RU2422849C1 - Radar facility - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: radar facility represents equally spaced receiving and transmitting stations, where space natural or artificial noise signal sources are used as transmitting station, and receiving station is ground-type and includes antenna and receiving deice including the main receiving path for noise signals, recording system of quantised noise signal, correlation device, and synchrometer. At that, the main receiving path includes low-noise amplifier (LNA) with wide receiving band and frequency converter connected to LNA, which has the output connected to recording system to which the synchrometer is connected and which includes two recording channels the outputs of which are connected to correlation device.

EFFECT: antenna reception of two quasi-noise signals, one of which is reflected from object and the other one if reference from transmitting station; the correlation between the above signals has the information on available object, value of delay between signals and change of time delay.

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Description

The invention relates to radar, in particular to multi-position radar, including with detection "in the light", and can be used for detection, measurement of coordinates and tracking of flying objects both in airspace and in near space.

Bistatic radar stations (RLS) are known (see Chernyak BC Multilink radar. - M.: Radio and communications, 1993, - 416 p., Guide on radar. Translation from English under the editorship of M. Skolnik. T.4. - M .: Soviet radio, 1979), including multi-position, in which the transmitting and receiving complexes of equipment are separated in space. Such a construction has a number of advantages compared to a monostatic radar (see Ufimtsev P.Ya. // Radio Engineering and Electronics, 1989, vol. 35, No. 12 - p. 2519-2527, Glaser J. Bistatic RCS of Complex Objects Near Forward Scatter , IEEE Transactions on aerospace and electronic systems. Vol. AES-21, No. 1, January, 1985. - p.70-78), which consist in the possibility of implementing the radar method based on the luminous effect, which consists in the fact that upon irradiation of an object , whose dimensions are several times greater than the wavelength emitted by the transmitter, the energy scattered backward is several orders of magnitude (on average three) less than the energy seeded forward along the irradiation line, as a result of which the effective scattering area (EPR) of the object when observed in a “bounce” bistatic radar is thousands of times greater than the EPR of the object for a traditional monostatic radar.

Known radar complex (see RU 2324197), containing a bistatic "translucent" radar station (radar), which is a spaced apart transmitting position as part of a series-connected transmitter and transmitting antenna and a receiving position as part of a series-connected receiving antenna with a multipath radiation pattern, the receiving device and the operator’s workplace, while the transmitting and receiving antennas are raised to a height that provides direct radio visibility, and the meetings are directed well, at the same time, a monostatic radar was introduced at the receiving position, the detection zone of which overlaps the detection zone of the bistatic “radar” radar, and the input-output of the monostatic radar is connected to the output-input of the operator’s workstation, providing the command to turn on the monostatic radar as directed by the bistatic Radar, display, identification of radar information and the issuance of target designation to an external consumer in the form of output information from the radar system, while the operating frequencies of the bistatic Swetnam "monostatic radar and radar are offset to ensure their simultaneous operation.

However, in most known radars, pulsed or quasi-harmonic signals are used as the emitted signal of the transmitting station, as well as the received reflected signal, the comparison of which with the emitted carries information about the position of the object. To process the reflected signal using traditional radar techniques, the structure of the emitted signal must be known. Correlation processing of such signals is either impossible or ineffective, which affects the accuracy of the coordinate measurements of the object. The bandwidth of the receiving device is determined by the nature of the emitted signals of the transmitting radar and is usually small.

In the bistatic known radars, the parameters of the receiving and transmitting complexes are interconnected, i.e. the receiving station can only work on the signals of its radar.

In addition, in a multi-position location, the direct signal from the transmitting station is in some cases spurious and its suppression is required to process the signal reflected from the target.

The task to which the invention is directed is the use of correlation methods for processing noise signals to increase the reliability of target detection and increase the accuracy of measuring the coordinates of objects in air and outer space.

The technical result of the invention is the reception by one antenna (or two adjacent antennas) of two quasi-noise signals - reflected from the object and the reference from the transmitting station, the correlation between which carries information about the presence of the object (detection), the delay between the signals (direction to the object) and change time delays (speed).

It is known that the sensitivity of the receiving device and the accuracy of determining the delay depend on the reception bandwidth. Extending the reception band to tens of MHz is effective only with the noise or quasi-noise spectrum of the emitted signal.

To achieve the specified technical result, the radar complex is a transmitting and receiving station spaced in space, where space-based natural or artificial noise sources are used as the transmitting station, and the receiving station is ground-based and contains an antenna and a receiving device, including the main receiving path for noise signals , a registration system for a quantized noise signal, a correlator, a synchronometer, the main receiving path including low noise a wide amplifier amplifier (LNA) and a frequency converter connected to the LNA with an output connected to a recording system, which also has a synchronometer and which contains two recording channels, the outputs of which are connected to the correlator.

