CN117214898A - Wide-scale earth surface deformation refined remote sensing method based on multidimensional electromagnetic information depth fusion - Google Patents

Wide-scale earth surface deformation refined remote sensing method based on multidimensional electromagnetic information depth fusion Download PDF

Info

Publication number
CN117214898A
CN117214898A CN202311482394.4A CN202311482394A CN117214898A CN 117214898 A CN117214898 A CN 117214898A CN 202311482394 A CN202311482394 A CN 202311482394A CN 117214898 A CN117214898 A CN 117214898A
Authority
CN
China
Prior art keywords
deformation
scale
coherence
area
frequency
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
CN202311482394.4A
Other languages
Chinese (zh)
Other versions
CN117214898B (en
Inventor
刘爱芳
葛仕奇
夏犇
李硕
姬亚龙
赵毅轩
花韬
曹兴双
张政川
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
CETC 14 Research Institute
Original Assignee
CETC 14 Research Institute
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by CETC 14 Research Institute filed Critical CETC 14 Research Institute
Priority to CN202311482394.4A priority Critical patent/CN117214898B/en
Publication of CN117214898A publication Critical patent/CN117214898A/en
Application granted granted Critical
Publication of CN117214898B publication Critical patent/CN117214898B/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Landscapes

  • Image Processing (AREA)

Abstract

A wide-scale earth surface deformation refined remote sensing method based on multidimensional electromagnetic information depth fusion obtains high-frequency and low-frequency-band full-polarization differential interference phases and coherence coefficients, identifies a non-coherent area, judges a large-scale deformation area and a small-scale deformation area, calculates earth surface deformation of the large-scale deformation area by using a pixel tracking method based on an amplitude maximum cross-correlation coefficient, divides the small-scale deformation area into a vegetation area and a non-vegetation area based on a high-frequency-band coherence joint constraint criterion, obtains deformation of the deepest penetration position of the vegetation area based on a complex-coherent-coefficient phase maximization separation principle, uses a SquesAR algorithm under a polarization optimal coherence principle as the small-scale earth surface deformation of the vegetation area, calculates deformation differences of adjacent pixels three times, obtains small-scale earth surface deformation results of the non-vegetation area, fuses the large-scale deformation, the small-scale deformation in the vegetation area and the small-scale deformation in the non-vegetation coverage area, and serves as the multi-area wide-scale earth surface deformation of a complex scene.

