RU2624769C1 - Method of side lobe suppression of lfm signal with interference extension of the spectrum - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: signal is generated as a sequence of M LFM pulses, where M is an integer greater than or equal to one, where the carrier frequency of the chirp pulses changes from pulse to pulse with overlapping of the spectra of the individual LFM pulses, emitting a signal, receiving a reflected signal, compressing the received signal by convolution with a reference signal. Before the received signal is compressed, a reference signal is generated by weighting each of the M LFM sequence pulses by two specially selected window functions.

EFFECT: reduction of the level of the side lobes of the compressed linear-frequency-modulated signal with inter-period spreading.

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Description

The invention relates to the field of radar, in particular to radar systems using linearly-frequency-modulated signals, and is intended to suppress the side lobes of a compressed LFM signal with inter-period spread spectrum.

The well-known "Method of suppressing the side lobes of the autocorrelation function of a broadband signal" [RU 2335782, published 10.10.2008, IPC G01S 7/36], including the emission of pulsed phase-domain signals with a change in phase manipulation code from period to period of repetition of probe pulses, the reception of reflected signals and their processing, moreover, in each sensing period, one of two phase-coded manipulated signals is emitted, with the amplitudes of the side lobes of the autocorrelation functions equal modulus, but they have opposite signs, and the main peaks of the autocorrelation functions are equal. When receiving the reflected signals, they are compressed separately for each repetition period of the probe pulses, the results of compression of the reflected signals are delayed with a delay of the first result relative to the second for the sounding period in accordance with the temporary position of phase-coded signals matched to each other.

The disadvantage of this method is the use of a rigidly specified set of phase-coded manipulated signals used with radiation, which are not compatible with the use of chirp signals.

The well-known "Method of suppressing the side lobes of the autocorrelation functions of noise-like signals" [RU 2549163, published 04/20/2015, IPC Н03Н 17/06], in which they carry out consistent filtering of the corresponding signal and form its autocorrelation function (ACF), which is the output of the matched filter. Next, an iterative procedure is implemented, which means that at the first iterative step, the time and amplitude of the most intense side lobes are determined from the initial ACF, based on which the corresponding time weight function is formed, by which the original ACF is multiplied and the frequency spectrum of the received signal is calculated (weighted ACF), which is then divided by the square of the module of the frequency spectrum of the input signal. According to the obtained frequency response, limited to the original frequency band, the corresponding correction filter is synthesized, which is connected in series with the original matched filter. If at the same time the amplitudes of the individual side lobes exceed a predetermined level, then the next iterative step is performed in accordance with the described operations, the result of which is the synthesis of a new physically feasible correction filter, while the output signal at the previous iterative step is used as the ACF to be weighed.

The disadvantage of this method is the complexity of its implementation and the indefinite time of the method, associated with an indefinite number of iterations.

The closest in technical essence is the method of processing the radar signal described in the description of the utility model "On-board radar station" [RU 152358, published 05.27.2015, IPC G01S 13/00]. The airborne radar station contains an antenna, a receiver, a transmitter, a master oscillator, a signal processor, a synchronizer, a control processor, a control and synchronization unit, and a separation and processing unit. The airborne radar station implements a method of inter-periodically expanding the signal spectrum, which consists in generating a series of n narrow-band pulses with a spectral width Δƒ _C at different carrier frequencies ƒ ₀ , ƒ ₁ ... ƒ _n-1 , the carrier frequency changes by a multiple of the step Δƒ between pulses, emission of a pulse train, reception of reflected pulses, synthesis of the total broadband spectrum of a signal of width Δƒ _c∑ = nΔƒ _c , processing of the total signal, including compression of the signal by range, formation of a radar image rage.

The disadvantage of this method is the high level of the side lobes of the received multi-frequency signal that occurs when the signal is compressed and leads to a decrease in the dynamic range of the radar image.

The task of the invention is to expand the dynamic range of the radar image (RLI) formed by the radar station.

The technical result is to reduce the level of the side lobes of the compressed chirp signal with inter-period spread spectrum.

The essence of the invention consists in generating a signal in the form of a sequence of M chirp pulses with a varying carrier frequency, where M is an integer greater than or equal to unity, the radiation of the signal, receiving the reflected signal, compressing the received signal by convolution with the reference signal.

What is new is that the carrier frequency of the chirp pulses varies from pulse to pulse with overlapping spectra of the individual chirp pulses, and before compressing the received signal, a reference signal is generated by weighting each of the M chirp pulses of the sequence with the first window function with a flat central part and smooth fronts at the edges, and the relative width of the fronts is chosen equal to the relative overlap of the spectra of adjacent LFM pulses of the sequence in frequency, and subsequent processing of the sequence of M chirp pulses by a second high-resolution window function divided into M parts of equal duration, with a relative overlap equal to the relative overlap of chirp pulses in frequency, the duration of each of the M parts of the second window function corresponding to the duration of each of the M chirp pulses , by weighting each of the M chirp pulses corresponding to the M part of the second window function.

In FIG. Figure 1 shows a graph of the chirp signal with inter-period spreading of the spectrum at M = 4 (4 pulses) in the time-frequency coordinates.

