RU124816U1 - THREE-ORDER MEDIUM AND HIGH ALTITUDE RADAR STATION - Google Patents

Abstract

A medium and high altitude three-coordinate radar station containing an antenna machine including a phased array, containing diagram-forming line patterns, a power distribution and phasing device, primary and secondary receiving channels and a phased array antenna deployment device, a state recognition antenna, a state recognition device, auxiliary channel antenna, amplifier unit, azimuth code sensor, analog signal processing unit, current collector, control unit l spam, waveguide path, transmitter, radar synchronization unit, radar mode control unit, interface unit with a fiber optic communication line, a hardware machine including operator workstations, information transfer unit, interface unit with a fiber optic communication line, autonomous system power supply, while one half of the diagram-forming circuit lines connected to the primary receiving channels, the outputs of which are connected to the secondary receiving channels, and the outputs of the secondary receiving channels are connected to the unit analog signal processing, the input-output of the other half of the diagram-forming line circuits connected to a power distribution and phasing device, the output of which is connected to the primary receiving channels, and the inputs are connected to the waveguide path and the beam control device, the other output of which is connected to the primary receiving channels, and the input is to the output of the radar mode control unit, the input of which is connected to the output of the current collector, while the other input of the secondary receiving channels is connected to the output of the amplifier unit, the input of which is to the ant

Description

The proposed radar relates to the field of radio engineering, in particular, to radar, and can be used as a source of information about airborne objects in radar systems for various purposes.

Foreign three-coordinate systems are known: medium and high altitude radars: HADR (USA), AR-320-type 93 (Great Britain), TRS-2230 (France), RAT-31SL (Italy) [1].

However, these radars have disadvantages:

- the viewing sector in elevation does not exceed 30 degrees;

- the upper boundary of the detection zones in height does not exceed 36 km;

- coefficients of suppression of reflections from local objects do not exceed 45 dB;

- coagulation / deployment time of stations is from 1 to 2 hours.

Of the well-known three-coordinate radars of medium and high altitude, the closest in technical essence, circuit and constructive solution is the Gamma-C1 radar [2], adopted as a prototype.

However, the Gamma-C1 radar has disadvantages:

- the viewing sector in elevation does not exceed 30 degrees, and the upper boundary of the detection zone in height does not exceed 30 km;

- coefficient of suppression of reflections from local objects no more than 40 dB;

- measurement errors of azimuth and elevation are 25 arc minutes;

- coagulation / deployment time is 40 min .;

- due to the irrational distribution of information processing equipment among the machines, the reliability of the station does not exceed 200 hours. MTBF.

The essence of the proposed three-coordinate radar of medium and high altitude is that it contains an antenna and hardware machines and an autonomous power supply system.

The antenna machine contains a phased antenna array (PAR), including diagram-forming line patterns [3, 4], a power distribution and phasing device, primary and secondary receiving channels and a deployment device for the PAR, an antenna and a state recognition device, an antenna for auxiliary channels for suppressing signals received at the side lobes of the PAR, amplifier block, azimuth code sensor, analog signal processing block, current collector, beam control device, waveguide path, transmitter, synchronization block Radar, control unit for radar modes, a unit for interfacing with a fiber optic communication line (FOCL).

The hardware machine contains operator workstations, an information transmission unit, a fiber optic interface.

In this case, one half of the diagram-forming line circuitry is connected to the primary receiving channels, the outputs of which are connected to the secondary receiving channels, and the outputs of the secondary receiving channels are connected to the analog signal processing unit. The input-output of the other half of the diagram-forming line circuits is connected to a power distribution and phasing device, the output of which is connected to the primary receiving channels, and the inputs are connected to the waveguide path and the beam control device. The other output of the beam control device is connected to the primary receiving channels, and the input to the output of the radar mode control unit, the input of which is connected to the output of the current collector. Another input of the secondary receiving channels is connected to the output of the amplifier block, the input of which is to the antenna of the auxiliary channels. The input-output of the state recognition device is connected to the state recognition antenna. The inputs of the information transfer unit are connected to the workstations of the operators and the output of the interface unit with the fiber optic link, and the input of the operator’s places is connected to the other output of the interface unit to the fiber optic link, and its output is connected to the input of the interface unit to the fiber optic link, and the output of the information transfer unit is connected to information consumers .

The equipment of the antenna machine provides information to the hardware machine and receives control commands from the latter via FOCL.

The autonomous power supply system is connected with power cables to the equipment of the antenna and hardware machines.

The antenna machine additionally contains a local oscillator and transmitter signal generation unit (FSGP), an additional secondary receiving channel that provides overlapping of a wider sector and reduces viewing time in elevation, antenna and signal processing unit of the GLONASS and GPS satellite navigation systems intended for automatic orientation and topographic positioning of the radar, power take-off generator, power supply for the deployment of the headlamp before connecting to the radar equipment systems independent power supply. A digital signal processing device, a unit for combining information of the main channels, a digital information processing and training device, an interference analysis unit, and a functional control unit are installed therein.