Description

Wide-scale earth surface deformation refined remote sensing method based on multidimensional electromagnetic information depth fusion
Technical Field
The invention belongs to the technical field of earth surface deformation measurement, and particularly relates to a frequency division interference image processing technology.
Background
The synthetic aperture radar differential interferometry DINSAR technology is a novel remote sensing earth observation means, has the advantages of all-day, all-weather and high-resolution observation, and is applied to the fields of natural disaster monitoring and earth surface subsidence monitoring, such as landslide, earthquake and volcanic eruption research.
Along with the continuous improvement of application requirements, the limitations of the traditional DINSAR technology are gradually highlighted, and based on the traditional DINSAR technology, the technology of PS-DINSAR, SBAS-InSAR and DS-InSAR of distributed target interferometry is provided.
Based on the PS-InSAR technology, 24-scene Sentinel-1A image data in 2019-2020 are used for researching the earth surface subsidence condition of a part of a city, and verifying results and analyzing causes. The 23-scene Sentinel-1A image data of 7 months 2017 to 12 months 2018 are selected in the university of Tibetan 2022, and the deformation characteristics and the trend of landslide disasters in the river basin of a certain county are analyzed by using an SBAS-InSAR technology, so that a ground disaster monitoring and prevention reference is provided. Taking a certain coal mine in the west as an example in the mining university of 2022, based on 52-scene Sentinel-1A image data covering a research area, acquiring surface deformation space-time distribution information caused by mining in the area 2016-2018 by using a DS-InSAR time sequence surface deformation monitoring method, and comparing and analyzing level measured data to verify the reliability of the method.
The deformation characteristics of various ground surfaces are large in difference, the mechanism is complex, such as landslide and debris flow are shown as local large deformation, and the deformation of the urban ground surface subsidence and high-speed rail surface is shown as wide-area micro deformation. With the increase of human activities, landslide and settlement frequently occur, and requirements of wide area, wide scale, high precision, high authenticity and high credibility are provided for deformation monitoring.
The spaceborne or airborne differential interferometry DINSAR technology is based on multiple navigation through acquired data and extracting reference information based on a permanent scattering point network, and is a preferred means for wide area deformation monitoring. Aiming at the surface deformation measurement of complex scenes, the prior differential interferometry DINSAR technology faces the following difficulties:
the measurable deformation scale range is small, the scale and the precision are poor, the complex scene has the surface deformation of multiple scales, the prior art is based on single frequency band measurement, the high frequency band cannot record large deformation information, and the low frequency band sensing tiny deformation precision is limited;
the scattering mechanism of the dense vegetation area is complex, single-frequency single-pole electromagnetic scattering comes from the upper layer in the branches, so that the ground deformation information of the vegetation bottom is difficult to truly reflect, and the ground deformation measurement is unreal;
the stable scattering points are unevenly distributed, so that the monitoring reliability is low, the long-time deformation monitoring has strong dependence on the stable scattering points, the stable scattering points are distributed in a sparse area in space, and the monitoring reliability is obviously reduced.
In summary, a method for finely monitoring the deformation of the surface of the wide scale surface suitable for complex scenes is urgently needed, for example, electromagnetic information utilized by SAR microwave remote sensing has multidimensional information characteristics of frequency, amplitude, phase and polarization.
Disclosure of Invention
In order to solve the technical problems of poor adaptability and single scale of the traditional differential interferometry deformation scene, the invention starts from the mechanism of surface deformation extraction, adopts the technical scheme of wide-scale surface deformation refined remote sensing by multi-dimensional electromagnetic information depth fusion, is based on the high-low frequency full-polarization interferometry synthetic aperture radar technology, flexibly applies various technologies such as pixel tracking, optimal polarization coherence, distributed scatterer differential interferometry, frequency division interferometry and the like, expands the observation dimension, has the technical effect of efficiently acquiring systematic and continuous deformation monitoring information of a complex scene, and effectively improves the measurement precision and reliability.
Step one: and acquiring high-frequency and low-frequency full-polarization SAR images by using a high-frequency and low-frequency full-polarization interference synthetic aperture radar system, and respectively carrying out image registration to acquire high-frequency and low-frequency full-polarization differential interference phases and coherence coefficients.
Step two: and (3) identifying a non-coherent region according to the low-frequency-band coherence coefficient obtained in the step one, judging as a large-scale deformation region by combining SAR amplitude information, and dividing the deformation scale region by using other regions as medium-small-scale deformation regions.
Step three: and (3) calculating the earth surface deformation of the large-scale deformation area determined in the step two by using a pixel tracking method based on the maximum cross correlation coefficient of the amplitude.
Let the coordinates and pixel values of the main image point be (m, n), A m (m, n), the corresponding auxiliary image homonymous point coordinates and pixel values are (m-Deltax, n-Deltay), A respectively s (m-Deltax, n-Deltay), selecting window with (m, n) as center and 5×5 as size, and setting average value of pixels in window as MeanA m (m, n), taking (m-Deltax, n-Deltay) as the center, 21×21 as the size selection window, setting the average value of pixels in the window as Mean A s (m-Deltax, n-Deltay) by the formulaRepresenting normalized cross-correlation coefficient rho (m, n) between coordinates (m, n) and (m-deltax, n-deltay), wherein Σ represents summation, traversing pixel points in a large-scale deformation area, calculating the maximum cross-correlation coefficient, acquiring pixel level registration offset between a main image and an auxiliary image, processing the pixel level registration offset by a cubic spline interpolation method, acquiring sub-pixel level registration offset, calculating offset caused by topography fluctuation by using priori DEM data and track data, removing the offset, acquiring registration offset corresponding to the large-scale deformation, performing geographic coding, converting the registration offset into a deformation corresponding to a real geographic position, and taking the deformation as a large-scale surface deformation.
