RU2629372C1 - Method of construction of panoramic radar location of object - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: creating a set of matrices of synthesized responses in the system of coordinates of the synthesized area, displaced to each other by a discrete angle, due to a uniform rotation of the object relative to the geometric center of the synthesizing area, form a block of matrices of synthesized responses by converting them to the object's coordinate system, fix the matrix of the panoramic radar image of the object As a result of displaying the maximal values of identical elements of the matrices of the block.

EFFECT: construction of a panoramic radar image of an object while preserving the exact characteristics of measuring the coordinates of the brilliant points of the object.

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Description

The invention relates to the field of research of the radar characteristics of an object and can be used when conducting studies of radar visibility, evaluating the effectiveness of measures to reduce it, and also to obtain initial data for solving problems of identification and recognition of objects.

A known method of constructing a two-dimensional radar invention (RLI) of a rectilinearly flying target with multi-frequency narrow-band sounding [1], based on the emission of pulsed signals, receiving reflected signals and accumulating them during the synthesis interval T _s . The carrier frequency of the probe pulses is changed from pulse to pulse according to a linear law in the frequency range from ƒ ₀ to ƒ ₀ + ΔF in increments of ΔF / 2 ^N , the pulse repetition rate T _{u is} chosen such that the value of T _u 2 ^{N is} an order of magnitude less than the correlation time of the path instabilities of the flight of the target (components 25-100 ms). The accumulation of reflected pulses in a volume of 2 ^N 2 ^{N is} carried out in 2 ^N steps with intervals between steps T _c / 2 ^N , they make a matrix with 2 ^N rows and 2 ^N columns, the elements of which are the amplitudes and phases of the reflected signals. The matrix is subjected to two-dimensional fast Fourier transform (FFT). The resulting two-dimensional spectral matrix of the synthesized responses is converted into a graphic matrix image of the target, for which the level of the first side lobes of the response of the most intense diffuser of the target is determined, this level is taken as a threshold value, the response values of the spectral matrix are compared with it, and if the threshold is exceeded, the corresponding element in the matrix is selected field 2 ^N 2 ^N , and the totality of all selected elements is taken as a radar image of the target.

The method provides the construction of a two-dimensional radar image limited by the synthesis sector ΔΨ (rotation angles of the object relative to the line of sight).

The disadvantage of this method is the narrow band of sensing and receiving radar data with a limited surveillance sector.

The closest technical solution to the claimed method (prototype) is a method of obtaining a two-dimensional radar object in a large range of changes in the effective scattering area (EPR) of local radar targets (RC) using multi-frequency pulsed sounding and synthesizing the antenna aperture [2], including radiation from a radar station (RS) signals a change in carrier frequency from pulse to pulse, measuring its value ƒ (t _{n, m)} at time points t _{n, m,} where n - the number of frequency adjustment step in the floor ce ΔF, m - number cycle frequency adjustment, measurement in the terrestrial reference frame at time instants t _{n, m,} center coordinates radar antenna and the coordinates of synthesizing a selected center on the object, measurement relative to the earth frame of reference viewing angle Ψ (t _{n, m),} the reference system associated with the object with the beginning at the synthesis center, receiving and measuring the complex envelopes of signals Φ ( _{n, m} ) reflected from the object, adjusting their phase to a fixed distance from the center of the radar antenna to the synthesis point, memorizing complex envelopes, neg signals from the object during the synthesis time in the angular sector ΔΨ, the formation of a two-dimensional matrix from them in spatial frequency coordinates and its conversion using the FFT into a two-dimensional matrix of synthesized object responses, determining the threshold value from the level of the first side lobes of the most intense response, comparing the level of synthesized object responses with a threshold for highlighting matrix elements representing a two-dimensional radar image of the object in the sector of viewing angles.

The specified method provides high resolution two-dimensional radar object in accordance with a given frequency band of the probe signal, taking into account the properties of the radio transparency of the object and the sector of viewing angles.

The disadvantage of this method (prototype) is the limited production of two-dimensional radar images of the object, which is due to the sector of viewing angles. Due to the wide range of non-uniformity of the scattering function, the restrictions imposed by the radio transparency of the object, the method does not allow to obtain a panoramic radar image of the object, most often it is a display of several shiny points of the object.

Panoramic object radar means the projection of the scattering function (brilliant points) of an object on the horizontal plane, when the viewing angle changes within 2π, and its intensity is proportional to the gradation of brightness (color) of the image. [3].

The technical result of the proposed method is to build a panoramic radar object, while maintaining the accuracy of the measurement characteristics of the coordinates of the shiny points of the object.

