RU2710837C1 - Method of increasing resolution of radar ultra-wideband probing - Google Patents

Abstract

FIELD: radar ranging.SUBSTANCE: invention relates to radar probing using single ultra-wideband (UWB) signals and can be used in probing several nearby objects, for example, a group aerial target of several aircraft. Method comprises emitting an N-petal probing radio pulse, receiving a reflected signal in a selected time window, processing it in K parallel channels, where K/N = 2, 3, 4, ..., in each of the K channels, the received reflected signal is multiplied by a signal identical to the probing N-petaled radio pulse, delayed in each channel in time relative to the previous one by the channel number by the value T/(K-1), where T is the duration of the N-petal probing radio pulse, the result obtained in each of the K parallel channels is a single integration result, displaying the obtained result for display on an indicator, based on the observation results of several bright marks on the indicator, a conclusion is made on the detection of the group air target and the number of targets in the group is estimated.EFFECT: high resolution of radar UWB probing nearby objects and high efficiency of obtaining results.1 cl, 2 dwg

Description

The invention relates to the field of radar sensing using ultra-wideband (UWB) signals of duration f and can be used for sensing several objects whose distance L is comparable to cf, where c is the speed of light, i.e. in conditions when the signals reflected from several objects of study overlap each other. Such a problem arises, for example, in radar sensing using single UWB pulsed signals in the interest of detecting and recognizing a group of airborne targets.

The use of conventional narrow-band radar (radar) does not allow to achieve the required resolution. Let a narrow-band radar radiate in the direction of finding recognizable objects a probing radio signal with a duration of f = 1 μs. This duration corresponds to a radial (range) resolution dR = cf = 300 m. Targets in a dense group, the distance between which will be less than 300 meters, will be perceived as a single mark on the radar indicator. The prompt receipt of information on the composition of the detected target will allow timely assigning a higher priority to its destruction, in accordance with the degree of the threat to the protected object. In this regard, in order to achieve timely opening of the detected air target, it is necessary to use more complex sounding radio signals, wide-base signals with intrapulse modulation, and even UWB signals.

By UWB we mean pulsed radio signals whose frequency bandwidth Df is comparable with the average frequency of their spectrum f _cf : Df ~ f _cf. To assess the degree of broadband, use the concept of a signal broadband indicator z ₀ (sometimes denoted by the letter µ): z ₀ = Дf / f _cf.

With regard to radar, this definition must be supplemented, given that the ultra-wideband radio signals used in radars are usually ultrashort radio pulses, and a physically more reasonable definition should be given: a radio signal whose frequency bandwidth is comparable to the average frequency of its spectrum is considered ultra-wideband if its spatial the duration of the SF is much less than the size of the radiating (receiving) aperture of the antenna or reflecting object (target) L.

Ultra-wideband radar allows us to hope to achieve such advantages as high accuracy of measuring the range to the target, high radial (range) resolution, the ability to recognize the type of target, etc.

There is a method of increasing the resolution of radar sensing [1, C.134-140, Fig.5.16], which consists in emitting an N-lobe probing radio pulse, continuously receiving a reflected signal in a selected time window, detecting and evaluating signals from objects of study. To solve the problem of increasing the resolution by improving the shape of the observed pulses by reducing the level of time side lobes, we used double voltage drops with adjustable amplitude, duration and relative time position of the voltage drops, which allowed us to reduce the level of time side lobes of the resulting output signal.

The disadvantage of this method is the difficulty of implementation due to the need to develop special measurement management software designed for experimenters.

Before describing the prototype and its criticism, some clarification is necessary.

Achieving the above advantages of UWB signals is possible only by completely extracting super-valuable non-coordinate information about the sensed object, and this requires adequate processing of the received signal corresponding to the probing signal.

Refer to figure 1 [1, Fig.1.1, C.10]. For clarity, in Fig. 1, in comparison with [1, Fig. 1.1], figures b) and c) are interchanged in accordance with the increase in the broadband index of the signal s ₀ . From FIG. 1, it is seen that only the 6-lobe signal a) can still be correctly applied to the concepts of “envelope” (dashed lines), as well as “frequency” and “phase”, corresponding to the description of narrow-band signals by harmonic functions. As the number of lobes decreases to three (Fig. B) and especially two (Fig. C) - the most ultra-wideband of physically feasible signals - the signal is no longer adequately described by the usual categories of spectral analysis based on interchangeable Fourier transforms.

