RU118073U1 - DEVICE FOR IMITATION OF REFLECTED SIGNALS OF A RADAR STATION - Google Patents

Abstract

A device for simulating the reflected signals of a radar station, consisting of an antenna, a radio receiver connected to the first input of the modulator, a power amplifier, characterized in that it contains a circulator, to one of the inputs of which an antenna is connected, the output of which is connected to the input of the radio receiver, a carrier frequency generator, an output which is connected to the second input of the modulator, the output of which is connected to the input of the radio power amplifier, the output of which is connected to the input of the radio line antenna, the output of which is connected to the input of the radio receiver of the radio line, the output of which is connected to the input of the radio line detector, the output of which is connected to the input of the power amplifier, the output of which is connected to the input of the circulator, the above blocks with connections between them are installed on the first carrier, and the blocks identical to the above-described ones with connections between them are installed on the second carrier, modulators, radio power amplifiers and radio link antennas of the first and second carriers are made so that the modulated signals after amplification in the power amplifier of the radio link are emitted and received by the antennas of the radio link, while the signal f [t-R2 / c-R0 / c], and the antenna of the radio link of the second carrier, respectively, the signal f [t-R1 / c-R0 / s ] where! R0 - distance between carriers,! R1 is the distance between the radar station and the first carrier,! R2 is the distance between the radar station and the second carrier,! с = 3 108 m / s - the speed of propagation of an electromagnetic wave in the air,! t - time,! f is the signal function.

Description

The technical solution relates to the field of electronic warfare and can be used to create spurious aviation targets that distract the work of air defense systems. To this end, false aviation targets are used, including in the form of unmanned aerial vehicles.

To create a sufficiently intense reflector of radar signals, passive reflectors are known, for example, in the form of corner reflectors or Lueneberg lenses (Paly AI Radio-electronic warfare. Military Publishing House of the Ministry of Defense of the USSR, 1989, pp. 77-83). The disadvantage of these devices is the significant overall dimensions, which makes it difficult to install them on small aircraft. For example, to simulate a signal reflected from an average aircraft (EPR = 10 m ² ), a passive reflector with a diameter of about 0.8 m is required for the decimeter wave range.

This drawback is absent in active radar reflectors. A known variant of such a device, consisting of antennas, a radio receiver, time delay devices, a modulator, and a terminal power amplifier (Paly A.I. Radio electronic warfare. Military Publishing House of the USSR Ministry of Defense, 1989, pp. 39-40). The disadvantage of this device is that the reflected signal has a number of parameters that distinguish it from the original, which allows the radar to recognize a false target.

Known simulators of reflected signals, characterized by high reliability of the simulation, for example, a station simulating radar interference according to RF patent No. 2258243, published on 08/10/2005 - Station of a single simulating interference Doppler radar stations, containing several channels simulating Doppler speeds. And also a device for creating interference according to the patent of the Russian Federation No. 2229603, published on July 20, 2008. - A device for creating targeted interference to radar stations, which allows to simulate a number of parameters of the reflected signal. The device comprises a receiving antenna, an input switch, a broadband high-frequency amplifier (UHF), a splitter, input bandpass filters, a control and synchronization unit, an input switch, an output channel switch, a signal frequency reproducing subsystem, a pulse selector, an adder, an UHF output, transmitting antenna, reference generator, mixer of the subsystem for estimating the signal frequency, mixer of the subsystem for reproducing the signal frequency, intermediate-frequency amplifier (IFA), band-pass filter of the frequency channel, pre itelny UHF forming apparatus baseband, the pulse generator and the noise, the intermediate frequency block path setup channel, voltage-controlled oscillator, a balanced modulator, an electronic switch, multichannel digital filter. Also, a high-fidelity simulated signal has an automatic response jamming station according to RF patent No. 2103705, published January 27, 1998. An automatic response jamming station, which consists of a receiving antenna, an input splitter of microwave signals, a device for short-term reproduction of a carrier frequency, and an input microwave amplifier , the first and second microwave couplers, a microwave switch, an output microwave amplifier, a transmitting antenna, a device for generating response noise interference, a device for recording pulse probing ignalov, the amplitude detector, the phase modulator logic element prohibition strobe generator and modulating pulses, the control device and temporary programming device, the signal processing logic, the first and second shapers baseband modulating voltages. A common disadvantage of the known devices is the significant complexity, and accordingly the weight and cost of the equipment, which does not allow the use of the listed technical solutions to create radar reflectors placed on the aircraft of a false aircraft target.

