RU118129U1 - RADAR FOR NEAR RADAR - Google Patents

Abstract

A radar for near-range radar, comprising a first receiving antenna connected to a first receiving amplifier, a stroboscopic converter connected in series, a matched filter, a synchronization and signal processing device, the control output of which is connected to the control input of the stroboscopic converter, a video pulse generator, the input of which is connected to the signal output of the device synchronization and signal processing, and the first transmitting antenna, characterized in that a second receiving antenna connected to the second receiving amplifier is introduced, a balanced detector, the input of which is connected to the outputs of the first and second receiving amplifiers, and the signal output is connected to the input of the stroboscopic converter, a differentiating circuit connected to the video pulse generator, and the output of the differential circuit is connected to the first transmitting antenna through a directly connected diode and to the second transmitting antenna through a reversely connected diode.

Description

The present device relates to the field of near radar, and in particular to devices for determining the distance to the target.

A device is known that emits a short video pulse and registers the delay time of the reflected signal (Astanin L.Yu., Kostylev AA "Fundamentals of ultra-wideband radar measurements." - M .: Radio and communications, 1989 - 190 s), which is included in the general ultrawideband measuring and computing complex. The device comprises a stroboscopic oscilloscope, a digital oscilloscope, a microcomputer, a broadband TWT for delivering shock excitation, a pulse generator, and two broadband horn antennas. The device is designed to measure the radar characteristics of target models.

An important parameter for such devices is a wide angle of view, small dimensions and high sensitivity, limited by the width of the radiation pattern used in the antenna device. When using the horn antennas proposed in the device, the required field of view is not provided.

A wide field of vision is provided in devices using the method of rotating beams and a survey of space, for example, "Radar" (patent RU 2178185, published January 10, 2002). This device comprises a master oscillator, a carrier frequency voltage generating unit, a synchronization voltage generating unit, a radiation signal generating unit, a rotating beam generating unit, a circular viewing space unit, and an indication and measurement unit for receiving signal parameters. The rotating beam forming unit comprises a synthesizer of a multiple radiation frequency group consisting of a group of radiation frequency multipliers, a radiation frequency matching unit, a group of radiation frequency converters and a group of radiation antennas. The site of the circular review contains a synthesizer of a group of multiple reception frequencies, consisting of a group of multipliers of a reception frequency, a block for matching reception frequencies, a group of reception antennas, a group of reception frequency converters, a group of reception filters, and a reception adder.

The device is designed for surveillance radar detection of a group of objects and measurement of their spatial parameters using rotating beams and a circular view of the space and provides high speed and reliability. The main disadvantage in this case is the technical complexity and dimensions of the device.

The closest in technical essence is the device according to the patent "Radar subsurface sounding" (RU 74484, published 06/27/2008), which is simpler and smaller. The device comprises a receiving antenna, an amplifier, a stroboscopic converter, connected in series with each other, a signal synchronization and processing device, the control output of which is connected to a stroboscopic converter control input, a video pulse generator, the input of which is connected to the signal output of the synchronization and signal processing device, and a transmitting antenna the input of which is connected to a video pulse generator, characterized in that a matched filter is implemented in the radar in the form of a synchronous drive, the input of which is connected to the output of the stroboscopic converter, and the output to the input of the synchronization and signal processing device.

The disadvantage of this device is that when using the known broadband antennas described in a number of works (Licul S. Ultra wide band antenna characterization and measurement of the Virginia Polytechnic Institute, Blacksburg, Virginia. 2004-164 p.), The field of view is insufficient, for example, for using radar as a miss detection device in target airborne complexes. The width of the radiation pattern of the broadband signal for these antennas is about 50-80 degrees, which is insufficient.

The technical problem solved by the claimed utility model is to expand the field of view of the radar for short-range radar (direction in the radar, engaged in short-range radar).

The technical problem in the inventive short-range radar, comprising a first receiving antenna connected to a first receiving amplifier, a stroboscopic converter, a matched filter, a synchronization and signal processing device, the control output of which is connected to a control input of a stroboscopic converter, a video pulse generator, the input of which is connected to the signal output of the synchronization and signal processing device, and the first transmitting antenna, is solved in s the fact that a second receiving antenna is connected to the second receiving amplifier, a balanced detector, the input of which is connected to the outputs of the first and second receiving amplifiers, and the signal output is connected to the input of the stroboscopic converter, a differentiating circuit connected to the video pulse generator, and the output is a differential circuit connected to the first transmitting antenna through a directly connected diode and to the second transmitting antenna through a reverse connected diode.

The invention is illustrated by the following drawings:

Figure 1 shows a structural diagram of a utility model, figure 2 - timing diagrams of signals, figure 3 - diagram of a balanced detector, figure 4 - diagram of a differentiating circuit.

The near-radar radar (figure 1) includes: 1 ₁ - the first receiving antenna; 1 ₂ - the second receiving antenna; 2 ₁ - the first receiving amplifier; 2 ₂ - the second receiving amplifier; 3 - stroboscopic converter; 4 - device synchronization and signal processing; 5 - video pulse generator; 6 ₁ - the first transmitting antenna; 6 ₂ - the second transmitting antenna; 7 - matched filter; 8 - balanced detector; 9 - differentiating circuit; 10 ₁ and 10 ₂ are diodes. The blocks shown in the block diagram have a power supply system not shown in the diagram.

