RU2632478C1 - Radioelectronic target simulator - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: invention relates to the field of radar, in particular, to the radar target signal simulators, and can be used as part of a complex simulating a multi-purpose scene by distance, Doppler frequency and angle for the exploration of the search, detection and tracking of the target (s). The radar target simulator comprises an antenna, five attenuators, a detector, two slit bridges, an amplitude modulator, a power control device, a generator, a frequency controller, a frequency switch and a counting device that are connected in a particular way, the input of the first attenuator being the input of the radar target simulator, the output of the reference device is a signal output the with the Doppler frequency.

EFFECT: creation of a simplified functional scheme of the radar target simulator, which does not require preliminary calibration of the blocks entering into it, which allows considerably to reduce the workplace preparation time for testing the RTS.

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Description

The invention relates to the field of radio electronics, in particular to simulators of a target radar signal, and can be used as part of a complex simulating a multi-purpose scene in range, Doppler frequency and angle for studying search processes, detecting and tracking targets (targets).

A known simulator of a radar target (RF Patent No. 2317563, IPC G01S 7/40, published 02/20/2008), which contains a signal simulation control device, a probing signal shaper, a controlled attenuator, a target re-emitter energy center positioner, two amplifiers and two emitters. In this case, the probe signal generator comprises a probe signal generator, an amplitude-pulse modulator, a controlled delay element and a controlled pulse duration controller.

A known simulator of a radar high-frequency frequency-modulated Doppler signal (RF Patent No. 2469348, IPC G01S 7/40, published December 10, 2012), containing two phase modulators, a balanced modulator, a phase detector, a controlled high-frequency signal generator, a directional coupler, a controlled attenuator, defined interconnected.

The closest device to the proposed technical solution for functional purpose is a simulator of a radar target (Patent RU No. 2412449, IPC G01S 7/40, published 02.20.2011) containing an antenna, an antenna switch, two attenuators, two mixers, a digital signal delay circuit, a detector , clock generator, analog-to-digital converter, three gates, power divider, frequency synthesizer and calculator.

The technical problem solved by the creation of this invention is the presence of a large number of units requiring preliminary calibration before testing radar stations.

The technical result of the claimed invention is aimed at creating a simplified functional diagram of a simulator of a radar target that does not require preliminary calibration of its constituent blocks, which can significantly reduce the time required to prepare a workplace for radar tests.

The technical result is achieved in that the radar target simulator comprises an antenna, a first attenuator, a second attenuator and a detector. In addition, it contains the third, fourth and fifth attenuators, the first and second gap bridges, an amplitude modulator, a power control device, a generator, a frequency regulator, a frequency switch and a reading device. The input of the first attenuator is the input of the simulator of the radar target. The output of the first attenuator is connected to the input of the first slot bridge, the first output of which is connected to the first input of the amplitude modulator, and the second output is connected to the input of the detector, the output of which is connected to the input of the power control device. The output of the amplitude modulator is connected to the input of the second slotted bridge, the first output of which is connected to the input of the second attenuator, and the second output is connected to the input of the third attenuator. The output of the second attenuator is connected to the input of the fourth attenuator, the output of which is the output of the first channel, and the output of the third attenuator is connected to the input of the fifth attenuator, the output of which is the output of the second channel. The output of the fourth attenuator is connected to the input of the antenna. The first input of the generator is connected to the frequency controller, its second input is connected to the frequency switch. The first output of the generator is connected to the second input of the amplitude modulator, its second output is connected to a reading device and is a signal output with a Doppler frequency.

The essence of the invention is illustrated in the drawing, which shows a functional diagram of a simulator of a radar target, where:

1 - first attenuator (At1);

2 - the first slotted bridge (ЩМ1);

3 - amplitude modulator (AM);

4 - second slotted bridge (ЩМ2);

5 - second attenuator (At2);

6 - fourth attenuator (At4);

7 - antenna;

8 - third attenuator (At3);

9 - fifth attenuator (At5);

10 - detector;

11 - power control device (UKM);

12 - generator;

13 - frequency controller (RF);

14 - frequency switch (IF);

15 - reading device (OS).

Input At1 1 is the input of the simulator of the radar target. The output of At1 1 is connected to the input of ЩМ1 2, the first output of which is connected to the first input of AM 3, and the second output is connected to the input of the detector 10, the output of which is connected to the input of UKM 11. The output of AM 3 is connected to the input of ЩМ2 4, the first output of which connected to the input of At2 5, and the second output is connected to the input of At3 8. The output of At2 5 is connected to the input of At4 6, the output of which is the output of the first channel (Output 1k), and the output of At3 8 is connected to the input of At5 9, the output of which is the output of the second channel (2k output). The output of At4 6 is connected to the input of the antenna 7. The first input of the generator 12 is connected to the RF 13, its second input is connected to the inverter 14. The first output of the generator 12 is connected to the second input AM 3, its second output is connected to the OS 15 and is the signal output with Doppler frequency (Fd).

