz frequency stabilization to the counter 24 pulses, when a pulse is supplied to its first input from the shaper 21. The oscillator 22 with quartz frequency stabilization has a generation frequency of 1 MHz and therefore the duration of the calibrated pulse is 1 μs. The counter 24 pulses counts the number of pulses from the oscillator 22 with quartz frequency stabilization for a time equal to the duration of the input signal generated by the driver 21, from the output of the counter 24 pulses, the signals are sent to the input of the microprocessor 25, which calculates the period T of the sequence of the input sounding signals according to the formula :

,

where: N is the number of pulses;

f is the frequency of the generator, in Hz.

T - the period following, s.

From the output of the microprocessor 25, the calculated values of the repetition periods of the input signals in the form of codes are sent to the shaper 10 of anticipatory pulses to the input of the logic unit 26 for comparison, processing and analysis, where the comparison, analysis and identification of radio electronic systems (RES) of radiation sources by repetition periods recorded to the storage device 27. Based on the results of the comparison, the type of carrier (ship, plane, rocket) of the radiation source is determined, the analysis is performed, the frequency tuning Radar sensor or radar from pulse to pulse, the frequency pattern is detected from the time adjustment.

An accurate prediction of the radiation time is possible if the pulse repetition rate of the radar or radar is fixed with a known range of its tuning. If the moment of transmission of the radar or radar radiated pulse cannot be estimated, then the working band of the interference transmitter should be set wider than the frequency band of the radar or radar for the time corresponding to the interval of the pulse from the radar or radar to the jamming station. The minimum noise interference width is usually 2-3 times wider than the passband of the suppressed receiver. Carrier Change Prediction Algorithm

The frequency of radar or radar radiation is greatly simplified if the magnitude of the frequency jumps between successive radar pulses is small compared to the full tuning range. Thus, as a result of analysis and processing of the input sequence of radar or radar probe pulses in the logic unit 26 for comparison, processing and analysis, a pre-emptive pulse is generated with a longer radar pulse duration for the lead time, which is fed to the input of modulator 17 to the second input of the adjustable attenuator 2 and match patterns 14-1 or 14-n. The radiation of anticipatory interference in time should coincide with the arrival of the next probing pulse of the radar or radar, thereby eliminating the delay between the reflected signal and the interference signal.

When exposed to a pre-emptive pulse, the sensitivity of the receiving device at the input of an adjustable attenuator decreases to 20-30 dB, which allows you to observe a change in the frequency of the radar or radar transmitter during exposure to radiated interference.

A pre-emptive pulse fed to the input of the modulator 17 generates a modulating pulse at its output, opening the power amplifier 18 and used to modulate the output noise signal taken from the output of the output adder 16. The width of the noise signal spectrum is equal to the filter passband.

A pre-emptive pulse arriving at the second input of the matching circuit 14-1 or 14-n triggers it and a signal appears at the output that opens the gate device 15-1 or 15-n, thereby passing noise from the source of broadband noise to the input of the output adder 16.

The inclusion of a microwave amplifier 3 in the receiving path can increase the sensitivity of the receiving device, and generate interference cover, mainly acting through the side lobes of the bottom of the radar or radar is not tunable in frequency. From the output of the multi-channel frequency-selective splitter, the output signal and signals from the source 5 of broadband noise are fed to the bandpass filters 11-1 - 11-n. Bandpass filters and a source of 5 broadband noise are pre-tuned to the frequencies of the suppressed radar or radar. The entire frequency range of the receiving device is divided into a number of narrower contiguous filter bands. To create a high spectral density of noise interference, the bandwidth of each filter must exceed the frequency band of the receiver of the suppressed radar or radar by the value of the frequency jump of the frequency from pulse to pulse. When an input signal arrives at any of the channels whose carrier frequency lies within

the passband of this filter, the signal from the output of the band-pass filter, for example, 11-1 of the first channel is fed to the input of the directional coupler 12-1 of the first channel, from the first output of which the signal is fed to the first input of the gate device 15-1 of the first channel, the output of which is connected with the first input of the output adder 16, from the second output of the directional coupler 12-1 of the first channel, the signal is input to the detector 13-1 of the first channel, the output of which is connected to the first input of the matching circuit 14-1 of the first channel. The gating device 15-1 of the first channel is opened for a time equal to the duration of the pre-emptive pulse, which exceeds the duration of the input signal (due to the early start of the formation of the pre-emptive pulse and a later end).

The maximum power of the interference transmitter is achieved when the power amplifier 18 is operating at the same frequency. If not one, but several radars or radars is operating, with the carrier frequency being tuned from pulse to pulse, each at its own carrier frequency, then two or more frequency channels can be opened simultaneously. If no signals are received at the input of the receiving antenna 1, pre-emptive signals are not generated, the gate devices are in a closed state, oscillation is not generated in the power amplifier and the interference signal is not emitted. Like the operation of the first channel described above, other channels work as well.