The technical result is achieved by the fact that in the known method, which includes radar signal emission with a change in the carrier frequency from pulse to pulse, measuring it at time points corresponding to the step and frequency tuning cycle, measuring the coordinates of the center of the radar antenna, coordinates of the selected synthesis center on the object, angle observations in the Earth's coordinate system, reception and storage of complex envelopes of signals reflected from an object in the angular sector of synthesis, adjustment of their phase to a fixed distance from the center radar antennas to the synthesis point, the formation of a matrix of complex envelopes of the signal in the coordinates of spatial frequencies, its conversion using a two-dimensional FFT into a matrix of synthesized responses in the coordinate system of the synthesis area, additionally create many matrices of synthesized responses in the coordinate system of the synthesis area, which are offset by a discrete the angle due to the uniform rotation of the object relative to the geometric center of the synthesis area, form a block of synthesis matrices These responses, by converting them to the coordinate system of the object, fix the matrix of the panoramic radar image of the object as the result of displaying the maximum values of the same elements of the block matrices.

A comparative analysis shows that the proposed method differs from the known one in the presence of new actions for the formation of many matrices of synthesized responses and their synthesis into the resulting matrix of a panoramic radar object.

When studying other known solutions in the art, the specified set of features that distinguish the invention from the prototype was not identified, which indicates, according to the applicant, the "novelty" of the claimed invention.

In FIG. 1 shows a diagram of a device for implementing the proposed method, comprising: 1 - radar station; 2 - object; 3 - turntable.

In FIG. 2 is a drawing explaining the formation of a matrix of a two-dimensional panoramic radar image.

In FIG. 3 and FIG. 4 presents two-dimensional radar images of an object of the "transport base" type with viewing angles of 225 ° and 125 °, respectively, obtained during the implementation of the proposed method.

In FIG. 5 presents a panoramic radar image of an object of the type "transport base" obtained during the implementation of the proposed method.

In FIG. 6 is a dimensional drawing of a top view of an object of the type "transport base".

The essence of the proposed method lies in the fact that they create many matrices of synthesized responses in the coordinate system of the synthesis area, which are offset by a discrete angle due to the uniform rotation of the object relative to the geometric center of the synthesis area, form a block of matrices of synthesized responses by converting them to the coordinate system of the object, fix the matrix of the panoramic radar image of the object as a result of displaying the maximum values of the same elements m Tritz block.

Panoramic radar image of an object is a synthesis of the reconstruction of many two-dimensional radar images based on Radon reverse projection algorithms [4]. The basis for constructing a panoramic radar image of an object is the construction of its two-dimensional radar image in the sector of viewing angles, which is performed in accordance with the prototype algorithm.

The construction of a panoramic radar image is supplemented by distinguishing features from the prototype algorithm, in terms of constructing a set of two-dimensional object radar images in the sector of discrete viewing angles ΔΨ≤Ψ≤2π and their synthesis into a panoramic radar.

The algorithm for constructing panoramic radar data includes:

1) The object is evenly rotated through an angle ΔΨ≤Ψ≤2π relative to the geometric center of the synthesis area, FIG. one.

2) Radar signals are emitted with a change in the carrier frequency from pulse to pulse and its measurements ƒ (t _{n, m} ) at time t _{n, m} , where n and m are the numbers of the tuning step and the frequency tuning cycle, respectively.

3) Measure the coordinates of the center of the radar antenna, the coordinates of the selected synthesis center on the object and the observation angle Ψ (t _{n, m} ) in the coordinate system of the synthesis area, FIG. one.

4) A two-dimensional array of complex envelopes of the signals Φ (Ψ, ƒ) reflected from the object is recorded in the sector of change of the observation angle ΔΨ≤Ψ≤2π and the frequency values ƒ (t _{n, m} ) of the signals at time instants corresponding to the n-step and m-cycle its adjustment.

5) There are many arrays of complex envelopes of signals reflected from the object, limited by the synthesis sector ΔΨ and offset by a discrete angle Ψ _s = sδ:

where s = 0, 1, 2 ... is the serial number of the values of the discrete viewing angles (arrays);

δ is the sampling step of the observation angle.

6) The formation of many matrices of complex envelopes of the signals reflected from the object in the coordinates of the spatial frequencies:

where [T _Nz , _Mx ] is the matrix of spatial frequency indices N _z (n, z), M _x (m, x) [5].

7) Correct the phase of the complex envelopes of the signals to a fixed distance R ₀ from the center of the radar antenna to the synthesis point:

where k (R _z / R ₀ ) is the phase correction coefficient of the complex signal envelopes, FIG. one;

R _z is the distance between the center of the radar antenna and the synthesis points on the object;

R ₀ - the distance between the centers of the radar antenna and the turntable.