In this regard, from the point of view of practical implementation, N-lobe radio pulses are of interest as probing signals in radars operating at ranges of several hundred kilometers. On the one hand, their characteristics already provide superresolution in range, provided that they are adequately processed, and on the other hand, traditional powerful microwave devices can be used to form them. Strictly speaking, N-lobed radio pulses are no longer narrow-band signals, but can still be described by Fourier transforms — Hilbert transforms [1, P.18]; for them, classical forms of narrow-band signal processing can be used without significant loss of generality.

Another point. With UWB radar sensing of several nearby objects (for example, air targets in a group), the problem of resolving signals received from one and the other objects arises. If several overlapping shifted UWB signals affect the optimal filter, each of them, due to the applicability of the superposition principle to linear systems, is compressed independently, i.e. it is possible to resolve signals from targets whose pulses overlap [2, C.132]. And vice versa, any non-linear processing will give rise to an uncontrolled amount of intermodulation components in the signal spectrum, which excludes separate observation of individual targets from the group.

Third remark. In the spectrum of any signal, including a single multi-leaf radar UWB, both radiated and received by the antenna, there are obviously no components at zero frequency (the integral of the function that describes the signal is always equal to zero over the signal lifetime) [1, formula 1.4, C .10]. Integration, as a linear operation on a signal, does not lead to the appearance of new components in the spectrum, including components at zero frequency.

Closest to the claimed method is a method of increasing the resolution of radar ultra-wideband sounding [3], which consists in emitting an N-lobe probing radio pulse, where N = 2, 3, 4, 5 ..., sensing the object of study with an N-lobe radio pulse carry out repeatedly, continuously receive the reflected signals in the selected time window, detect signals from the objects of study, measure and evaluate the parameters of the signals reflected from the objects of study, when receiving the reflected of the received signals with a controlled delay value, a reception window is set with the ability to obtain the entire implementation of the reflected signal in the selected time window and the position of the reference point in it, integrate the received samples of the reflected signal in the selected time reception window N-1 times, converting the N-lobed temporal structure of the signal into a single providing resolution of nearby objects of study, use the results of integration to detect objects of study, measure and evaluate the parameters of signals from research objects.

The prototype authors believe that, since integration is a linear method of signal conversion, the use of digital N-1 multiple integration will allow converting a multi-lobe time structure to a single-lobe structure, which, ultimately, will increase the resolution of ultra-wideband radar sensing.

Indeed, integration is a linear signal processing operation. But at the same time, the integrator is a low-pass filter that suppresses high frequencies that carry super-valuable non-coordinate information about the probed object, which is absolutely necessary to increase the resolution of ultra-wideband radar sensing. Sequential digital multiple integration of the received signal sequentially destroys information that can serve to increase the resolution, transforming the signal after such procedures into uninformative.

After passing N-1 integrators, only the constant component of the received signal would pass to the output, but, as mentioned above, there are obviously no components at the zero frequency in both the radiated and received radio signals, so the signal after passing the N-1 integrators is always zero . The output signal after N-1 multiple digital integration is the noise of sampling, quantization and digital processing errors.

In this regard, we should talk about the failure to achieve a technical solution prototype declared as a technical result of the invention to increase the resolution of UWB sensing.

Achievable technical result of the claimed invention is to increase the resolution of UWB radar sensing of nearby objects and increase the efficiency of obtaining the result.

To solve the problem in a method of increasing the resolution of radar ultra-wideband sounding, which consists in emitting an N-lobe probing radio pulse, where N = 2, 3, 4, 5 ..., receive the reflected signal in the selected time window, detect signals from objects of study, measure and evaluate the parameters of the signal reflected from the objects of study, when receiving reflected signals with a controlled delay, set the reception window; additionally enter the processing operations of the received N-l a petal probing radio pulse in K parallel channels, where K / N = 2, 3, 4, ..., in each of the K channels the received reflected signal is multiplied by a signal representing an N-lobe radio pulse identical to the probing delayed in each channel by time relative to the previous channel number by the value of T / (K-1), where T is the duration of the N-lobe probing radio pulse, the result obtained in each of K parallel channels is integrated once, the results are displayed for display on the indicator, by cut To observation followers of several bright marks on the indicator, a conclusion is made about the detection of a group air target and the number of targets in the group is estimated.