The prototype of the technical solution is a radar trap, according to the patent of the Russian Federation No. 2358277, published June 10, 2009. Radar trap. The device comprises a receiving and transmitting antenna, a radio receiver, a terminal amplifier, and a gain control feedback circuit. The operation of the device is to receive the irradiating signal, its amplification and radiation, and to prevent self-excitation, the gain is automatically maintained below the permissible value, depending on the isolation of the receiving and transmitting antennas. The disadvantage of the prototype is that the re-emitted signal carries information about the true angular coordinates of the false target, which makes it vulnerable to fire defense systems.

The problem to be solved in the proposed technical solution is to increase the survivability of false aviation targets in the face of active opposition, as well as to increase the effectiveness of false aviation targets used to cover the main group of air assets.

The problem to be solved in a device for simulating the reflected signals of a radar station consisting of an antenna, a radio receiver connected to the first input of the modulator, a power amplifier is achieved by the fact that it contains a circulator, to one of the inputs of which an antenna is connected, the output of which is connected to the input of the radio receiver, a carrier frequency generator, the output of which is connected to the second input of the modulator, the output of which is connected to the input of the power amplifier of the radio line, the output of which is connected to the input of the antenna of the radio line, the output of which connected to the input of the radio receiver of the radio line, the output of which is connected to the input of the detector of the radio line, the output of which is connected to the input of the power amplifier, the output of which is connected to the input of the circulator, the above blocks with the connections between them are installed on the first carrier, and the blocks identical to the above with the connections between them are installed on the second medium.

Figure 1 shows the direction to a false target located on the bisector of the angle between two carriers. Figure 2 shows a block diagram of a device for simulating the reflected signals of a radar station.

A device for simulating the reflected signals of a radar station (figure 2) contains an antenna 1 whose output is connected to the input of the circulator 2, the output of which is connected to the input of the radio 3, the output of which is connected to the first input of the modulator 4, the output of the carrier frequency generator 5 is connected to the second input of the modulator 4, the output of which is connected to the input of the power amplifier of the radio line 6, the output of which is connected to the input of the antenna of the radio line 7, the output of which is connected to the input of the radio receiver of the radio line 8, the output of which is connected to the input of det the vector of the radio line 9, the output of which is connected to the input of the power amplifier 10, the output of which is connected to the input of the circulator 2, the above blocks with the connections between them are installed on the carrier 11 ₁ , and the blocks identical to the above with the connections between them, are installed on the carrier 11 ₂ . All units included in the device for simulating the reflected signals of a radar station are standard, their circuits are published in the available literature. As carriers can be used, for example, unmanned aerial vehicles.

Consider the operation of a device for simulating reflected radar signals.

Antennas 1 mounted on media 11 ₁ and 11 ₂ receive signals and having different time delays corresponding to delays at different propagation lengths — R ₁ and R ₂ from the radar to the first and second carriers, respectively. The indicated signals passing through the circulator 2 are received and amplified by the radio receivers 3. The amplified signals f ₁ (t) and f ₂ (t) in the modulator 4 modulate the oscillations of the carrier frequency generators 5 having different carrier frequencies f ₁ and f ₂ , and the values frequencies f ₁ and f ₂ are significantly higher than the largest of the frequencies of simulated oscillations S (t). The modulated signals after amplification in the power amplifier of the radio link 6 are emitted and received by the antennas of the radio link 7, while the antenna of the radio link 7 of the carrier 11 ₁ receives the signal where R ₀ is the distance between the carriers, and the antenna of the radio link 7 of the carrier 11 ₂ is, respectively, the signal . These signals are fed to the input of the radio receivers of the radio line 8, allocated by the detectors of the radio line 9 and after amplification by power amplifiers 10, and decoupled from the input signals in the circulators 2 are emitted by antennas 1.

