RU2746038C1 - Method for fractal complexing of multifrequency radar images - Google Patents

Abstract

FIELD: radar and digital image processing.

SUBSTANCE: method of fractal complexing of multifrequency radar images, which consists in the fact that with the help of a multi-band radar station, initial images are obtained and the components are combined, characterized in that after receiving the images, the original images are ranked in descending order of the carrier frequencies or the width of the spectrum of the probing signals on which they were obtained, the base image is determined according to the criterion of the maximum frequency of the probing signal, the scale of the original images is calculated, the section of the scene corresponding to the base image on the remaining images selected, the selected sections of the remaining images are brought to the base image resolution, the dynamic range of the images aligned taking into account the calculated values ​​of their scale, the integration is carried out by formation of a field of fractal dimensions simultaneously for all image areas selected and reduced to a single resolution and dynamic range.

EFFECT: technical result consists in increasing the information content of the image containing the elements of the original images of the same scene, obtained at different frequency ranges.

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Description

The invention relates to radar and the field of digital image processing and can be used to integrate digital radar images of the same scene, obtained in different frequency ranges.

The closest in technical essence to the claimed method (prototype) is a method for integrating digital multispectral images of the earth's surface (US Pat. RF 2520424 Russian Federation: IPC G06T 5/40 / Nikitin O.R., Kislyakov A.N., Shulyat'ev A.A. .; applicant and patentee Federal State Budgetary Educational Institution of Higher Professional Education "Vladimir State University named after Alexander Grigorievich and Nikolai Grigorievich Stoletovs"; filed. 07/11/12; publ. 06/27/14. Bul. No. 18), including obtaining initial images, integration component based on the principle of weighted summation for each pixel, and after obtaining the images, the most informative image is determined by calculating its own entropy of each image, the morphological form of the most informative image is calculated based on the histogram segmentation with a given number of histogram modes, the morphological the projections of the remaining images onto the shape of the most informative image, and the complexation is carried out by summing the brightness of the pixels of the most informative image, which is taken as the base image, and the projections of the remaining images onto the shape of this image.

The main disadvantage of the prototype method is the distortion or loss of some elements of the original images as a result of calculating morphological projections of images onto the form of the most informative image (see, for example, R. Gonzalez, R. Woods, S. Eddins. Digital image processing in MATLAB. M. : Technosphere, 2006. 616 pp.), Which, for example, in the case of loss of "shiny points" on radar images causes a decrease in the information content of the image containing elements of the original images of the same scene, obtained in different frequency ranges. In addition, the determination of the most informative image according to the criterion of the maximum intrinsic entropy of the image can lead to an error in choosing the most informative image, since in real conditions of the operation of radar systems destabilizing factors of various nature cause a decrease in resolution and distortion in radar images (see, for example, Dudnik P I.I., Kondratenkov G.S., Tatarsky B.G., Ilchuk A.R., Gerasimov A.A.Aircraft radar complexes and systems.A textbook for listeners and cadets of the Air Force Universities / Edited by P.I.Dudnik. M .: VVIA, 2006. 1112 p.), Which leads to a significant increase in the entropy of the radar image, and, ultimately, also leads to a decrease in the information content of the image.

The technical result of the invention is to increase the information content of an image containing elements of the original images of the same scene, obtained simultaneously in different frequency ranges, by ranking the images in descending order of carrier frequencies or the width of the probe signal spectrum, determining the base image by the criterion of maximum frequency or width the spectrum of the probing signal, calculating the scale of the original images, highlighting a section of the scene corresponding to the base image on the remaining images, bringing the selected sections of the remaining images to the resolution of the base image, leveling the dynamic range of the original images taking into account their scales and forming a field of fractal dimensions calculated simultaneously for all images.

The specified technical result is achieved by the fact that in the known method of complexing digital multispectral images of the earth's surface, including obtaining initial images and combining components, according to the invention, after obtaining the images, the initial images are ranked in descending order of the carrier frequencies or the width of the spectrum of the probing signals on which they were obtained, the base image is determined according to the criterion of the maximum frequency of the probing signal, the scale of the original images is calculated, the scene area corresponding to the base image is selected in the remaining images, the selected areas of the remaining images are brought to the base image resolution, the dynamic range of the images is equalized taking into account the calculated values of their scale, the integration is carried out by forming fields of fractal dimensions calculated by the coverage method (see, for example, Potapov A.A.Fractals in radiophysics and radar: Sampling topology. op. M .: Universitetskaya kniga, 2005.848 p.) Simultaneously for all selected and reduced to a single resolution and dynamic range image areas.