The proposed functional diagram is simple to implement and does not require preliminary calibration of its constituent units, which can significantly reduce the time required to prepare a workplace for radar testing.

A simulator of a radar target operates when monitoring a radar station (radar) as follows.

A signal at the carrier frequency (Fnp) is supplied to the input At1 1 from the monitored radar, which is fed to the first input AM 3 through the SHM1 2. Generator 12 is a high-frequency stimulating signal generator. From the first output of the generator 12, a sinusoidal signal with a Doppler frequency (Fd) is supplied to the second input AM 3. Next, the modulated signal is fed to the input of ЩМ2 4, where it is divided into two channels. The signal of the first channel from the first output of ЩМ2 4 passes through At2 5 and At4 6 and enters the antenna 7, through which it is radiated into space. After that, the radiated signal is received by the radar antenna. Such a check allows us to identify the radar operability, but does not provide a qualitative assessment, since it is impossible to accurately estimate the spatial losses between antenna 7 and the radar antenna.

To obtain a qualitative assessment of the operability of a monitored radar, the signal of the second channel from the second output of ЩМ2 4 after it passes through At3 8 and At5 9 is fed directly to the input of the receiving path of the monitored radar. Losses in connecting devices are regulated and taken into account when measuring radar parameters. The signal level is controlled by the attenuators At1 1, At2 5, At3 8, At4 6 and At5 9. The input signal is controlled by At1 1 and is controlled by the power control device 11, which is fed through the detector 10 from the second output of ЩМ1 2. Balancing the signal levels of the first and the second channel is provided by At4 6 and At5 9 smooth attenuators. To control the radar over the entire Doppler range, the frequency of the generator 12 is continuously adjusted using RF 13 at the first input of the generator 12 and stepwise using the IF 14 at the second input of the generator 12. From the second output of the generator 12, the pulse signal Fd, generated from a sinusoidal wave, is fed to the op-amp 15, which controls and visualizes the value of the generated frequency of the generator 12. In addition, from the second output of the generator 12, the signal Fd is fed to the radar synchronizer, which ensures synchronous operation Radar and the claimed simulator of a radar target.

A radar target simulator can be manufactured according to the existing technology well-known in the radio industry on the basis of modern components and used to test radars during bench tests.

To confirm the feasibility of implementing the technical solution, a prototype simulator of a radar target was made and bench tests were carried out. In this prototype, At1 1, At2 5, At3 8, At4 6, At5 9, ЩМ1 2, ЩМ2 4, AM 3 and detector 10 are made in a single unit, which is a high-frequency part (high-frequency unit) of the radar target simulator. In the high-frequency unit, a division into two channels is organized in which it is possible to control the signal level with the step attenuators At2 5 and At3 8, as well as smooth At4 6, At5 9. Antenna 7 is a horn antenna connected to the output of the first channel of the high-frequency unit with a corresponding cable. The output of the second channel of the high-frequency unit is designed to connect to it the input of the receiving path of the monitored radar station. UKM 11, the generator 12, RF 13, FC 14 and OA 15 are made on a modern element base in a single unit (low-frequency simulator block), which is responsible for generating sinusoidal signal to modulate the signal Fnp and controls the power of this signal. To ensure the synchronous operation of the radar and the simulator of the radar target, the radar synchronizer is connected to the Fd output of the generator 12. This simulator of a radar target has reduced overall dimensions (the total mass of the simulator blocks is about 42 kg, which is much less than the known analogues) and does not require preliminary calibration, which makes it possible to organize a workstation for conducting radar tests in a short time.

Claims (1)

A radar target simulator comprising an antenna, a first attenuator, a second attenuator, a detector, characterized in that, in addition, it contains a third, fourth and fifth attenuators, first and second slot bridges, an amplitude modulator, a power control device, a generator, a frequency controller, frequency switch and reading device, the input of the first attenuator is the input of the simulator of the radar target, the output of the first attenuator is connected to the input of the first slot bridge, the first output of which is connected to the first input of the amplitude tedious modulator, and the second output is connected to the input of the detector, the output of which is connected to the input of the power control device, the output of the amplitude modulator is connected to the input of the second slot bridge, the first output of which is connected to the input of the second attenuator, and the second output is connected to the input of the third attenuator, the output of the second the attenuator is connected to the input of the fourth attenuator, the output of which is the output of the first channel, and the output of the third attenuator is connected to the input of the fifth attenuator, the output of which is the output of the second the output of the fourth attenuator is connected to the antenna input, the first input of the generator is connected to the frequency controller, its second input is connected to the frequency switch, the first output of the generator is connected to the second input of the amplitude modulator, its second output is connected to the reading device and is the signal output from Doppler frequency.

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