Figure 2 shows the timing diagrams of the signals in the inventive radar: 11 - pulses generated by the pulse generator; 12 - pulses at the output of the differentiating circuit; 13 ₁ and 13 ₂ - exciting pulses of transmitting antennas; 14 ₁ and 14 ₂ - output pulses at the receiving antennas; 15 - output signal of the balanced detector

Figure 3 presents a diagram of a possible implementation of a balanced detector. The balanced detector circuit contains a transformer with a midpoint 16, a diode 17, and a load resistance 18.

Figure 4 presents a diagram of a possible implementation of the differentiating circuit. The circuit of the differentiating circuit contains a capacitor 19 and a resistance 20.

Figure 5 presents a block diagram of the algorithm of the signal processing device.

The radar operates as follows. The video pulse generator 5 generates video pulses, for example, in the form of a meander, the duration of which corresponds to the maximum range to the target:

where S is the maximum distance of detection and measurement;

t _and - the duration of the exciting pulse;

t _dmax - maximum pulse frequency;

C is the speed of light.

The video pulses pass to the input of the differentiating circuit 9, which generates on their fronts, nanosecond pulses of different polarities, arriving at the first transmitting antenna 6 ₁ and the second transmitting antenna 6 ₂ through diodes 10 ₁ and 10 _2, respectively. As a result, each of the transmitting antennas is excited by its own pulse at a certain point in time and in a certain direction. When an object falls within the range of a locator, the signals will be reflected from it, undergoing changes determined by the characteristic of its equivalent scattering surface.

The reflected signal from a certain direction will be received mainly by the first receiving antenna 1 ₁ or the second receiving antenna 1 ₂ and amplified respectively in the first receiving amplifier 2 ₁ or the second receiving amplifier 2 ₂ . When passing through a balanced detector 8, the reflected pulses will be converted to a unipolar signal input to the input of the stroboscopic transducer 3. Further processing consists in accumulating a given number of input pulses in a matched filter 7, detecting the reflected signal according to the criterion for exceeding a given threshold and measuring the distance to the target using the time delay of the reflected signal in the synchronization and signal processing device 4. Thus, due to the presence of two bi-directional of the transmitting and receiving antennas, a solution to the technical problem is achieved - expanding the radar field of view.

The device can be implemented as follows:

The video pulse generator can be created both on the basis of electronic devices with nano- and picosecond switching currents, for example, avalanche diodes, and a multivibrator - a relaxation pulse generator of almost rectangular shape, made in the form of an amplifier device with a positive feedback circuit.

The balance detector can be implemented according to the traditional scheme with a midpoint or by a bridge circuit.

As a differentiating circuit, an RC circuit can be used. In this case, the product of resistance and capacitance should be less than the duration of the video pulse arriving at its input.

Considering the use of picosecond exciting pulses of transmitting antennas, it is necessary to use ultrafast diodes for fast switching to decouple bipolar pulses.

The stroboscopic converter can be implemented using modern technology of direct conversion of the analog input signal by high-speed ADCs, or by a circuit similar to that used in digital stroboscopic oscilloscopes

A matched filter can be a synchronous drive (Z.M. Kanevsky, M. I. Finkelshtein, “Fluctuation interference and detection of pulsed radio signals”, Gosenergoizdat, 1963, pp. 169-179.) And consist of a summing device and delay lines .

The first receiving antenna, the second receiving antenna, the first receiving amplifier, the second receiving amplifier, a stroboscopic converter, a matched filter and a synchronization and signal processing device have well-known implementation options published in the literature.

This radar can be used in near-radar devices, in particular, in miss detection equipment used in firing target complexes. For such equipment, there is an acute question of reducing the dimensions with the least loss in sensitivity and angle of view. When using the device according to the patent RU 74484 to ensure an increase in the angle of view, it is necessary to use omnidirectional or weakly directional antennas. At the same time, in order to maintain the operating range, it will be necessary to increase the power of the emitted pulses. When using the proposed device, it becomes possible to use more efficient antennas. Antennas can be mounted directly in the rear of the aircraft or on a specially towed object. In this case, the radiation patterns of the emitters should overlap in level - 3dB. In this case, the width of the radiation pattern can be determined using a technique that takes into account the specifics of working with UWB signal, as described, for example, in (M.M. Bulatov, A.P. Ovcharov, Yu.E. Sedelnikov. "Directivity characteristics of ultra-wideband radio antennas ”, Vestnik MarSTU, No. 1 2011. - Yoshkar-Ola). The proposed device does not increase dimensions, while allowing to increase sensitivity and reduce radiated power. In this case, it will be achieved the technical result of the invention is the expansion of the radar field of view.

Claims (1)

Near-radar radar, comprising a first receiving antenna connected to a first receiving amplifier, a stroboscopic converter, a matched filter, a synchronization and signal processing device, the control output of which is connected to a control input of a stroboscopic converter, a video pulse generator, the input of which is connected to the signal output of the device synchronization and signal processing, and the first transmitting antenna, characterized in that the second receiving an antenna connected to the second receiving amplifier, a balanced detector, the input of which is connected to the outputs of the first and second receiving amplifiers, and the signal output is connected to the input of the stroboscopic converter, a differentiating circuit connected to the video pulse generator, and the output of the differential circuit is connected to the first transmitting antenna through directly turned on diode and to the second transmitting antenna through a back-connected diode.