RU40679U1 - MOBILE THREE-YEAR RADAR STATION - Google Patents

Abstract

A mobile three-coordinate radar station containing an antenna-rotary device including an antenna of a ground radio interrogator, a rotary support mechanism with a current collector, a phased antenna array containing transceiver lines, a probe signal divider and a display and control device including an operator’s workstation , a power system and a control unit for an azimuthal rotation drive, characterized in that the signal processing unit, the driver of the local oscillators and the transmitter, the terrestrial radio interrogator unit is located in the antenna rotary device, and the phased array antenna further comprises a pilot divider, a local oscillator divider, a reference divider and synchronization divider, four transceiver lines, a preliminary power amplifier, an additional output are introduced into each transceiver line a power amplifier, two receivers, an encoding module and a digital beamforming processor, one output of which is connected to a beamforming processor nth transmit and receive line, and the output of the last forming and transmitting line forming processor to the signal processing unit, the other output of the forming base processor is connected to the inputs of the output power amplifiers and to the input of the phase shifter, one input of the digital forming base is connected to the output of the encoding module, the other to the output of the reference signal divider and synchronization, while two inputs of the receivers are connected to the output of the divider of the local oscillator signal, the other two inputs of the receivers are connected to the outputs of the output

Description

The proposed utility model - a mobile three-coordinate radar refers to the field of radio engineering, in particular, to radar.

Known mobile - radar detection TPS-2630, manufactured by Thompson and included in the air defense system Krotal-NG (France) [1].

The TPS-2630 station is a pulse-Doppler radar capable of surveying airspace in motion, and contains an antenna device made in the form of a flat transceiver array, a transmitter generating RF signals at one of 12 fixed frequencies, and a receiving device made by double frequency conversion superheterodyne circuit.

Signal processing includes coherent accumulation of a useful signal, Doppler filtering, pulse compression, and stabilization of false alarms.

Such a station has the following disadvantages:

- short range detection of air targets;

- the impossibility of determining the altitude of flight of air targets;

- small limits of work in height and elevation.

Of the known mobile radars, the closest in technical essence, circuit design, tactical, technical and operational characteristics is the 1PC1-1-O radar (UVAI.461311.024) selected for the prototype.

The 1PC1-1-O radar is designed to detect, measure coordinates and identify the nationality of air targets and to provide target designation to a target tracking station.

The structural diagram of the radar 1PC1-1-O is shown in Fig.1.

The 1PC1-1-O radar consists of their antenna-rotary device, which includes a phased antenna array, a ground-based radio interrogator antenna, a rotary support mechanism, a current collector, and a signal conditioning and processing device comprising a signal conditioner

local oscillators and transmitter, receiver, signal processing unit, equipment of the ground radio interrogator, operator's workplace. However, such a radar has the following disadvantages:

- short range detection of air targets;

- low accuracy in measuring height (elevation angle);

- low protection against active interference of high intensity;

- lack of automatic functional diagnostic control of the transceiver equipment of the phased antenna array during the operation of the radar.

The essence of the proposed radar is that it contains a signal processing unit, a signal generator of local oscillators and a transmitter, a ground-based radio interrogator unit, a coding module, receivers, an antenna-rotary device including an antenna of a ground-based radio interrogator, a rotary support mechanism with a current collector, a phased antenna a grid containing identical transceiver strings, a divider of the probe signal, and a display and control device including an operator’s workstation, a power system, and lock control of the azimuthal rotation. It differs in that the signal processing unit, the driver of the local oscillators and the transmitter, and the terrestrial radio interrogator unit are located in the antenna-rotary device.

The phased antenna array further comprises a pilot divider, a local oscillator divider, a reference divider and a clock divider, and four transceiver lines. A preliminary power amplifier, an additional output power amplifier, two receivers, a coding module, and a digital beamforming processor are introduced into each transceiver line. One output of each line of the processor of digital diagram formation is connected to the processor of the next transceiver line, and the output of the processor

diagramming of the last transceiver line - to the signal processing unit. Its other output is connected to the inputs of the output power amplifiers and to the input of the phase shifter, one input of the chip-forming processor is connected to the output of the coding module, and the other is connected to the output of the reference signal divider and synchronization. Two receiver inputs are connected to the output of the local oscillator signal divider. Two other inputs of the receivers are connected to the outputs of the output power amplifiers. The second output of the additional output power amplifier is connected to the input of the beam-forming circuit of the transceiver string. The second input of the additional power amplifier is connected to the output of the preliminary power amplifier. The input of the preliminary power amplifier is connected through a phase shifter to the output of the probe signal divider, and its second output is connected to the existing output power amplifier. The output of the pilot signal divider is connected to a diagram-forming circuit of the transceiver string, and its input is connected to one of the outputs of the local oscillator driver and transmitter, the other three outputs of which are connected respectively to the probe signal divider, to the reference signal and synchronizer divider, to the local oscillator signal divider . The terrestrial radio interrogator unit is connected to the antenna of the terrestrial radio interrogator.

