RU2673251C1 - Shipbuilding station of pulse and masking interference - Google Patents

Abstract

FIELD: radio equipment and communication.SUBSTANCE: invention relates to radio engineering, in particular to electronic suppression means, and can be used for radio-technical protection of a ship by creating sighting in the frequency and direction of interference to aircraft and shipborne radar stations of the enemy and radar homing missiles. Station contains measuring indicators bearing port and starboard, a device for storing and reproducing frequency, output microwave amplifier of the port side, the output microwave amplifier of starboard and the control device, in a certain way executed and connected to each other.EFFECT: providing a higher output power and expanding the functionality of creating impulse noise, in particular the possibility of creating both a single, and groups of active false targets simultaneously with masking interference, as well as the possibility of creating interference with chaotic polarization.1 cl, 1 dwg

Description

The invention relates to radio engineering, in particular to means of electronic suppression, and can be used for radio-technical protection of the ship by creating aimed at the frequency and direction of interference of enemy aircraft and ship radar stations and homing radar anti-ship missiles.

In the book [S.A. Vakin, L.N. Shustov Basics of electronic warfare. Textbook, part I. - VVIA them. Prof. NOT. Zhukovsky. - 1998] a noise interference station is described comprising a receiving and transmitting antenna, a reconnaissance receiver, a frequency storage system, a frequency tuning unit of an interference transmitter, a power amplifier and a noise generator.

The listed elements of this interference station are essential features of the claimed interference station.

The reason preventing the achievement in this analogue of the technical result provided by the invention is the relatively low speed of the station.

Also known is protected by RF patent No. 2103705, class. G01S 7/38, 1998 automatic response interference station. It contains a receiving antenna, a microwave amplifier, a device for generating response noise interference and a control device. All of the listed elements of this jamming station are included in the inventive jamming station.

The reason that impedes the achievement in this analogue of the technical result provided by the invention is the lack of the possibility of the simultaneous effect of interference from both sides of the ship on the suppressed means.

Closest to the technical nature of the claimed (prototype) is a ship station of pulsed and masking interference, protected by the certificate of the Russian Federation No. 29818, cl. Н04К 3/00, G01S 7/38, 2003 for utility model. The station contains measuring instruments for the bearing of the left and right sides, a device for storing and reproducing frequencies, output microwave amplifiers of the left and right side and a control device.

The bearing meter of each side contains N pairs of receiving antennas, two switches, two identical high-frequency amplifiers, two power dividers, matching load and an interferometer based on a matrix adder.

The frequency storage and reproducing device comprises an input adder, an input high-frequency amplifier, an input frequency-selective splitter, a first frequency converter, a power divider, a controlled delay line, a masking noise synthesizer, a local oscillator unit, an adder, a second frequency converter, an output frequency-selective splitter, high frequency output amplifier and output power divider.

The microwave output amplifiers of each side contain a power divider, two high-frequency amplifiers, two valves, and a transmitting antenna.

All elements of the prototype station, with the exception of the power divider, the controlled delay line and the adder, which are part of the frequency storage and reproduction device, as well as the amplitude-frequency response corrector and frequency diplexer, which are part of the left or right side output microwave amplifiers, are included and the composition of the claimed jamming station.

The reason that impedes the achievement in the prototype station of the technical result provided by the invention is the rather limited functionality of the prototype station. The fact is that in terms of impulse noise, in essence, there is the possibility of creating only one type of interference - leading in range. At the same time, this type of interference has been studied quite well by now, and the methods of protection against it (limiting the speed of removal, guard gates, etc.), which sharply reduce the effectiveness of the effect of such interference, are widely used in existing promising electronic suppression systems, which makes this hindrance itself is ineffective. In addition, in the prototype station, either only a masking or only a distracting interference can be created.

Another reason for the relatively low efficiency of the emitted interference is the fact that the emitted interference is created only on one polarization of the emitted signal, from which it is quite possible to tune out.

The technical problem to which the invention is directed is to expand the functionality of creating pulsed interference, in particular the possibility of creating both a single and a group of active false targets simultaneously with masking interference, as well as the possibility of creating interference with chaotic polarization.