The inputs of the FSGP unit are connected to the output of the radar mode control unit and to the output of the radar synchronization unit, and the outputs are connected to the input of the analog signal processing unit and the transmitter. The input of the additional secondary receiving channel is connected to the output of the primary receiving channels, and the output to the input of the analog signal processing unit, the output of which is connected to a digital signal processing device.

The outputs of the digital signal processing device are connected to the input of the digital information processing and training device and to the input of the main channel information combining unit, the output of which is connected to the input of the current collector, and the input-output of the digital signal processing device is connected to the interference analysis unit. Other inputs of the digital information processing and training device are connected respectively to the azimuthal code sensor, state recognition device, signal processing unit of the GLONASS and GPS satellite navigation systems, while the input-output of the digital information processing and training device is connected to the functional control unit, and the output to the current collector .

The input of the signal processing unit of the GLONASS and GPS satellite navigation systems is connected to the antennas receiving the signals of these systems. The power take-off generator during the collapse-deployment of the radar station is connected to the headlight deployment device.

The introduction of the FSGP block into the antenna machine increases the suppression of reflections from local objects from 40 to 50 dB.

The introduction of an additional secondary receiving channel into the antenna machine provides an extension of the field of view in elevation from 30 to 45 degrees. and in altitude from 30 to 40 km, as well as reducing errors in measuring azimuth and elevation from 25 to 15 arc minutes.

The introduction of the antenna machine and the signal processing unit of the GLONASS and GPS satellite radio navigation systems for automatic orientation and topographic location of the radar, power take-off generator, reduces the station deployment-folding time from 40 to 20 minutes.

The installation in the antenna machine of a digital signal processing device, a unit for combining the information of the main channels, a digital information processing and training device, an interference analysis unit, and a functional control unit increases the radar reliability from 200 to 400 hours. MTBF.

The essence of the proposed radar is illustrated by the structural diagram shown in figure 1.

The proposed three-coordinate radar of medium and high altitude is made on two machines - antenna machine 1, hardware machine 2 and trailer 3 of the autonomous power supply system.

Antenna machine 1 contains a HEADLIGHT 4, which includes diagram-forming circuits of lines 5, a power distribution and phasing device 6, primary 7 and secondary 8 receiving channels, an additional secondary receiving channel 9. A headlight deployment device 10, a state recognition antenna 11, a state recognition device 12, auxiliary channel antenna 13, amplifier unit 14, azimuthal code sensor 15, analog signal processing unit 16, digital signal processing device 17, main channel information combining unit 18, digital device information processing and training 19, current collector 20, beam control device 21, waveguide path 22, transmitter 23, FSGP 24, radar synchronization unit 25, jamming analysis unit 26, functional control unit 27, radar mode control unit 28, antennas 29 and a signal processing unit 30 of the GLONASS and GPS satellite navigation systems, a power take-off generator 31, an interface unit 32 with a fiber optic link.

Hardware machine 2 contains operator workstations 33, information transfer unit 34, interface unit 35 with FOCL.

The proposed radar operates as follows.

Sounding linear-frequency-modulated signals with different durations and repetition rates are generated in the driver of the local oscillators and the transmitter 24 and from its output go to the transmitter 23. After amplification, the powerful sounding signals along the waveguide path 22 are supplied to the power distribution and phasing device 6, and with of its output - to the diagram-forming circuits of lines 5 of HEADLIGHT 4, working both on radiation and on reception. The control of the radiation patterns of the headlamps for transmitting and receiving is carried out using signals from the beam control device 21 according to the commands received from the control unit of the radar 28.

The reflected signals are received by the diagram-forming circuits of lines 5 of the HEADLIGHT 4. The received signals are received in the primary receiving channels 7 from one half of the lines directly, and from the other through the power distribution and phasing device 6. In the primary receiving channels 7, the input devices are protected from powerful signals neighboring radars and own transmitter signals, gain, band pass filtering.

From the outputs of the primary receiving channels 7, the received signals are transmitted to the secondary receiving channels 8 and 9, in which the dynamic range is adjusted, amplification and double conversion of microwave signals to an intermediate frequency. The inputs of these channels through the amplifier unit 14 also receive signals received by the antenna of the auxiliary channels 13, designed to suppress signals received along the side lobes of the antenna. From the outputs of the secondary receiving channels 8 and 9, the signals are sent to the analog processing unit 16, where heterodyne signals from FSGP 24 are also fed.

In the block of analog processing 16 is a noise automatic gain control and analog-to-digital conversion of the intermediate frequency voltage into a digital code. After amplification and digitization in the analog processing unit 16, the received signals are transmitted to the digital signal processing device 17. The digital signal processing device 17 exchanges information with the interference analysis unit 26. From one of the outputs of the digital signal processing device 17, the signals are sent to the information channeling unit of the main channels 18, then through the current collector 20, FOCL 32 and 35 to the operator’s workstations 33. From the output of the digital signal processing device 17, the signals are fed to one of the inputs of the digital processing information and training 19. In this device, primary and secondary processing of information, the formation of control commands for viewing modes and noise protection, the formation of information for consumers, the processing of the results of the functional diagnostic control of radar equipment, as well as the simulation of air-noise conditions for training operators .