The need for K-channel parallel processing of the received N-lobe reflected from the target signal is due not only to the non-invariance of the receiving device to the delay time of the reflected signal, which is a priori unknown, but also to the fact that the device that implements the inventive method has super-resolution in the sensing direction. In this case, the resolution will be determined by the error of combining in time the received signal with the multiplied signal when they are multiplied in the mixer. In this case, the minimum value of the K / N ratio is determined from the theorem of Kotelnikov samples and is equal to 2. But in the interests of increasing the accuracy of measurements and reducing the instrumental error of measurements, the sampling rate should be reduced by increasing the number of parallel processing channels.

Consider the possibility of practical implementation of the proposed method. Figure 2 shows a diagram of a device that implements the inventive method, where:

1. UWB signal generator.

2. Transmitting antenna.

3. The receiving antenna.

4. Attenuator.

5. Ultra-wide low-noise amplifier (SMU).

6. Managed delay line.

7. Multi-tap ultrasonic delay line (MULZ).

8. The computer.

9. K multipliers.

10. K integrators.

The signal from the first output of computer 8 starts the UWB signal generator 1, which is emitted by the transmitting antenna 2. The UWB signal reflected from nearby objects, presumably a group air target, enters the receiving antenna 3. Alternatively, the computer 8 in FIG. 2 the composition of the radar for long-range radar surveillance and target detection, for example, radar 91N6E. This radar solves the problem of detecting moving targets at large ranges from the protected object and does not have the technical capabilities to quickly reveal the composition of the attacking targets, especially targets found at extreme ranges. In this regard, by obtaining information about the detected target from the RLC 91N6E and determining the oblique range to the target, computer 8 has information about the delay between the time of emission of the N-lobe UWB signal by the transmitting antenna 2 and the time of arrival of the signal reflected from the airborne target to the receiving antenna 3. The system for measuring the range to the target programmatically implemented in computer 8 generates a signal from the second output of computer 8 to the second input of the SMU 5, forming a time window and opening the SMU 5 to pass the received UWB signal to the first input of the SMU 5 from the output of the receiving antenna 3. From the third output of computer 8, the time window signal is fed to the second input of the controlled delay line 6, opening it to pass the signal, the first input of which receives a small part of the radiated power of the UWB signal from the gene Ator UWB signal 1 via an attenuator 4. The controlled delay line 6 generates a delay value providing passage of one N-petalled UWB signal in synchronism with the reception signal reflected from a target. MULZ 7 consists of K-1 series-connected elements, each of which provides a delay of T / (K-1), where T is the duration of the N-lobe probing UWB signal, K is the number of parallel processing channels.

The very feature of the received signals, described in sufficient detail above, does not allow the use of classical methods of optimal processing associated with filtering (filtering is invariant by the time of arrival of the reflected signals and allows for single-channel processing). Also, all optimal processing methods associated with heterodyning or multiplication by a complex conjugate function with subsequent integration at an intermediate frequency are absolutely unacceptable. The author believes that the most adequate processing, in which it is not lost, but is used advantageously, in the interest of obtaining the highest possible resolution of radar sensing, is to calculate the autocorrelation function between the received N-lobe UWB signal and the same signal, delayed for a time between the signal his reception.

The use of multi-channel processing of the received signal reflected from the target is explained not only by the a priori uncertainty of the delay of the received signal, but also by the need to calculate the value of the autocorrelation integral for various values of the delays between the signals.