To achieve the specified technical result, a prototype protected by a certificate of the Russian Federation for utility model No. 29818, class. H04K 3/00, G01S 7/38, 2003, comprising left and right side bearing meters, a memory device and a frequency reproduction, an output left-side microwave amplifier, an output right-side microwave amplifier and a control device in which a bearing meter of each of the sides contains N pairs of identical receiving antennas and two microwave switches, one of the antennas of each pair is connected to the corresponding input of the first switch, the other to the input of the second switch, the outputs of the switches through identical high-frequency amplifiers and power dividers connected to the inputs of the interferometer based on the matrix adder, the control inputs of the microwave switches are connected to the first output of the control device, and the outputs of the interferometers are connected respectively to the first and second inputs of the control device, the memory device and the frequency reproduction contains a series-connected input adder, the first and second inputs of which connected to the outputs of the power dividers of the measuring instruments for the bearing of the left and right side, and the input amplifier of a high frequency, is connected in series the input frequency-selective splitter and the first frequency converter, the sequentially included masking noise synthesizer and the local oscillator unit, the second frequency converter in series, the output frequency-selective splitter, the high-frequency output amplifier and the output power divider, the outputs of the local oscillator unit are connected to the second inputs of the first and second frequency converters, and the first and second outputs of the output power divider are respectively the first and second outputs of the device To memorize and reproduce the frequency, the output microwave amplifier of each side contains a power divider, two high-frequency amplifiers, the inputs of which are connected to the outputs of the power divider, two valves, the inputs of which are connected to the outputs of the corresponding high-frequency amplifiers, and a transmitting antenna, the input of which is connected to the output of one of the gates, a power divider with three outputs is introduced into the device for reproducing and storing the frequency, the input of which is connected to the output of the input high-frequency amplifier, the first output - with the input of the input frequency-selective splitter, and the second and third outputs are respectively the third and fourth outputs of the memory device and the frequency reproduction, while the input of the masking noise synthesizer is connected to the output of the first frequency converter, and its second output to the second input of the second frequency converter , in addition to the output microwave amplifier of each side, sequentially connected pulse modulator-driver and a power amplifier, as well as the uncontrolled delay line, the microwave adder and the second transmitting antenna with polarization of the emitted signal, orthogonal to the signal of the transmitting antenna, the input of the delay line is connected to the output of the second valve, the output of the power amplifier is connected to the second input of the microwave adder, the signal input of the pulse-noise modulator-shaper is connected to the third or fourth depending on the board number the output of the frequency storage and reproduction device, and its control input to the second or third output of the device is controlled I am depending on the room side.

There are no sources of information that would describe the newly introduced elements and communications in conjunction with the remaining elements and communications of the jamming station. Therefore, the proposed jamming station should be considered new and inventive.

The invention is illustrated in the drawing, which shows a structural diagram of the proposed ship station interference.

The station contains measuring instruments for the bearing of the left side 1.1 and starboard 1.2, a device 2 for storing and reproducing frequency, an output microwave amplifier for the left side 3.1, an output microwave amplifier for the starboard 3.2 and a control device. The control device is not shown in the drawing, only its inputs and outputs are shown.

Each of the meters 1.1 and 1.2 contains N pairs of identical (in this particular case N = 4) receiving antennas 6.1, 7.1, 8.1, 9.1 (6.2, 7.2, 8.2, 9.2) and two microwave switches 10.1 and 10.2. One of the antennas (6.1, 7.1, 8.1, 9.1) of each pair is connected to the corresponding input of the first switch, 10.1, the other (6.2, 7.2, 8.2, 9.2) to the input of the second switch 10.2. The outputs of the switches 10.1 and 10.2 through identical high-frequency amplifiers 11.1, 11.2 and power dividers 12.1, 12.2 are connected to the inputs of the interferometers 13 based on matrix adders. The second output of the power divider 12.1 is loaded on the matching load 14, and the second output of the power divider 12.2 is connected to the input of the frequency storage and reproducing device 2. The control inputs of the switches 10.1 and 10.2 are connected to the first output 15 of the control device, and the outputs of the interferometers 13 of the measuring instruments for the port and starboard bearings are respectively connected to the first 16 and second 17 inputs of the control device.

The frequency storage and reproducing device 2 comprises a series-connected input microwave adder 18, a high-frequency amplifier 19, a power divider 20 into three outputs, an input frequency-selective splitter 21 and a first frequency converter 22, series-connected masking noise synthesizer 23 and a local oscillator unit 24, as well as series-connected second frequency converter 25, output frequency-selective splitter 26, high-frequency output amplifier 27 and power output divider 28. The input of the synthesizer 23 is connected to the output of the converter 22, and the second output is connected to the first input of the converter 25. The first and second outputs of block 24 are connected to the second inputs of the converters 22 and 25, respectively. The first and second outputs of the power divider 28 are the first and second outputs of the device 2, respectively, and the second and third outputs of the power divider 20 are the third and fourth outputs of the device 2, respectively.

