RU2715060C1 - Imitation-test complex of semi-realistic testing of radar station - Google Patents

Abstract

FIELD: radar ranging.

SUBSTANCE: invention relates to radar ranging and can be used to assess the most reliable characteristics of radar facilities. Simulation-test complex of semi-real testing of radar station comprises target simulator made in the form of unmanned aerial vehicle (UAV) with radar reflector installed on it, device for controlling a target simulator with an antenna point, a tested radar station, a former of a signal reflected from the target simulator, first and second inputs of which are connected to the first and second outputs of the tested radar station, a microwave signal transmitter of illumination, the input of which is connected to the output of the shaper of the signal reflected from the simulator of the signal target, microwave signal output of the illumination signal is connected to the input of the transmitting antenna of the simulated target illumination signal, which is installed on the positioning drive of the transmitting antenna of the illumination signal, which input is connected to signaling antenna positioning signal generator of illumination signal, input of which is connected to target simulator, wherein transmission antenna of illumination signal with drive is closed by barrier from radar absorbent material. Deflector installed on the UAV is omnidirectional; the UAV is made on the basis of a quadcopter capable of hovering rigidly relative to the tested radar station.

EFFECT: possibility of performing semi-realistic tests of radar stations of various types with the possibility of simulating parameters of radar targets.

3 cl, 1 dwg

Description

The proposed simulation and testing complex of semi-natural testing of a radar station relates to radar and can be used to assess the most reliable characteristics of radar equipment.

The well-known "Simulation-testing complex for a radar station" (RU No. 2533779 C2, publ. March 20, 2014, IPC G01S 7/40) containing the goal to create a natural environment in the field of view according to a given overflight program, on board which are connected to satellite navigation system, flight navigation system and electronic measuring device associated with the control point. The purpose for creating a full-scale environment in the field of view according to a given flight program was made in the form of an unmanned aerial vehicle with a wing, plumage, fuselage, engine and landing gear, equipped with a launcher, on which there is a pusher and a retractable retractable starter on the side of the engine screw. On the fuselage in its lower part along the longitudinal axis there is a stop contacting during takeoff with the end surface of the pusher, and the landing device is installed in the compartment, on the wall of which an opening wing is connected, which is connected to an automatic lock.

Closest to the technical nature of the present invention is a "System for checking and testing air defense systems" (RU No. 109870 U1, publ. 10/27/2011, IPC G01S 7/40), containing an air target with a control device, a radar detection station and a capture station and target tracking, a device for detecting target tracking and tracking parameters, the aerial target being made in the form of an unmanned aerial vehicle with a variable effective dispersion area.

The disadvantages of the known devices is that the work of the proposed verification and testing systems involves the full broadcasting of the radio transmitting devices of the tested radar station, which is not always possible.

The technical result of the invention lies in the possibility of conducting semi-natural tests of various types of radar stations with the ability to simulate all parameters of radar targets.

The essence of the proposed technical solution lies in the fact that the simulation and test complex of the semi-natural testing of a radar station contains a target simulator made in the form of an unmanned aerial vehicle with a radar reflector installed on it, a target simulator control unit with an antenna post and a tested radar station.

New features that ensure the achievement of the claimed technical effect is the introduction to its shaper of a signal reflected from the target simulator, the first and second inputs of which are connected to the first and second outputs of the tested radar station, a microwave backlight signal transmitter, the input of which is connected to the output of the shaper reflected from the target simulator , the output of the transmitter of the microwave signal of the backlight is connected to the input of the transmitting antenna of the backlight signal of the simulated target, mounted on a positioning drive a transmitting antenna of the backlight signal, the input of which is connected to the output of the driver of the positioning signal of the transmitting antenna of the backlight signal, the input of which is connected to the control device of the target simulator. Moreover, the transmitting antenna of the backlight signal with the drive is closed by a barrier of radar absorbing material. The reflector mounted on the unmanned aerial vehicle is omnidirectional; the unmanned aerial vehicle is based on a quadrocopter capable of freezing motionless relative to the tested radar station

In FIG. A simulation and testing complex for testing a radar station is presented, where:

1. UAV simulator of a quadrocopter type target;

2. Omni-directional radar reflector on board the UAV;

3. UAV control unit with antenna post;

4. Tested radar (in the "on reception" mode);

5. Shaper of the signal reflected from the target simulator (UAV);

6. The transmitter of the microwave signal "backlight";

7. The transmit antenna of the signal "illumination" of the simulated target;

8. The mechanical drive positioning the transmitting antenna signal "backlight";

9. Shaper of positioning signals of the transmitting antenna of the signal “illumination” of the target simulator (UAV);

10. A barrier of radar absorbing material around the antenna of the "backlight" signal, providing isolation through the forward channel; the passage of the signal from it to the antenna post of the tested radar;

11. Antenna post (including on the basis of the PAR, AFAR) as part of the radar;

12. Possible spatial positions of the radiation pattern of the radar antenna post when viewing or tracking a target;

13. The trajectory of the UAV simulator target in one of the picture planes;

14. The average elevation of the UAV (slant range R) from the antenna of the tested radar;

15. The main beam of the transmitting antenna signal "backlight";

16. The maximum level of the side lobes of the antenna signal "backlight" in the area of the antenna under test radar;

17. The control channel of the target simulator - UAV;

18. The re-emitted (from the reflector to the UAV) signal of the simulated target.

The simulation and test complex of the semi-natural testing of a radar station contains a target simulator 1 in the form of an unmanned aerial vehicle with a radar reflector 2 mounted on it, a target simulator control device with an antenna post 3 and a tested radar station 4. In addition, a simulation and test complex of a semi-natural test of a radar station contains a shaper of signal 5 reflected from the target simulator, the first and second inputs of which are connected to the first and second output Ami tested radar station 4, the transmitter of the microwave signal of illumination 6, the input of which is connected to the output of the driver of the signal reflected from the target simulator 5. The output of the transmitter of the microwave signal of illumination 6 is connected to the input of the transmitting antenna of the signal of the simulated target 7, mounted on the positioning drive of the transmitting antenna of the signal of illumination 8, the input of which is connected to the output of the driver of the positioning signal of the transmitting antenna of the backlight signal 9, the input of which is connected to the control device of the target simulator with 3, and the transmitting antenna of the backlight signal 7 with the drive of its positioning 8 is closed by a barrier of radar absorbing material 10

The system operates as follows.

