RU2165665C1 - Transceiver antenna system for radar station - Google Patents

Abstract

FIELD: active phased-out antenna arrays; radar stations of mobile equipment. SUBSTANCE: transceiver antenna system has two one-dimensional active phased-out transceiver antenna arrays 11 mounted horizontally and relatively orthogonaly each incorporating transceiver modules; each module has two radiators connected through switch to first sides of circulator whose second sides are connected to inputs of limiters; outputs of the latter are connected to inputs of low-noise amplifier whose outputs are connected to first sides of transmit-receive switches ; second sides of the latter are connected to inputs of power amplifiers whose outputs are connected to third sides of circulator; third sides of switches are connected to inputs of phase shifters whose outputs are connected to N-inputs (outputs) of switchgear; first side of switch is connected to that of circulator, its second and third sides, to inputs of radiators. System also has vertically mounted one-dimensional phased-out receiving antenna array with receiver modules each incorporating several radiators whose outputs are connected to inputs of multiple-side switch; output of the latter is connected to input of limiter whose output is connected to input of low-noise amplifier; output of the latter is connected to input of phase shifter whose output is connected to one of M inputs of summing amplifier. EFFECT: enlarged functional capabilities; reduced cost. 4 dwg

Description

 The invention relates to techniques for active phased antenna arrays, in particular to antenna transceivers of radar stations of mobile objects.

 Active transceiver antenna systems are known for a circular view of airspace (A. Tanygin, Yu. Kuznetsov, E. Belkin "Modern Air Defense Radar", Military Parade, July 1999, p. 50-51).

 In the known technical solutions described in the aforementioned review, it is not possible to electronically scan the space in the azimuthal plane, but to provide a circular view of the space, the electromechanical rotation of the antenna system is used. The noted disadvantages significantly limit the scope of the system, since at the same time, the radar does not have the ability to track targets on the aisle (a combination of a space survey with measuring the coordinates of targets) and speeding up the rate of updating information when moving to a sectorial survey of space.

 The closest to the present invention in technical essence and the achieved result when used is an antenna transceiver radar system (APS radar), made on the basis of an active transceiver phased antenna array, designed to view the space in the airborne radar (Introduction to Airborne Radar, second edition, George W. Stimson, Electronically Steered Array Antennas (ESAs), chap. 37, Scitech publishing, Inc., Mendham, New Jersey, 1998).

 The antenna-transceiver system 1 (Fig. 1) contains transceiver modules (PPM) 2, each of which includes: a radiator 3, the input (output) of which is connected to the first arm of the circulator 4, the second arm of the circulator 4 is connected to the input of the limiter 5, the output limiter 5 is connected to the input of a low noise amplifier (LNA) 6, the output of which is connected to the first arm of the receive-transmit switch 7, the second arm of which is connected to the input of the power amplifier 8, the output of which is connected to the third arm of the circulator 4, the third arm of the receive-transmit switch hut 7 is connected to the input of the phase shifter 9 whose output is connected to one of N inputs (N O) of the distribution device 10, the dispenser 10 is connected to the output of the master radar device input and the output of the switchgear 10 is connected with the input of the radar receiver unit.

 The known device operates as follows: in the power radiation mode, the microwave signal from the radar driver is supplied to the input of the switchgear 10, in which it is distributed between N outputs. Next, the microwave signal from each of the N outputs of the switchgear 10 enters the phase shifters 9 PPM. In the phase shifters 9, the phase of the emitted signal is changed in accordance with the desired direction of radiation and the location of the MRP. From the output of the phase shifter 9, the signal is fed to the third arm of the receive-transmit switch 7, which, in the radiation mode of power, commutes the signal to the second arm. Next, the signal is amplified by a power amplifier 8, enters through the circulator 4 in the emitter 3 and is radiated into space.

 In the mode of receiving power, the signal reflected from the target is received by the emitter 3 and through the circulator 4 is fed to the input of the limiter 5 and through it to the input of the LNA 6. In the mode of receiving power, the first arm of the switch 7 is connected to the third, and the signal from the output of the LNA is input phase shifter 9 and then to one of the N inputs (outputs) of the switchgear 10, in which the common-mode signals from N PPM are added and the radiation pattern is formed for reception.