As a result, almost equal signals arrive at the radar location point from the first and second antennas . These signals are perceived by the radar as a signal reflected from the target at a range whose angular direction corresponds to the bisector of the angle between the directions to each of the carriers.

Known means may be used to implement the device. Receivers, transmitters, terminal power amplifiers can be performed in a traditional way using a typical electronic components base. Radio links can be made both in the radio frequency and in the optical range.

In the first embodiment, diode or transistor generators can be used as generators, while the carrier frequencies of the transmission from the first to the second carrier and from the second carrier to the first must meet the condition f ₁ , f ₂ >> f _max , where f _max is the largest of radiation frequencies of a simulated radar. Thus, f ₁ and f ₂ can be selected in the frequency range of 40 ... 60 GHz, corresponding to the window of atmospheric opacity, or in the range of 30 ... 40 GHz or 85 ... 95 GHz.

Generators, modulators and microwave cascades of receivers can be made in a transistor version, in the traditional way. Optical band equipment may be used as another embodiment of a radio link. The generation, modulation and demodulation of optical signals can be carried out by traditional technical means similar to those used in optical communication technology.

Achieving conditional goals is determined by the following factors. Firstly, the use of a false aviation target, which includes the proposed device, leads to false information regarding the true position of the specified target. Its angular position and range do not coincide with the true ones, which makes it difficult to destroy it using anti-aircraft artillery weapons. When using an anti-aircraft missile with a radar homing head against a false target, the specified missile after capturing the target will follow in the direction of its false position to order ranges where R ₀ is the distance between the carriers, - the width of the bottom of the radar antenna at a level of 0.707. After that, the homing radar will “lose” the twin target and either continue to move in the direction between the carriers, or start searching for the target. In the latter case, a very short time, of the order : at R ₀ = 300 m, , V _rockets = 1000 m / s, t = 0.3 s As a result, the rocket may not have time to complete the necessary maneuver.

Thus, the proposed technical solution allows us to solve the problem of creating false information about the air situation and at the same time has a reduced vulnerability to weapons.

Claims (1)

A device for simulating the reflected signals of a radar station, consisting of an antenna, a radio receiver connected to the first input of the modulator, a power amplifier, characterized in that it contains a circulator, one of the inputs of which is connected to an antenna, the output of which is connected to the input of the radio receiver, a carrier frequency generator, an output which is connected to the second input of the modulator, the output of which is connected to the input of the power amplifier of the radio line, the output of which is connected to the input of the antenna of the radio line, the output of which is connected to the input ohm of the radio link radio receiver, the output of which is connected to the input of the detector of the radio line, the output of which is connected to the input of the power amplifier, the output of which is connected to the input of the circulator, the above blocks with the connections between them are installed on the first carrier, and identical blocks with the connections between them are installed on the second carrier , modulators, power amplifiers of the radio link and antennas of the radio link of the first and second carrier are configured so that the modulated signals after amplification in the power amplifier of the radio link chayut radio link and received by antennas, the signal f [tR ₂ / cR ₀ / c], and the radio antenna of the second support - accordingly, the signal f [tR ₁ / cR ₀ / c], where R ₀ is the distance between the carriers, R ₁ - the distance between the radar station and the first carrier, R ₂ is the distance between the radar station and the second carrier, s = 3 · 10 ⁸ m / s is the propagation velocity of an electromagnetic wave in air, t is the time f is the signal function.