8) Conversion using the two-dimensional FFT of the complex envelopes of the signals reflected from the object into the synthesized responses:

where F {•} is the operation of a two-dimensional FFT.

A synthesized response is a response of a system that implements a conversion algorithm to the effect of complex envelopes of multi-frequency signals [6].

9) Form a block of matrices of synthesized responses — the transformation of the set of matrices to the coordinate system of the object, FIG. 2:

where L (Ψ _s ) is the linear coordinate transformation operator (Z _s , X _s ) → (Z, X) when the system rotates around the beginning by an angle Ψ _s [7];

10) Form the matrix of a panoramic radar object by displaying the maximum values of the same elements of the block matrices, FIG. 2:

The mapping of the maximum values of the same elements of the block matrices is explained by the fact that the intermediate values of the matrix elements represent an uncorrelated ensemble of random realizations of the scattering function depending on the discrete observation angle Ψ _s , and the range of variation of their levels is contained in the maximum value ΔD _Zs-1 , Z _s-1 ⊂ max _s ⎜D _Zs , X _s ⎜ in the form of halftones (colors) of radar images.

The output of the algorithm is the projection of the maximum values of the scattering function (shiny points) of the object on the horizontal plane, with a change in the viewing angle within 2π, and its intensity is proportional to the gradations of brightness (color) of the radar image.

Using the prototype algorithm ensures the accuracy of the measurement of the coordinates of the bright points of the object, and the algorithm for constructing a panoramic radar image provides the same resolution in orthogonal coordinates and the binding of individual scattering centers on the object to its configuration, while the quality of the panoramic radar image of the object is determined by the sampling step of the observation angle Ψ _s . The proposed method eliminates the disadvantages of the prototype - the limited two-dimensional radar object of the sector of the viewing angle.

The proposed method for constructing a panoramic radar object is industrially applicable, and for its implementation modern radar measuring systems (RIC) with multi-frequency sounding of the signal and synthesis of the antenna aperture can be used. An example implementation of the method using RIC is shown in FIG. 5.

The proposed method allows you to compare the radar image of the object with its configuration, identify structural elements that form brilliant points, solve the problem of recognizing the shape and size of the object, carry out their classification, Fig. 5, FIG. 6.

List of sources used

1. Patent of the Russian F for invention No. 2099743 “A method for constructing a two-dimensional radar image of a rectilinearly flying target in multi-frequency narrow-band sounding”. IPC G01S 13/89, publ. 12/20/1997

2. Patent of the Russian Federation for invention No. 2422851 “A method for obtaining a two-dimensional radar image of an object with multi-frequency pulsed sounding”. IPC G01S 13/89, publ. 06/27/2011

3. Belyaev V.V., Kiryanov O.E., Ponkin V.A. Radar, antenna and radiophysical measurements. Monograph - Voronezh: Publishing and Printing Center "Scientific Book", 2013, pp. 81-105.

4.Http: //ru.Wikipedia,arg/Wiki, 10/06/2014

5. Research methods for the radar characteristics of objects. Monograph ed. S.V. Yagolnikov. - M.: Radio Engineering, 2012, pp. 172-185.

6. Radar with synthesizing aperture of the antenna. V.N. Antipov, V.T. Goriyanov, A.I. Kulin et al. - M.: Radio and Communications, 1988, pp. 8-64.

7.Http: //zhukovsd.blogspot.ru/2010/04/blog-post.html, 10/06/2014

Claims (1)

A method of constructing a panoramic radar image of an object, including the emission of signals from a radar station with a change in the carrier frequency from pulse to pulse, measuring it at times corresponding to the pitch and frequency tuning cycle, measuring the coordinates of the center of the antenna of the radar station, the coordinates of the selected synthesis center on the object, the observation angle in the coordinate system of the area of synthesis, reception and storage of complex envelopes of signals reflected from the object in the angular sector synthesis correction of their phase to a fixed distance from the center of the antenna of the radar station to the synthesis point, the formation of a matrix of complex envelopes of the signal in the coordinates of spatial frequencies, its conversion using the two-dimensional fast Fourier transform into the matrix of synthesized responses in the coordinate system of the synthesis area, characterized in that they create many matrices of synthesized responses in the coordinate system of the synthesis area, offset by a discrete angle, due to the equal measuring the rotation of the object relative to the geometric center of the area of synthesis, form a block of matrices of synthesized responses by converting them to the coordinate system of the object, fix the matrix of a panoramic radar image of the object as the result of displaying the maximum values of the same elements of the matrix of the block.

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