The input of the digital information processing and training device 19 receives information from the output of the signal processing unit 30 of the GLONASS and GPS satellite navigation systems. The digital signal and coordinate information from the output of the digital information processing and drainage device 19 is supplied through the current collector 20, FOCL 32-35 to the operator’s workplaces 33. From the output of the operator’s workplaces, information is transmitted to the information transfer unit 34. From its outputs, information is transmitted via communication lines to consumers. Operators from workplaces receive commands to control station operating modes, which are transmitted through FOCL 35-32, current collector 20 to mode control unit 28.

The power supply to the equipment is antenna 1 and hardware 2 of the machines and is supplied from the autonomous power supply system 3 via power cables. A power take-off generator 31 is used to power the device 10 for automatically deploying a phased array before connecting to the equipment of the main power supply system.

The proposed mobile three-coordinate radar of medium and high altitude has been tested and accepted for serial production.

Sources of information used in the application process

1 Perunov Yu.M., Matsukevich V.V., Vasiliev A.A. Foreign electronic equipment. / Ed. Yu.M. Perunova. Book 1. Radar systems. - M .: Radio engineering, 2010.

2 Patent No. 49285.

3 V.V. Demidov, A.D. Egorov, M.V. Indenbom. Antennas, issue 9 (55), 2001, pp. 3-8, “Printed strip vibrator phased arrays of the L and S ranges”.

4 History of domestic radar. - M: "Publishing House Metropolitan Encyclopedia", 2011, pp. 54-55.

5 Radar systems of airports. L.T. Pereverzentsev, A.V. Zelenkov, V.M. Ogarkov. - M: "Transport", 1981, p. 103.

6 Electrical equipment and automation of armored vehicles. Under. ed. V.A. Belonovsky, Military Publishing, Part 1, 1972

Claims (1)

A medium and high altitude three-coordinate radar station containing an antenna machine including a phased array, containing diagram-forming line patterns, a power distribution and phasing device, primary and secondary receiving channels and a phased array antenna deployment device, a state recognition antenna, a state recognition device, auxiliary channel antenna, amplifier unit, azimuth code sensor, analog signal processing unit, current collector, control unit l spam, waveguide path, transmitter, radar synchronization unit, radar mode control unit, interface unit with a fiber optic communication line, a hardware machine including operator workstations, information transfer unit, interface unit with a fiber optic communication line, autonomous system power supply, while one half of the diagram-forming circuit lines connected to the primary receiving channels, the outputs of which are connected to the secondary receiving channels, and the outputs of the secondary receiving channels are connected to the unit analog signal processing, the input-output of the other half of the diagram-forming line circuits connected to a power distribution and phasing device, the output of which is connected to the primary receiving channels, and the inputs are connected to the waveguide path and the beam control device, the other output of which is connected to the primary receiving channels, and the input is to the output of the radar mode control unit, the input of which is connected to the output of the current collector, while the other input of the secondary receiving channels is connected to the output of the amplifier unit, the input of which is to the ant there are no auxiliary channels, and the input-output of the state recognition device is connected to the state recognition antenna, while the inputs of the information transfer unit are connected to the operator’s workplaces and the output of the interface unit with the fiber-optic communication line, and the input of the operator’s places is connected to another output of the interface unit optical communication line, and its output is to the input of the interface unit with a fiber optic communication line, and the output of the information transmission unit is connected to information consumers, characterized in that the antennas The second machine additionally contains a local oscillator and transmitter signal generation unit, a secondary receiving channel, antennas and a signal processing unit for GLONASS and GPS satellite navigation systems, a power take-off, a digital signal processing device, a unit for combining information of the main channels, a digital information processing device, and the training, the unit for the analysis of the interference situation, the functional control unit, while the inputs of the local oscillator driver unit and the transmitter are connected to the unit control of the radar modes and to the radar synchronization unit, and the outputs to the analog signal processing unit and the transmitter, the input of the additional secondary receiving channel connected to the outputs of the primary receiving channels, and the output to the input of the analog signal processing unit, the output of which is connected to the digital processing device signals, and the outputs of the digital signal processing device are connected to a digital information processing and training device and to a unit for combining information of the main channels, the output of which is connected to to the skewer, while the input-output of the digital signal processing device is connected to the interference analysis unit, and the other inputs of the digital information processing and training device are connected respectively to the state recognition device, the azimuth code sensor, the signal processing unit of the GLONASS and GPS satellite navigation systems, the input of which is connected to the antennas receiving signals of these systems, and the input-output of the digital information processing and training device is connected to the functional control unit, and its output - to the current collector, wherein the input-output of the current collector is connected to the interface unit with the fiber optic communication line of the antenna machine, the input-output of which is connected to the input-output of the interface unit with the fiber optic communication line of the hardware machine, while the power take-off is connected to the device deployment of a phased array antenna.

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