Each of the output microwave amplifiers 3.1 and 3.2 contains transmitting antennas 4 and 5, a modulator-driver of impulse noise 29, an amplifier 30 of the output power of the microwave signal, amplifiers 32.1 and 32.2 of the output microwave signal, valves 33.1 and 33.2 of the output microwave signal, uncontrolled delay line 34 and a microwave adder 35. A power divider 31, an amplifier 32.1, a gate 33.1, and a transmitting antenna 4 are connected in series and represent a channel for amplifying, generating, and emitting masking interference. The same channel is represented by serially connected power divider 31, amplifier 32.2, gate 33.2, delay line 34, adder 35 and transmitting antenna 5. Serially connected modulator-shaper 29 and power amplifier 30, adder 35 and transmitting antenna 5 represent a channel of formation, amplification and radiation of impulse noise. The input of the power divider 31 is connected to the first or second, depending on the board number, the output of the device 2. The signal input of the modulator-shaper 29 is connected to the third or fourth, depending on the board number, the output of the device 2, and the control input to the second 36 or third 37 outputs of the device control depending on the board number.

The work of the proposed jamming station is as follows.

Bearing meters 1.1 and 1.2 of the port and starboard, respectively, do not differ from the corresponding bearings of the prototype station. Their functioning is the alternate formation with the help of an appropriate pair of antennas and switches 10.1 and 10.2 of two signals, their amplification with the help of amplifiers 11.1 and 11.2, measurement with the help of power dividers 12.1 and 12.2 and interferometers 13 of the phase difference of the amplified signals. Subsequently, the control device recalculates this phase difference in the direction of arrival of these signals.

In terms of storing and reproducing the frequency and generating masking interference, the device 2 performs the same functions as the corresponding device of the prototype station. It carries out signal amplification at its real ultra-high frequency, frequency-selective branching, conversion to an intermediate frequency and vice versa, conversion to ultra-high frequency, as well as the formation of masking interference. Compared with the corresponding device for storing and reproducing the frequency of the prototype station, it does not generate distance-distracting interference, but using it with a power divider 20, two additional output signals are generated at a real ultra-high frequency to generate pulse signals in the output microwave amplifiers 3.1 and 3.2 interference.

Microwave output amplifiers 3.1 and 3.2, as well as the corresponding microwave output amplifiers of the prototype station, amplify and emit masking noise generated in device 2, as well as generate, amplify and emit pulsed noise.

However, the masking noise in the output microwave amplifiers of the prototype station is carried out only on one polarization of the emitted signal, they are single-channel, while in the proposed station in the output microwave amplifiers 3.1 and 3.2, the amplification, formation and emission of masking interference is carried out by two channels transmitting antennas of which 4 and 5 have mutually orthogonal polarization of the emitted signals, while the second channel additionally includes an uncontrolled delay line 34 with a duration of the order of 0.1 ÷ 0.2 μs to ensure values of the complete correlation of the signals emitted by the channels. This provides an almost random polarization of the total interfering signal at the receiving point.

In addition, using a modulator-shaper 29 and an amplifier 30 of power from a real microwave signal received at the signal input of a modulator-shaper 29 from the third (fourth) output of device 2, a sufficiently powerful multiple pulse response is generated. As such, there can be either a separate active false target, or a group of separate active false targets, differing both in range and bearing. Specifically, the type of impulse noise is set by the code supplied to the control input of the modulator 29 from the output 36 (37) of the control device, depending on the board number. Summing up in the adder 35 with masking interference, it is amplified and radiated by the antenna 5 in the direction of the suppressed means.

Thus, the output microwave amplifiers 3.1 and 3.2 of the proposed station provide masking interference with chaotic polarization of the emitted signal and at the same time emit multiple repetitive pulsed interference sufficient in power, which are separate or group active false targets that vary both in range and on the bearing.

Depending on the selected service sector, from the first output 15 of the control device, meters 1.1 and 1.2 are given a command to connect the corresponding pair of receiving antennas of meters 1.1 and 1.2 of the bearing. With the reception of the signals of the suppressed means processed by meters 1.1 and 1.2, the control device measures the signals received at its inputs 16 and 17, recounts them in the measured bearing to the radiation source and directs the transmitting antennas 4 and 5 to it, determines the necessary specific type of the desired pulse interference and the corresponding codes at its outputs 36 and 37. With each reception of the signal of the suppressed means by meters 1.1 and 1.2, this signal is fed to the corresponding input of the high-frequency adder 18, devices Ohm 2 remembers its carrier frequency. Next, the received signal is converted in the device 2 into a noise masking noise. From the output of device 2, the processed signal in the form of a combination of two signals, one of which is a masking noise, and the second is a signal at the carrier frequency of the suppressed means, is fed to the inputs of one of the output microwave amplifiers 3.1 or 3.2.