Due to this, there is an increase in the information content of an image containing elements of the original images of the same scene, obtained simultaneously in different frequency ranges.

,

, динамическим диапазоном и зоной обзора, обусловленной интервалом накопления (синтезирования) зондирующего сигнала

, полученные радиолокационные изображения ранжируют в порядке убывания значений несущей частоты

,

, или ширины спектра

зондирующих сигналов, с помощью которых они получены, радиолокационное изображение, полученное на максимальной частоте или при максимальной ширине спектра зондирующего сигнала из всех Q имеющихся на носителе диапазонов частот электромагнитных волн, считают наиболее информативным и принимают за базовое изображение z размером M×N пикселей, вычисляют масштаб

каждого исходного n-го изображения согласно выражению:The essence of the invention lies in the fact that using a multi-band radar with a synthetic aperture antenna (MD RSA) with Q channels or Q RSA operating at different carrier frequencies, with different spectral widths of sounding signals and placed on the same carrier, receive radar images (RLI ) of the underlying surface, as shown in FIG. 1, differing in resolution

,

, dynamic range and field of view due to the interval of accumulation (synthesis) of the probing signal

, the obtained radar images are ranked in descending order of carrier frequency values

,

, or the spectrum width

of the probing signals with which they were obtained, the radar image obtained at the maximum frequency or at the maximum width of the probe signal spectrum out of all Q available on the carrier frequency ranges of electromagnetic waves is considered the most informative and is taken as the base image z with a size of M × N pixels, calculate scale

of each original n-th image according to the expression:

,

,

– операция округления к большему, n – порядковый номер ранжированного изображения,

– число элементов изображения, соответствующих линейному размеру l₀ некоторого эталонного объекта, с – абсолютная величина скорости распространения электромагнитных волн в вакууме, относительно середины интервалов накопления зондирующих сигналов

,

, выделяют на остальных изображениях участок сцены, соответствующий базовому изображению, приводят выделенные участки остальных изображений к разрешению базового изображения M×N пикселей, выравнивают динамический диапазон исходных изображений, как показано на фиг. 2, например, путем нормировки с учетом масштабов

, например, согласно выражению:Where

- operation of rounding up, n is the ordinal number of the ranged image,

Is the number of image elements corresponding to the linear size l _{0 of a} certain reference object, s is the absolute value of the propagation velocity of electromagnetic waves in vacuum, relative to the middle of the intervals of accumulation of probing signals

,

, a section of the scene corresponding to the base image is selected in the remaining images, the selected sections of the remaining images are brought to a resolution of the base image of M × N pixels, the dynamic range of the original images is aligned, as shown in FIG. 2, for example, by normalizing taking into account the scales

, for example, according to the expression:

,

,

– множество значений яркости элементов преобразованного n-го изображения с учетом масштаба, z_n – множество значений яркости элементов исходного n-го изображения, min(z_n) и max(z_n) – минимальное и максимальное значения яркости исходного n-го изображения соответственно, комплексирование проводят путем формирования поля фрактальных размерностей

,

,

, для этого в скользящем окне размером W×W, где W – нечетное целое число, рассчитывают локальную мультифрактальную размерность L_q (см., например, Yong Xia, Dagan Feng, Rongchun Zhao Morphology-Based Multifractal Estimation for Texture Segmentation // IEEE Transactions on Image Processing, 2006. Vol. 15. No. 3) согласно выражению:Where

- the set of brightness values of the elements of the transformed n-th image, taking into account the scale, z _n is the set of brightness values of the elements of the original n-th image, min (z _n ) and max (z _n ) are the minimum and maximum brightness values of the original n-th image, respectively , complexation is carried out by forming a field of fractal dimensions

,

,

, for this, in a sliding window of size W × W, where W is an odd integer, the local multifractal dimension L _{q is} calculated (see, for example, Yong Xia, Dagan Feng, Rongchun Zhao Morphology-Based Multifractal Estimation for Texture Segmentation // IEEE Transactions on Image Processing, 2006. Vol. 15. No. 3) according to the expression:

,

,

локальная мультифрактальная размерность соответствует фрактальной размерности, при

выявляются мультифрактальные свойства, которые также возможно использовать в изобретении для повышения информативности,

,

,

– масштаб базового изображения z,

, вычисленное значение

каждого центрального элемента скользящего окна запоминают в соответствующем элементе двумерной матрицы

,

,

, а в случае

– в соответствующем элементе трехмерной матрицы

, содержащей элементы исходных радиолокационных изображений одной и той же сцены, полученных одновременно в различных частотных диапазонах. where q is the order of the scaling moment, for

the local multifractal dimension corresponds to the fractal dimension, at

reveals multifractal properties, which can also be used in the invention to increase information content,

,

,

- the scale of the base image z,

, calculated value

each central element of the sliding window is stored in the corresponding element of the two-dimensional matrix

,

,

, and in the case

- in the corresponding element of the three-dimensional matrix

containing elements of the original radar images of the same scene, obtained simultaneously in different frequency ranges.

The essence of the invention is illustrated in FIG. 3.

,

или ширины спектра

зондирующих сигналов, с помощью которых они получены, определения наиболее информативного (базового) изображения z и вычисления масштаба

исходных изображений, далее на остальных изображениях проводится процедура 2 выделения участка сцены базового изображения относительно середины интервалов накопления зондирующих сигналов (

,…,

,…,

), а также процедура 3 приведения выделенных участков изображений к разрешению базового изображения M×N пикселей, затем проводится процедура 4 выравнивания динамического диапазона всех изображений, в том числе и базового, например, путем нормировки с учетом вычисленных масштабов

, преобразованные таким образом изображения подвергаются процедуре комплексирования 5, основанной на формировании с помощью скользящего окна W×W двумерного или трехмерного поля фрактальных размерностей D. After obtaining the original two-dimensional digital halftone images (z ₁ , ..., z _n , ..., z _Q ) and the corresponding values of the carrier frequencies (f ₀₁ , ..., f _0n , ..., f _0Q ) or the spectrum width (Δf ₁ , ..., Δf _n , ..., Δf _Q ) of the probing signals, the procedure of 1 ranking is carried out in descending order of the values of the carrier frequency

,

or spectrum width

probing signals with which they are obtained, determining the most informative (base) image z and calculating the scale

of the original images, then on the remaining images, procedure 2 is performed for selecting a section of the base image scene relative to the middle of the intervals of accumulation of probe signals (

, ...,

, ...,

), as well as procedure 3 for bringing the selected areas of images to the resolution of the base image M × N pixels, then procedure 4 is performed to align the dynamic range of all images, including the base one, for example, by normalizing taking into account the calculated scales

, the images transformed in this way are subjected to the complexing procedure 5 based on the formation of a two-dimensional or three-dimensional field of fractal dimensions D using a sliding window W × W.

Thus, an increase in information content is achieved by ranking the images in descending order of the carrier frequencies or the width of the spectrum of the probing signals, determining the base image by the criterion of the maximum frequency or the width of the probe signal spectrum, calculating the scale of the original images, highlighting the scene section corresponding to the base one in the remaining images. reduction of the selected areas of the remaining images to the resolution of the base image, alignment of the dynamic range of the original images, taking into account their scales and the formation of a fractal dimension field containing information about the scene area at different measurement scales due to the frequency ranges of electromagnetic waves.

The proposed technical solution is practically applicable, since elements widely used in the field of electronics, electrical engineering and digital image processing can be used for its implementation.

Claims (1)

The method of fractal complexing of multifrequency radar images, which consists in the fact that using a multi-band synthetic aperture radar (RSA) or several SARs operating at different carrier frequencies, with different widths of the spectrum of probing signals and placed on the same carrier, obtain the original images and complex the components, characterized in that after obtaining the images, the original images are ranked in descending order of the carrier frequencies or the width of the spectrum of the probing signals on which they were obtained, the base image is determined by the criterion of the maximum frequency of the probing signal, the scale of the original images is calculated, and the remaining images are extracted the area of the scene corresponding to the base image, the selected areas of the remaining images are brought to the resolution of the base image, the dynamic range of the images is equalized taking into account the calculated values of their scale, the integration is carried out by We form a field of fractal dimensions simultaneously for all selected and reduced to a single resolution and dynamic range image areas.

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