The practical implementation of the proposed method for processing UWB signals is carried out by supplying a signal from the output of the delay control line to the first inputs of the multipliers 9 - to the first input of the multiplier of the first channel - directly, and to the first inputs of the remaining K-1 of the multipliers 9 - from the corresponding MULZ 7 branch the MULZ input 7 is connected to the output of the controlled delay line 6, while simultaneously calculating the autocorrelation integrals in the K channels K: for this, the same input to each of the second inputs K of the multipliers 9 received from the target and coming from the output of the SMU 5 N-flap UWB signal, the signal from the outputs K of the multipliers 9 is fed to the inputs of the integrators. The outputs K of the integrators 10 generates a signal at zero frequency (constant component). The magnitude of this signal corresponds to the magnitude of the autocorrelation integral. The signals from the output K of the integrators 10 enter the computer 8 for display on the indicator (computer screen).

With the exact combination of the received N-lobe reflected signal from the target with the multiplied signal, there will be a significant excess of the signal level at zero frequency at the output of the integrator of one of the channels compared to the other K-1 channels. This will be displayed with a high brightness of the glow of the mark on the indicator (computer screen 8) and a graphic display of the signal level. If the mark is unique, then such a result will allow us to solve the recognition problem - to recognize the detected target as a single one.

In the event that a group target is detected, even if individual N lobes are combined in time in the received radar signal, significant signals will be observed at the outputs of several integrators (according to the number of targets in the group), which will allow to quickly recognize a group target long before traditional narrow-band radars can do this. Of course, mistakes are made in determining the number of goals in the group (due to the shading of some goals in the group by others), but the very fact of identifying a group goal can be carried out with high reliability and extremely quickly, which will allow you to take timely and effective actions to destroy such a goal.

It should be noted that an increase in K / N over several units will not lead to an increase in resolution - it is obvious that the key points for implementing superresolution are primarily the width of the N-lobe signal lobe and the degree of adequacy of the signal processing used.

From the point of view of implementation, it should be noted that all nodes associated with the passage of UWB signals must be implemented using elements that have sufficiently wide bandwidths. Currently, the development of the elemental base to a large extent removes the severity of these requirements. So, back in 2016, GlobalFoundries announced the development of ultra-fast chips commissioned by DARPA, made using 32-nanometer technology and capable of processing input signals with a frequency of up to 30 GHz [4]. Calculations using Fig. 1 a) show that the use of such an elemental base allows us to achieve the spatial dimensions of each of the N-petals of UWB signals of only 5 mm, which is redundant not only for recognizing the number of targets in a group, but also redundant for the technical implementation of signature recognition not not only types of attacking air targets, but also weapons located on their suspensions.

Thus, the proposed method is technically feasible and can increase the resolution of radar ultra-wideband sounding and increase the efficiency of obtaining the result.

Literature

1. Astanin L.Yu., Kostylev A.A. Basics of ultra-wideband radar measurements. - M .: Radio and communications, 1989 .-- 192 p. (analogue);

2. Theoretical foundations of radar. Ed. Shirmana Y.D. - M., "Soviet Radio", 1970, p.132;

3. Patent for the invention RU 2348945 C1 (prototype);

4.https: //www.dailytechinfo.org/military/7748-novye-sverhbystrodeystvuyuschie-chipy-stanut-osnovoy-kommunikacionnyh-sistem-rabotu-kotoryh-budet-nevozmozhno-podavit.html.

Claims (1)

A way to increase the resolution of ultra-wideband radar sensing, which consists in emitting an N-lobe probing radio pulse, where N = 2, 3, 4, 5 ..., receive the reflected signal in the selected time window, detect signals from the objects of study, measure and evaluate the parameters of the signals reflected from the objects of study, when receiving reflected signals with a controlled delay value, a reception window is set, processing operations of the received N-lobe probing radio signal are additionally introduced the pulse in K parallel channels, where K / N = 2, 3, 4, ..., in each of the K channels, the received reflected signal is multiplied by a signal that is identical to the emitted N-lobe probing radio pulse, delayed in each channel in time relative to the previous channel number by the value of T / (K-1), where T is the duration of the N-lobe probing radio pulse, the result obtained in each of the K parallel channels is integrated once, the results are displayed for display on the indicator, according to the observation results Olka bright marks on the display conclude the discovery of a group of air targets and estimate the number of goals in the group.

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