Further, using the output microwave amplifiers 3.1 and 3.2, as shown above, the formation, amplification, and radiation in the direction of the suppressed means of masking interference with random polarization are carried out, as well as the formation, amplification, and radiation in the same direction of pulse interference, both types of interference emitted simultaneously.

Thus, the functionality of the proposed interference station is significantly higher than that of the prototype station:

- as shown above, masking interference in the prototype station can be created only on one specific polarization of the emitted signal, while in the proposed station it is possible both on the same polarization of the emitted signal and on the orthogonal, including chaotic , which makes the provision of "detuning" from these interference difficult;

- in addition, in the proposed station, the power of the pulsed interference is significantly higher than in the prototype station, and their specific form can vary within wider limits;

- It should also be noted that in the proposed interference station, in contrast to the prototype station, it is possible to simultaneously emit masking interference and impulse noise.

The above arguments allow us to conclude that the effectiveness of the proposed station interference on the suppressed means will be higher than that of the prototype station.

The proposed jamming station is quite easy to implement. Modulators-shapers 29 of transmitting devices 3.1 and 3.2 can be implemented on the basis of broadband with code control delay lines, power amplifiers 30 - on traveling wave lamps of the “Corkscrew” type with grid control and output power less than 1000 W, delay line 34 - based on sections a rectangular waveguide of standard cross section with a total length of about 30 m. The rest of the equipment of the proposed interference station can be implemented on the basis of the same elements as the prototype station.

Claims (1)

A shipboard station of impulse and masking interference, comprising left and right side bearing meters, a frequency storage and reproducing device, a left side microwave amplifier, a starboard microwave output amplifier and a control device in which the bearing meter of each side contains N pairs of identical receiving antennas and two microwave switches, one of the antennas of each pair is connected to the corresponding input of the first switch, the other to the input of the second switch, the outputs of the switches through identical amplifiers you high frequency and power dividers are connected to the inputs of the interferometer based on the matrix adder, the control inputs of the microwave switches are connected to the first output of the control device, and the outputs of the interferometers are connected respectively to the second and third inputs of the control device, the frequency storage and reproduction device contains series-connected input adder, the first and second inputs of which are connected to the outputs of the power dividers of the measuring instruments for the bearing of the left and right side, and the input amplifier is high the first frequency converter, a series-connected input frequency-selective splitter and a first frequency converter, a series-connected masking synthesizer and a local oscillator unit, a second frequency converter, an output frequency-selective coupler, a high-frequency output amplifier and an output power divider, the outputs of the local oscillator unit are connected to the second inputs of the first and second frequency converters, and the first and second outputs of the output power divider are According to the first and second outputs of the frequency storage and reproduction device, the microwave output amplifier of each side contains a power divider, the input of which, depending on the side, is connected to the first or second output of the frequency storage and reproduction device, two high-frequency amplifiers, the inputs of which are connected to the outputs power divider, two gates, the inputs of which are connected to the outputs of the corresponding high-frequency amplifiers, and a transmitting antenna, the input of which is connected to the output of one of the gates, characterized we note that a power divider with three outputs is introduced into the frequency reproducing and memory device, the input of which is connected to the output of the input high-frequency amplifier, the first output is connected to the input of the input frequency-selective splitter, and the second and third outputs are respectively the third and fourth outputs of the memory device and frequency reproduction, while the input of the masking noise synthesizer is connected to the output of the first frequency converter, and its second output is connected to the second input of the second frequency converter, the microwave output amplifier of each side is additionally introduced sequentially connected pulse modulator-driver and a power amplifier, as well as an uncontrolled delay line, a microwave adder and a second transmitting antenna with polarization of the emitted signal, orthogonal to the transmitting antenna signal, the input of the delay line is connected to the output of the second valve, the output of the power amplifier is connected to the second input of the microwave adder, the signal input of the modulator-driver of the pulse interference is connected to temu or fourth depending on the room side and the output frequency memory reproducing apparatus, and its control input - to the second or third depending on the room side output of the control device.

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