 From the output of the switchgear, the signal received by the antenna-transceiver system is fed to the input of the radar receiver.

This device partially solved the problems inherent in known devices of a similar purpose, and eliminated the above-mentioned disadvantages. However, this device has the following disadvantages:
- limited sector of the precision survey (scanning in azimuth is performed only in the sector of angles no more than ± 60 ^o from the normal to the radiating opening);
- the inability to measure the elevation angle of the detected target.

 It is known from practice that a precision electronic circular survey of space is performed, as a rule, using four phased antenna arrays located orthogonally to each other, and elevation aiming is performed by organizing a two-dimensional aperture of the phased antenna array. The above measures really allow you to eliminate the disadvantages inherent in the prototype, but require significant costs in the process of their hardware implementation.

 The problem to which this invention is directed is to create an APS radar, free from the above disadvantages inherent in similar systems, providing circular azimuthal precision scanning and measuring the elevation angle of the target while minimizing the cost of hardware implementation of the APS radar.

 The technical result achieved by using the present invention is to create an APS radar with wider functionality: electronic scanning of the beam in azimuth and elevation planes, a programmable overview of the space and higher technical characteristics: the rate of updating information, the probability of detection and the accuracy of determining the coordinates of the target.

 The problem with the achievement of the above technical result is solved by the fact that in the APS radar containing a horizontally located one-dimensional, active transceiver phased antenna array 11, an additional second, similar to the first, horizontally located one-dimensional, active transceiver phased antenna array 11, oriented orthogonally to the first as well as an active receiving phased array antenna 14 located vertically. In addition, each transceiver module is additionally introduced via an emitter 3 and a switch 13, connecting in accordance with a given work program the outputs of the emitters 3 with the input of the circulator 4, and the introduced one-dimensional active receiving phased antenna array 14 has receiving modules 15, each of which includes several emitters 3, United by a switch 16, the output of which is connected to the input of a series-connected limiter, amplifier and phase shifter, the output of which is connected to the input of the summing device TWA 17.

Each of the transceiver gratings 11 provides precision electronic scanning in azimuth in the forward and opposite directions, which allows a circular view of the surrounding space electronically. The receiving grating 14 has a wide beam in the azimuthal plane, which is discretely transferred by the value of the beam width within 360 ^o in azimuth, and in the elevation plane, a narrow beam, which moves precisely in an electric way.

The invention is illustrated by drawings, which depict:
- in FIG. 2 shows the relative positioning of one-dimensional active transceiver phased antenna arrays 11 and one-dimensional active receive phased antenna arrays 14;
- in FIG. 3 is a structural diagram of a transceiver array with circuit diagrams of transceiver modules 12;
- in FIG. 4 is a block diagram of a receiving grid with circuit diagrams of receiving modules 15.

 APPS radar in accordance with the present invention contains two one-dimensional active transceiver phased antenna arrays 11 located horizontally and orthogonally to each other (figure 2), each of which contains transceiver modules 12? including two emitters 3 connected through a switch 13 to the first arms of the circulators 4, the second arms of which are connected to the inputs of the limiters 5, the outputs of which are connected to the inputs of the LNA 6, the outputs of which are connected to the first arms of the transmit-receive switches 7, the second arms of which are connected to the inputs of power amplifiers 8, the outputs of which are connected to the third arms of the circulator 4, and the third arms of the switches 7 are connected to the inputs of the phase shifters 9, the outputs of which are connected to the N-inputs (outputs) of the switchgear 10, with this first arm of the switch 13 is connected to the first arm of the circulator 4, and the shoulders 2 and 3 to the inputs of the emitters 3, one one-dimensional active receiving phased antenna array 14 located vertically (figure 2), containing receiving modules 15 (figure 4), each of which includes several emitters 3, the outputs of which are connected to the inputs of the multi-arm switch 16, the output of which is connected to the input of the limiter 5, the output of which is connected to the input of the LNA 6, the output of which is connected to the input of the phase shifter 9, the output of which is connected to one of the M input dov summing device 17.