The placement of the signal processing unit, the signal generator of the local oscillators and the transmitter, the terrestrial radio interrogator unit in the antenna rotary device provides a reduction in the loss of useful signals in the transmitting and transmitting path, increases reliability and reduces the overall dimensions of the station.

The introduction of a pilot signal divider into the phased antenna array ensures the automatic functional diagnostic control of the phased antenna array transceiver equipment during radar operation.

The introduction into the phased array of an additional four transceiver lines, and in each line of an intermediate power amplifier and an additional output power amplifier, provides an increase in the power of the probing signal and an increase in the detection range of air targets.

The introduction of the coding module and the processor of digital diagram formation into the composition of each transceiver line increases the accuracy of measuring the height (elevation angle) and the effectiveness of protection against active interference.

The essence of the proposed utility model is illustrated by the drawing of figure 2, which shows the structural diagram of the radar.

The proposed mobile three-coordinate radar structurally consists of two parts: an antenna-rotary device 1 and a display and control device 2.

Antenna-rotary device 1 contains a phased antenna array 3, which includes a divider of the probing signal 4, a divider of the pilot signal 5, a divider of the signal of the local oscillators 6, a divider of the reference signal and synchronization 7 and twenty identical transceiver lines 8, the antenna of the terrestrial radio interrogator 9, block the equipment of the ground radio interrogator 10, the signal generator of the local oscillators and the transmitter 11, the signal processing unit 12, the current collector 13, which is part of the slewing gear 14.

Each of the twenty transceiver lines 8 contains two output power amplifiers 15, a preliminary power amplifier 16, two analog receivers 17 made in a superheterodyne circuit, a discretely controlled phase shifter 18, an encoding module 19, a digital beamforming processor 20, and a beam-forming circuit of line 21.

A discretely controlled phase shifter 18, a preliminary power amplifier 16, and two analog receivers 17 form a receiver

a transmitting unit 22, and a coding unit 19 and a digital beamforming processor 20 form a digital receiving unit of line 23.

The display and control device 2 contains an operator’s workstation 24, an azimuthal rotation drive control unit 25 and a power supply system 26.

All communications in the transmit-receive line, shown in figure 2, relate to one receive-transmit line. For the rest of the transceiver strings, the relationships between the elements of the string are identical.

The input of the beam-forming circuit of line 21 is connected to the outputs of the output power amplifiers 15 and to the corresponding output of the pilot divider 5. The second outputs of the output power amplifiers 15 are connected through receivers 17 to the coding module 19, the output of which is connected to the input of the digital forming processor 20. Two inputs output power amplifiers 15 are connected to the outputs of the preliminary power amplifier 16, and two other inputs and the input of the discretely controlled phase shifter 18 are connected to the output of the digital diagram processor formations 20. The input of the preliminary power amplifier 16 is connected through a discretely controlled phase shifter 18 to the corresponding output of the probe signal divider 4, the input of which is connected to the driver of the local oscillators and transmitter 11. Two other inputs of the receivers 17 are connected to the corresponding output of the signal divider of the local oscillators 6. Another processor output digital charting 20 is connected to the processor of digital charting of the next line, and the processor output of the last 20 lines is connected to the block brabotki signal 12. The second input beamforming processor 20 is connected to the output of the reference signal and the divider circuit 7, whose input is connected to a signal shaper of the transmitter and local oscillator 11. The local oscillator signal input divider 6 is connected to the signal generating unit and the local oscillator of the transmitter 11. The antenna ground radiozaproschika 9

connected to the ground-based radio interrogator unit 10. Signal processing unit 12 is connected through a current collector to the operator’s workstation 24 and to information consumers. The power system 26 is connected through a current collector 13 to lines 8 to a signal processing unit 12 and to a signal generator unit of local oscillators 11, and the control unit of the azimuthal rotation drive 25 is connected to the slewing gear 14.

The proposed mobile radar operates as follows.