In FIG. Figure 2 shows a typical oscillogram of the chirp signal with interperiodic spreading of the spectrum at M = 4 (4 pulses) in the time-amplitude coordinates.

In FIG. 3 shows a diagram of the formation of a support function by means of weight windows W ₁ and W ₂ .

In FIG. 4 presents the results of compression of a sequence of 4 chirp pulses with inter-period spreading of the spectrum according to the method of the prototype a), b) and according to the claimed method c), d).

The method of suppressing the side lobes of the chirp signal with inter-period spread spectrum is as follows.

An inter-period spreading LFM signal is described by a mathematical expression

,

,

where T _p is the pulse repetition period, M is their number, as _m (t) is a function that describes a single LFM pulse at the mth carrier frequency:

,

,

where ƒ ₀ is the initial (lower) frequency in the signal, Δƒ is the shift between the carrier frequencies of the chirp pulses, τ _p and Δƒ _p are the duration and deviation of the chirp pulse, P (t) is its rectangular envelope,

The frequency overlap of pulses (Δƒ _p -Δƒ) is selected in the range from 0% to 50% deviation Δƒ _p , based on the requirements for the level of the side lobes and the base Δƒ _p ⋅τ _{r of the} LFM pulses: the lower the required level of the side lobes and the less base, the greater should be the overlap of pulses in frequency. The graph of such a signal at M = 4 (4 pulses) in the time-frequency coordinates is schematically shown in FIG. 1, and its characteristic appearance is in FIG. 2.

The generated sequence of chirp pulses is emitted by a radar station, and then a reflected signal is received.

To compress the received signal, a reference signal is generated with which the convolution will be carried out. For this, each chirp pulse of the original sequence s (t) is sequentially weighted by the window function W ₁ and the corresponding part of the window W ₂ .

The weight window W ₁ has a flat central part and smooth fronts at the edges, where its values fall to zero. In this case, the relative front width is chosen equal to the relative pulse overlap in frequency (Δƒ _p -Δƒ) / Δƒ _p. As an example of the window W _1, we can cite the following function defined on the unit interval x ∈ (0; 1):

,

,

where Φ (⋅) is the error function.

The window function W ₂ consists of M parts, and each part of the window is a fragment of a high-resolution amplitude weighting window (e.g., Hamming, Han, Blackman).

Fragments of the weight window W ₂ are formed as follows: the window W _{2 is} "cut" into M equal parts, and the borders of the fragment when weighing the m-th pulse are selected so that the central part of the pulse of relative width Δƒ / Δƒ _{p is} weighted by the m-th part of the window W ₂ . A diagram of the formation of the support function by means of the weight windows W ₁ and W _{2 is} illustrated in FIG. 3.

After weighing the original chirp signal s (t) with the window functions W ₁ and W ₂ , the received signal is compressed by convolving the received reference signal with the received chirp signal.

In FIG. 4a), b) shows (at different scales on the horizontal axis) the result of compression of the chirp signal with inter-period spreading of the spectrum, consisting of 4 pulses with a base of 1000 without suppression of the side lobes, and in FIG. 4 c) and d) - a similar result when using the claimed method of suppression at 10% overlap of the spectra of chirp pulses in frequency. In FIG. 4 shows a decrease in the level of the near side lobes by 15-20 dB due to the application of the proposed method. This allows you to detect targets with a weak reflected signal, which was below the level of the side lobes of the signal reflected from the target located in the neighboring resolution element. As a result, the dynamic range of radar data is significantly expanded.

Thus, due to the formation of the signal by overlapping the spectra of individual chirp pulses and the formation of the reference signal in a special way, the desired technical result is achieved.

Claims (3)

1. The method of suppressing the side lobes of the LFM signal with inter-periodical spreading of the spectrum, which consists in generating a signal in the form of a sequence of M LFM pulses, where M is an integer greater than or equal to unity, emits a signal, receives a reflected signal, compresses of the received signal by convolution with a reference signal, characterized in that the carrier frequency of the LFM pulses varies from pulse to pulse with overlapping spectra of individual LFM pulses, and before compressing the received signal, a reference signal is generated by by weighting each of the M LFM pulses of the sequence with the first window function with a flat central part and smooth edges at the edges, the relative width of the edges being chosen equal to the relative overlap of the spectra of adjacent LFM pulses of the sequence in frequency, and the subsequent processing of the sequence of M LF pulses of the second high-resolution window function, divided into M parts of equal duration, with relative overlap equal to the relative overlap of the LFM pulses per hour totem, and the duration of each of the M parts of the second window function corresponds to the duration of each of the M LFM pulses by weighting each of the M LFM pulses corresponding to the M part of the second window function. 2. A method for suppressing the side lobes of a compressed sequence of pulses of an LFM signal according to claim 1, characterized in that the overlap of the spectra of adjacent LFM pulses of the sequence is from 0% to 50% of the spectrum width of an individual LFM pulse. 3. A method for suppressing the side lobes of a compressed pulse sequence of the chirp signal according to claim 1, characterized in that the Hamming function is used as the second high-resolution window function.

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