APPS works as follows. The microwave signal in the radar power mode from the outputs of the power amplifiers 8 is fed through circulators 4 to the inputs of the switches 13 and to the inputs of one of the emitters 3. In the reception mode, the signal through the same emitter enters the limiter and LNA. For one state of the switch 13, the transceiver array using phase shifters 9 provides precision electronic movement of the beam in the modes of receiving and transmitting power in the azimuthal sector ± 45 ^o relative to the normal to the opening of the lattice. In another state of the switch 13, precision scanning in the azimuthal plane is carried out in the opposite (opposite) direction also in the sector ± 45 ^o from the normal.

 Thus, thanks to the newly introduced second emitter 3 and switch 13, the one-dimensional active transceiver phased array 11 provides a precise electronic overview in the azimuthal sector, which is twice as large as that of the prototype AMS. The introduction of a second transceiver array located orthogonally to the first allows you to expand the viewing sector in the azimuthal plane to a circular plane, provided there is no mutual shading of the gratings.

The emitters 3 of the active receiving phased antenna array 14, located vertically, have an expanded beam in the azimuthal plane, for example 50 ^o - 60 ^o , which allows the eight-arm switch 16 to make a switched view in azimuth in the sector 360 ^o , while the receiving array 14 using phase shifters 9 produces precision electronic scanning and high-precision measurement of the elevation coordinate of the target.

 After detecting the target and measuring its azimuth using transceiver arrays 11, the diagram of the receiving lattice 14 by means of the switches 16 is set in the corresponding azimuthal direction and using phase shifters 9, the diagram of the lattice 14 is mounted on the target in the elevation plane. The signal reflected from the target is transmitted through the emitters 3 and the switches 16 to the inputs of the limiters 5, amplified in the LNA 6 and through phase shifters 9 are in-phase summed in an adder 17, by means of which the array of the receiving array 14 is formed, then the signal is fed to the radar receivers.

 Thus, the APS, made in accordance with the present invention, provides a circular precision view of the space in the azimuthal plane and allows you to measure the elevation angle of the target with a relatively small increase in the cost of its hardware implementation.

Claims (1)

 Antenna-transceiver system containing a horizontally positioned one-dimensional active transceiver phased antenna array consisting of a switchgear and transceiver modules, each of which includes a radiator, a circulator, a limiter, a low-noise amplifier, a receive-transmit switch, a power amplifier, a phase shifter, while the radiator connected to a circulator, the first tap of which is connected to the input of the limiter, the output of which is connected to the input of a low-noise amplifier, the output of which connected to the first output of the receive-transmit switch, the second output of the receive-transfer switch is connected to the input of the power amplifier, the output of which is connected to the second output of the circulator, and the output of the receive-transmit switch is connected to the input of the phase shifter, the output of which is connected to one of the N-inputs ( outputs) of a switchgear, characterized in that a second one-dimensional active transceiver phased antenna array oriented orthogonally howling, and a one-dimensional active receiving phased antenna array located vertically, with each transceiver module of both transceiver arrays contains an additional emitter and a switch, the first arm of which is connected to the first emitter, and the second to the second emitter located opposite the first, the output of the switch is connected to a circulator, the first tap of which is connected to the input of the limiter, the output of which is connected to the input of a low-noise amplifier, the output of which is connected to the first tap of the switch receive-transmit, the second tap of which is connected to the input of the power amplifier, the output of which is connected to the second tap of the circulator, the output of the switch transmit-receive is connected to the input of the phase shifter, the output of which is connected to one of the N - inputs (outputs) of the switchgear, and the receiving module the receiving grating contains several emitters, a multi-arm switch, a limiter, a low-noise amplifier, a phase shifter, an adder, and the output of each of the emitters is connected to the corresponding outlet an ode to a multi-arm switch, the output of which through a limiter is connected to the input of a low-noise power amplifier, the output of which is connected to the input of a phase shifter, the output of which is connected to one of the M inputs of the summing device.

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