To increase the sensitivity and highlight a narrow field of view, a reference antenna and an adder can be additionally introduced into the ground station of the radar complex, the receiving antenna being connected to the first input of the adder and the supporting antenna being connected to the second input of the adder, and the output of the adder connected to the main receiving path.

In order to increase the efficiency in the case of a “translucent” effect with short delay times, a reference antenna and a receiving path connected to the reference antenna identical to the main receiving path can be added to the ground station of the radar complex, the outputs of these receiving paths being connected respectively to the first and second recording channels registration systems.

In the proposed radar complex, a direct signal with a quasi-noise spectrum of one or more transmitting radars located in near-Earth space is used as a reference signal. An antenna with a weakly directed radiation pattern is used as a receiving position, the detection zone of which directly includes “radar” radars to create a reference signal. Since the receiving system uses a broadband receiver, the fine structure of the signal spectrum of the transmitting station does not matter, and therefore, any spacecraft (SC) emitting quasi-noise signals, as well as radiation from the Sun, the most powerful natural radio source, can be used as transmitting radar. This version of the device is most effective in detecting targets in mid-air and in near space at heights of hundreds of kilometers using the "translucent" effect, when the magnitude of the signal scattered by the target is comparable in intensity to the reference one.

At target heights from a few hundred meters to tens of kilometers outside the “translucent” effect zone, the device’s efficiency will be determined by the sensitivity of the receiving station, since the signal reflected from the target depends on the effective scattering cross section (EPR) and is much smaller than the reference signal. In this case, it is possible to use a directional antenna with a large gain for tracking the target and a small reference antenna that monitors one of the transmitting radars, the signals of both antennas are summed before the LNA of the receiving path.

Currently, there are several dozen artificial Earth satellites (AES) in near-Earth space emitting quasi-noise signals: navigation GLONASS and GPS, relay, communications, etc. The use of broadband reception with correlation processing at ground-based reception centers makes it possible to use existing space transmitters as elements of multi-position radars, and the multi-position radar is also multi-position. In addition, as a source of broadband radiation with an almost continuous radio spectrum, you can use the Sun, the radiation intensity of which is comparable to the intensity of most artificial emitters in near-Earth outer space. The delay between the signals at the “translucent” location varies depending on the position of the object from zero to values of several tens of kilometers, which allows an on-line search of the radiation source by a high-speed correlator. The process of correlation of two streams of information (from two recording channels) can be carried out in quasi-real time. The signals of several “radar” radars reflected by the object will occur at different delays, which will allow determining the coordinates of the object in space with high accuracy by only one receiving complex. It is known (Handbook of Radar. Translated from English under the editorship of M. Skolnik. T.4. - M .: Soviet Radio, 1979, p.203) that in multi-position systems it is possible to determine the target position only by measuring ranges (signal delays) , with four receiving points, the problem is solved completely. When using the signal of one space radar, it will be necessary to increase the number of receiving complexes to at least two when reviewing a given region of space.

Figure 1 shows a radar complex, which is a spatially separated transmitting and receiving stations, where space-based natural or artificial noise sources are used as the transmitting station, and the receiving station is a ground-based one and contains a ground-based antenna 1 connected to the input of the receiving device, which includes a main receiving path for quasi-noise signals 2, a registration system for a quantized noise signal 3, a correlator 4, a synchronometer 5. The main receiving path 2 contains t low-noise amplifier (LNA) 6 and an intermediate frequency converter 7 connected to the LNA 6, which consists of a mixer 8, a local oscillator 9, an intermediate frequency amplifier (UPCH) 10. The output of the LNA 6 is connected to the first input of the mixer 8, to the second input of which a local oscillator 9 is connected, and the output of the mixer 8 is connected to the input of the OPC 10, the output of which is connected to the recording system 3, to which a synchronometer 5 for recording time stamps is connected and which contains two identical recording channels 11 and 12, the outputs of which are connected to the correlator 4.

The operation of the device is as follows.

Two signals are received at the ground receiving antenna 1: the reference signal from the radar and scattered from the flying object with a delay determined by the relative position of the target and the receiving antenna 1. The general signal is fed to the input of the main receiving path 2, where it is amplified by the LNA 6, converted to a low intermediate the frequency in the converter 7. In the registration system 3, the signal is converted to digital form, recorded on two magnetic media 11 and 12 together with time stamps from the synchronization device (synchronometer) 5 and fed to the correlator 4. Primary processing — obtaining a response by correlating two streams of information with the introduction of a variable delay (to compensate for the difference in the path of the received signals) is carried out directly in the process of observation in the regime of quasireal time. The correlator 4 produces the multiplication of signals (software) with the introduction of a variable delay in one of the information flows. The exact delay between the signals is determined from the maximum of the cross-correlated signal, and the interference frequency determined by the movement of the source relative to the receiving antenna 1 is determined from the maximum of its spectrum. Depending on the relative position of the receiving antenna 1, the radar and the intended target location, the range of delay variation is calculated and, accordingly, the search process is accelerated reflected signal.