The tested radar (4) operating in the “receive” mode (in this case, the transmitter may either not turn on at all or work on the “equivalent” antenna), in some of the possible modes (review, tracking, etc.), transmits via the terrestrial cable communications system from the synchronizer blocks and the reference generator block to the driver of signal 5 reflected from the simulated target, the necessary parameters for this (possible reference radiation frequencies, clock synchronization pulses of the transmitter, etc.). In the driver of the signal reflected from the target simulator (5), based on the signals from the tested radar, simulation signals are generated that are “reflected from the target” with the necessary (relative to the emitted):

- delays that determine the distance to the target;

- Doppler frequency shifts that determine the radial velocity of approach of the target and the radar;

- attenuation, which determines the scattering parameters of the direction-finding target (EPR), etc.

The signals 5 formed in the driver of the signal 5 reflected from the target simulator, the signals, after corresponding amplification in the transmitter of the microwave backlight signal 6, are fed to the transmit antenna of the backlight signal of the simulated target 7, mounted on a mechanical drive for positioning the transmit backlight antenna 8 that monitors the UAV 1 moving in space. The control signals of the drive 8 are generated by the driver of the positioning signal of the transmitting backlight antenna to the UAV 9 based on the data received from the ground control device of the UAV with the antenna post 3. These signals form the commands of the drive of the positioning of the transmitting backlight antenna to the target simulator, so that the target simulator being tracked 1 (UAV) is always in the main beam of the radiation pattern 15 of the transmitting antenna of the illumination signal of the simulated target 7. Omni-directional radar reflector l 2 on board the UAV uniformly disperses the radiation energy 18 in space according to the bistatic secondary scattering diagram (indicatrix) for the applied omnidirectional reflector. Thus, provided that the scattering object (the reflector on board the UAV) is removed to the distance R14 of the “far zone” for the test radar at the surface of its antenna post 11, a plane electromagnetic wave is created, the normal to the front of which corresponds to a certain angular position of the reflecting object in the system coordinates of the tested radar. Various angular positions (or their continuous change) can be simulated by setting different UAV trajectories 13 and speeds of movement along them, using the standard UAV control channel 17 with its ground control device with antenna post 3. Thus, in addition to range, speed and The ESR of the target simulator, formed in the driver of signal 5 reflected from the target simulator, should be included in the UAV operation and angular tracking channels of the tested radar (without transmitting the probe signal to the air a). The radiated power of the simulated UAV backlight signal will be determined by the ultimate sensitivity of the tested radar (for the selected type of reflector on board the UAV), and the change in the power level of the transmitter of the microwave backlight 6 signal allows you to simulate targets with different EPRs. In this case, it is necessary to ensure a significant degree of isolation on the direct passage channel, determined by the level of maximum lateral radiation 16 of the transmitting antenna of the signal of the "illumination" of the simulated target, between it and the antenna post 11 of the tested radar 4. This can be achieved by shielding the transmitting antenna of the signal "illumination" of the simulated target by a barrier of radar absorbing material 10, as well as by removing the antenna post of the tested radar 11 and the transmitting antenna of the illumination signal of the simulated target 7 apart ence providing the necessary degree of isolation. If the whole set of equipment for generating and transmitting the “backlight” signal is organized in the form of a mobile mobile post mounted, for example, such a task can be solved on a car chassis.

Thus, the semi-natural modeling system under consideration allows us to almost completely simulate the operation of the radar (for one target) in various modes of its operation. At the same time, in the semi-natural simulation mode, it becomes possible to test all the blocks of the tested radar (including antennas, microwave receiver blocks, angular tracking channels) and, which is especially important, collectively evaluate the radar's performance as a whole.

Claims (3)

1. Simulation-testing complex of the semi-natural testing of a radar station, containing a target simulator, made in the form of an unmanned aerial vehicle with a radar reflector installed on it, a target simulator control device with an antenna post, a tested radar station, characterized in that it consists of a simulation and testing complex a half-life test of the radar station, a shaper of the signal reflected from the target simulator was introduced, the first and second inputs of which are single with the first and second outputs of the tested radar station, the microwave transmitter of the backlight signal, the input of which is connected to the output of the driver of the target reflected from the simulator, the output of the transmitter of the microwave signal of the backlight is connected to the input of the transmitting antenna of the backlight signal of the simulated target installed on the positioning drive of the transmitting antenna of the backlight signal, the input of which is connected to the output of the driver of the positioning signal of the transmitting antenna of the backlight signal, the input of which is connected to the control device Ator purpose, the transmitting antenna illumination drive signal from the radio closed barrier material. 2. The simulation and testing complex according to claim 1, characterized in that the reflector mounted on the unmanned aerial vehicle is omnidirectional. 3. The simulation and testing complex according to claim 1, characterized in that the unmanned aerial vehicle is based on a quadrocopter capable of freezing motionless relative to the tested radar station.

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