The main advantage of the proposed interference transmitter is its ability to concentrate all the power in a narrow frequency band of one frequency channel, and therefore such a transmitter is capable of suppressing radar receivers of GOS RCC and radar with fast tuning of the carrier frequency from pulse to pulse at small and large distances between RCC and interference transmitter, as well as suppressing radio electronic equipment, without tuning the frequency along the side lobes of the antenna patterns.

Thus, the proposed interference transmitter generates noise pulses that overlap all the operating frequencies of the suppressed radar of the GOS RCC or radar station with fast tuning of the operating frequency from pulse to pulse without completely overlapping its frequency range, which is more energy efficient compared to other types of interference transmitters. Due to the discreteness of overlapping the operating frequency range, the interference power density increases by 20-100 times, in accordance with the well-known ratio - the power density decreases inversely with the bandwidth of the interference transmitter, the narrower the band - the greater the radiated power.

Calculating the repetition period of the input sounding signals, the anticipatory pulse shaper 10 generates an interfering signal at the transmitter output in the form of a covering pulse for each input signal. So, for example, with an average repetition period Tcl equal to Tsl = 200 μs and a wobble of ± (10 ... 12)%, the duration τ _{and the} covering impulse of the interference will be τ _and = (40 ... 50) μs, respectively. When two to three radars are counteracted simultaneously, experimental studies have shown that in 80-90% of cases the interference signals do not coincide in time, thereby suppressing each radar with the full power of the interference transmitter.

The proposed interference transmitter is freely implemented on a modern element base manufactured by foreign and domestic companies, in particular, the following are widely used in the development:

- mirror, horn and lens aperture antennas, on decimeter centimeter, millimeter waves [Zelkin EG, Petrova R.A. Lens antennas. M., Soviet Radio, 1974];

- low-noise microwave amplifiers M41149-2, M41155AZ, M42174-2, M411102, M421135-2 and others;

- microwave modules on TWT, code "Skif", "Sarmat", etc., manufacturer of the Scientific and Production Center "Electronic Systems", NPP "Almaz" and others;

- power dividers model 37-26, manufactured by NP "Phase";

- processors ADSP21060, ADS218X company "Analog Devise" USA;

- FPGA based on once and repeatedly programmable memory (EPROM), the company "ALTERA" A128A, A1240, EPF10K30, ADSP21060, ADS218X and others;

- ADC: AD6765, AD9240, AD9243 of the company "Analog Devise";

- DAC: AD7945, TLC320, AC02 firm "Texas Instrument";

- catalog (electronic components sector "Russia-99", DODEKA, 1999);

- catalog (nomenclature of high-tech IET recommended for development in Russia and dual-use in REA. M., Association “UNIET Fund, 2001”).

Claims (3)

1. An interference transmitter comprising a receiving antenna, a broadband noise source, a pulse detector, a modulator, a transmitting antenna, a power amplifier, the first input of which is connected to the output of the output adder, and the second to the output of the modulator, the output of the power amplifier is connected to the input of the transmitting antenna, n -channels of formation of masking interference that are aimed at the frequency, each of which consists of a channel bandpass filter, a channel detector and a channel gating device, the output of which is connected to the corresponding channel number in the course of the output adder, characterized in that it includes an adjustable attenuator, microwave amplifier, power divider, input adder, multi-channel frequency-selective splitter, a meter of the periods of the input signals, a shaper of anticipatory pulses, and is included in each channel for generating interference-frequency masking interference directional coupler and matching circuit, while the output of the receiving antenna through connected in series adjustable attenuator, microwave amplifier, power divider, is connected to the first input of the input adder, the second input of which is connected to the output of the broadband noise source, and to its output is the input of the multi-channel frequency-selective splitter, each output of the multi-channel frequency-selective splitter from the first to the nth, through a series-connected channel bandpass filter, a directional coupler channel gating device of the channel is connected respectively to the input from the first to the n-th output adder, the second output of the power divider through series-connected pulse the second detector and meter of the periods of the input signals, connected to the input of the forward pulse shaper, the output of which is connected to the input of the modulator, the second input of the adjustable attenuator and the second inputs of the matching circuits of each channel, the first inputs of which are connected through the channel detectors to the second outputs of the directional channel couplers, and the outputs to the second inputs of the channel gating devices. 2. The interference transmitter according to claim 1, characterized in that the input signal repetition period meter comprises a video amplifier, driver, oscillator with quartz frequency stabilization, a selector, a pulse counter, a microprocessor, and the video amplifier input is an input signal period meter, an output of a video amplifier connected to the input of the shaper, the output of which is connected to the first input of the selector, the output of the generator with quartz frequency stabilization is connected to the second input of the selector, the output of which through snip pulses connected to the input of the microprocessor, the microprocessor output is the output meter repetition periods of the input signals. 3. The interference transmitter according to claim 1 or 2, characterized in that the anticipatory pulse generator comprises a logic unit for comparison, processing and analysis and a storage device, the first input of the logical unit for comparison, processing and analysis is the input of the anticipatory pulse generator, the second input of which is connected to the output of the storage device, the output of the logical unit for comparison, processing and analysis is the output of the forward pulse shaper.