To increase the sensitivity of the device and highlight a narrow field of view, a reference signal can be generated using an additional antenna 13 (Fig. 2) connected via an adder 14 to the main receiving path 2, to which the main receiving antenna 1 is also connected via the adder 14, the small reference antenna 13 is directed to the “radar” radar location zone, and a narrowly directed antenna with a large effective area of 1 is directed to the desired field of view (the most likely occurrence of targets). In this case, it is possible to achieve approximate equality of the reference and useful signals.

To increase the efficiency of the device in the case of a "translucent" effect with short delay times, a reference signal can be generated using an additional reference antenna 13 (Fig. 3), which has its own independent additional receive path 2.1, which is identical to the main receive path 2, and which includes LNA 6.1 and the intermediate frequency converter 7.1 connected to the LNA 6.1, consisting of a mixer 8.1, a local oscillator 9.1, an intermediate frequency amplifier (UPCH) 10.1, where the output of the LNA 6.1 is connected to the first input of the mixer 8.1, to the second input of which for prison oscillator 9.1 and 8.1 of the mixer output connected to the input IF amplifier 10.1, the outputs of the main and additional 2 2.1 reception paths connected respectively to the first 11 and second 12 channels record registration system 3.

In this case, due to the independence of the noise of the receiving channels, there is no maximum of the cross-correlation function at zero delay (as is the case for the autocorrelation function), which makes it possible to find a useful signal at low delays.

The operation of the proposed device was tested on the equipment according to the scheme depicted in figure 4, at an operating frequency of 610 MHz with a reception band of 8 MHz. The signal of the noise generator 15 (GS) branched into two channels, one of which was directly fed to the adder 14, simulating the reference radar signal. The second signal was applied to the adder 14 through a delay line 16 with a delay time τ having a attenuation of 15–20 dB, simulating the signal reflected from the object. The total signal from adder 14 was supplied to the LNA 6 input, converted into a video frequency using a frequency converter 7, and recorded on a computer 11 in magnetic recording system 3, and then the autocorrelation processing of this signal was performed with a delay change from zero to values exceeding τ. The presence of a response in the autocorrelation signal with a delay of τ meant the detection of a signal from GS 15. The exact value of the signal delay in the laboratory model made it possible to determine the difference in the electric lengths of the receiving paths of the reference and delayed signals. Comparison of the obtained delay value with the known value of τ gave an estimate of the accuracy of the method.

Figure 5 shows the amplitude of the autocorrelation function of the GSH signal depending on the delay when working according to the scheme of figure 4 (autocorrelation function is symmetric). Figure 6 shows the same graph, but the central maximum due to the autocorrelation of the noise of the receiver is excluded for convenience of scaling. The maximum at a delay value of about +7 samples (one sample corresponds to 62.5 ns) is the response of the receiving system to the GS signal and determines the signal delay in path 16 (Fig. 4). In Fig. 7, the autocorrelation function is shown on the left, Fig. 5, with the GS turned on, on the right - the GS is off: it is clear that the lateral maximum of the autocorrelation function is due to the presence of the GS signal.

In addition, an experiment was conducted with the reception of the GSH signal to two identical paths (figure 3). On Fig shows a cross-correlation function when receiving a GS signal to two receiving devices without introducing a delay in one of the paths. Figure 9 is a view of the correlation function when, in addition to the direct signal, the pulse train is additionally delayed by a value of τ in addition to the direct signal (similar to figure 4). It is seen that after the processing, two cross-correlation function maxima appear in the output signal due to the direct and delayed GS signals in one path when correlating with the direct GS signals in the second path.

Claims (3)

1. The radar complex, which is a transmitting and receiving station spaced in space, characterized in that the transmitting station uses space-based natural or artificial noise sources, and the receiving station is ground-based and contains an antenna and a receiving device including a main receiving path for noise signals, a registration system for a quantized noise signal, a correlator, a synchronometer, while the main receiving path includes a low-noise amplifier (LNA) with a wide and reception band LNA connected to the frequency converter with an output connected to a recording system to which is connected synchronometer and which comprises two recording channels, the outputs of which are connected to the correlator. 2. The radar system according to claim 1, characterized in that the reference antenna and the adder are additionally introduced into the ground station, the receiving antenna connected to the first input of the adder, the reference antenna connected to the second input of the adder, and the output of the adder connected to the main receiving path. 3. The radar system according to claim 1, characterized in that the reference antenna and an additional receiving path identical to the main receiving path connected to the reference antenna are additionally introduced into the ground station, the outputs of these receiving paths being connected respectively to the first and second recording channels of the registration system.

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