When the phased array antenna 3 is in operation, the probe pulse from the driver of the local oscillator signals and the transmitter 11 is transmitted to the divider of the probe signal 4, the output of which is fed to the input of the transceiver module 22 of each of the transceiver lines 8 and, through a discrete controlled phase shifter 18, is transmitted to a preliminary power amplifier 16, which carries out amplification and in-phase division of the probe pulse into two equal parts. From the output of the preliminary power amplifier 16, the signals are fed to the output power amplifiers 15, where they are amplified and transmitted through the corresponding strip dividers and vibrators of the diagram-forming circuit of line 21 to space.

As a result, an antenna pattern for transmitting is formed, the shape of which in the azimuthal plane is determined by the parameters of the diagram-forming circuit of line 21, and in the vertical by control codes of phase shifters 18 of all transceiver lines.

When the phased array antenna 3 is in the receiving mode, the signals received by the diagram-forming circuit of line 21 are transmitted through the circulators of both output power amplifiers 15 to the input of analog receivers 17 of the first and second channel. From the outputs of the analog receivers 17, the signals at an intermediate frequency are fed to the inputs of the encoding module 19, which performs analog-to-digital conversion and generates codes for digital samples of quadrature received

signals. From the output of the encoding module 19, digital codes are supplied to the digital chart forming processor with a control circuit 20.

To form the desired directional pattern at the reception, digital beamforming processors 20 of each row multiply the codes of digital samples of quadrature of the received signals of the corresponding rows by complex coefficients, add the codes obtained from the previous row, and transmit the next line to the digital beamforming processor 20.

To carry out the correction, the digital beamforming processors 20 calculate the amplitudes and phases of the pilot pilot signal and are stored in the processors of each row in the form of correction coefficients. These correction factors multiply the quadrature information of signals and interference vectorly.

The performance of the digital chart formation circuit is chosen in such a way as to simultaneously form the required number of spatial beams of the bottom beam in a vertical plane at the reception.

From the output of the digital chart-forming processor 20 of the last line, the information goes to a signal processing unit 12, the software and hardware modules of which provide target isolation against local objects, intentional active and passive interference, target class recognition, direction finding of active jammers, solving primary and secondary processing problems information, as well as issuing data to the consumer of information. From the output of the signal processing unit 12, information is transmitted via digital communication channels to the operator’s workplace 24 and to the information consumer.

The proposed mobile radar station was tested, which confirmed the positive results and its advantages.

Sources of information taken into account when preparing the application:

1. Ganes Defense Wekly, 2001, v36, 19, p16.

2. Ganes Missiles Rockets, 2002, vo16, No. 8b p. 2.

3. UVAI. 461 311.024

Claims (1)

A mobile three-coordinate radar station containing an antenna-rotary device including an antenna of a ground radio interrogator, a rotary support mechanism with a current collector, a phased antenna array containing transceiver lines, a probe signal divider and a display and control device including an operator’s workstation , a power system and a control unit for an azimuthal rotation drive, characterized in that the signal processing unit, the driver of the local oscillators and the transmitter, the terrestrial radio interrogator unit is located in the antenna rotary device, and the phased array antenna further comprises a pilot divider, a local oscillator divider, a reference divider and synchronization divider, four transceiver lines, a preliminary power amplifier, an additional output are introduced into each transceiver line a power amplifier, two receivers, an encoding module and a digital beamforming processor, one output of which is connected to a beamforming processor nth transceiver line, and the output of the last forming and transmitting line forming processor to the signal processing unit, the other output of the forming unit is connected to the inputs of the output power amplifiers and to the input of the phase shifter, one input of the digital forming unit is connected to the output of the encoding module, the other to the output of the divider of the reference signal and synchronization, while two inputs of the receivers are connected to the output of the divider of the signal of the local oscillator, the other two inputs of the receivers are connected to the outputs of the output power amplifiers, and the outputs are connected to the coding module, and the other output of the additional output power amplifier is connected to the input of the diagram-forming circuit of the transceiver line, and its second input is connected to the output of the preliminary power amplifier, the other output of which is connected to the input of the existing output power amplifier, and the input of the preliminary power amplifier is connected through the phase shifter to the output of the probe signal divider, while the output of the pilot signal divider is connected to the diagram-forming circuits e of the receiving and transmitting line, and the input is to the output of the local oscillator driver and transmitter, the other three outputs of which are connected to the probe signal divider, to the reference signal and synchronization divider, to the local oscillator signal divider, and the terrestrial radio interrogator unit is connected to the terrestrial radio interrogator antenna.