Step four: and (3) dividing the medium-small-scale deformation area into a vegetation area and a non-vegetation area based on the high-low-frequency-band coherence joint constraint criterion according to the high-low-frequency-band coherence coefficient, the interference phase and the SAR amplitude obtained in the step one.
The low-frequency band coherence of the vegetation area is larger than the high-frequency band, the high-frequency band coherence and the low-frequency band coherence of the non-vegetation area are not different, the high-frequency band coherence coefficient and the low-frequency band coherence coefficient are subjected to homonymous pixel point matching, the difference of threshold constraint coherence coefficients is set, the vegetation area is initially selected, isolated pseudo vegetation points are removed through median filtering, and the real vegetation area is identified.
By Cor L (m, n) represents the coherence coefficient of the low-band pixel point coordinates (m, n), cor X (m, n) represents the coherence coefficient of the high-band pixel point coordinates (m, n), ΔCor (m, n) represents the difference of the coherence coefficients, threshold represents the set Threshold, p (m, n) represents the type of pixel point (m, n), 1 represents the vegetation region, 0 represents the non-vegetation region, and the formula is usedIndicating the high and low frequency band coherence joint constraint criteria.
Step five: based on a principle of phase maximization separation of complex coherent coefficients, scattering phase centers of a vegetation region are separated, phases corresponding to the lowest scattering centers are selected, and deformation of the deepest penetration position of the vegetation region is obtained through differential interference treatment and is used as medium-small scale surface deformation of the vegetation region.
Representing the unit complex vector of the polarized scattering mechanism by omega 12 Representing a non-hermitian complex coherent matrix () H Represents the conjugate transpose of the matrix, j represents the imaginary unit, and the formula is usedAnd calculating a complex coherence coefficient phase value, solving the maximum value, taking the complex coherence coefficient as a complex coherence coefficient with the maximized phase difference, and carrying out differential interference treatment on the interference phase of the center of the lowest scattering phase to obtain the medium-small scale surface deformation of the vegetation region.
Step six: according to low-frequency interference data, using a SqueseAR algorithm under a polarization optimal coherence principle to obtain initial earth surface deformation, calculating deformation difference of adjacent pixels, setting a threshold to select a low-frequency band inapplicable region, according to frequency division interference data, using the SqueseAR algorithm under the polarization optimal coherence principle again to update earth surface deformation, calculating deformation difference of adjacent pixels again, setting the threshold to select the frequency division interference inapplicable region, and according to high-frequency interference data, using the SqueseAR algorithm under the polarization optimal coherence principle again to obtain a medium-and small-scale earth surface deformation result of a non-vegetation region.
The deformation difference of adjacent pixels in the surface deformation is represented by delta R, lambda L Represents the wavelength of the low frequency band lambda X Represents the wavelength of the high frequency band lambda M Represents the equivalent wavelength after the frequency division of the high frequency band, eta represents the conversion coefficient and uses the formula、/>The division principle of the low-frequency band application region, the frequency division interference application region and the high-frequency band application region is respectively represented.
The SqueseAR algorithm under the polarization optimal coherence principle is used for performing PSIO processing on interference data, establishing an optimal coherence criterion according to coherence amplitude information, acquiring an optimal scattering mechanism and highest coherence, performing SquesAR processing, acquiring stable scattering points with uniform distribution and high density, and acquiring high-precision and high-reliability surface deformation.
With omega opt Represents an optimal scattering state vector, T 11 And T 22 Respectively represent the polarization coherence matrix and omega corresponding to two interference images H And T represents an intermediate variable, phi represents phase, gamma opt Representing the optimal complex coherence coefficient by the formula、/>Representing the optimal coherence criterion.
Step seven: and D, fusing the large-scale deformation obtained in the step three, the small-scale deformation in the vegetation area obtained in the step five and the small-scale deformation in the non-vegetation coverage area obtained in the step six, and obtaining the multi-area and wide-scale surface deformation results of the complex scene.
The invention uses high and low frequency fusion wide scale and high precision deformation monitoring, adapts to various types of earth surface deformation monitoring through iterative fusion, and solves the difficult problems of small deformation monitoring scale range, large scale and high precision; the high-frequency polarization interference and the low-frequency polarization interference are used for accurately extracting the surface deformation of the vegetation area, so that the problems of poor electromagnetic scattering penetrability and unrealistic deformation measurement of the vegetation area are solved; the stable scattering points are extracted by using high-frequency polarization and low-frequency polarization optimal coherence, so that the net density of the deformation monitoring scattering points is increased, and the problem of low reliability of deformation monitoring is solved.
Drawings
Fig. 1 is a flow chart of a method.
Detailed Description
The technical scheme of the invention is specifically described below with reference to the method flow shown in fig. 1.
And acquiring high-frequency and low-frequency full-polarization SAR images by using a high-frequency and low-frequency full-polarization interference synthetic aperture radar system, and respectively carrying out image registration to acquire high-frequency and low-frequency full-polarization differential interference phases and coherence coefficients.
And identifying a non-coherent region according to the low-frequency band coherence coefficient, judging the non-coherent region as a large-scale deformation region by combining SAR amplitude information, and dividing the deformation scale region by other regions which are small-scale and medium-scale deformation regions.
And calculating the surface deformation of the large-scale deformation area by using a pixel tracking method based on the maximum cross correlation coefficient of the amplitude.
Let the coordinates and pixel values of the main image point be (m, n), A m (m, n), the corresponding auxiliary image homonymous point coordinates and pixel values are (m-Deltax, n-Deltay), A respectively s (m-Deltax, n-Deltay), centered on (m, n), 5X 5Cun selecting window, setting the mean value of pixels in the window as MeanA m (m, n), taking (m-Deltax, n-Deltay) as the center, 21×21 as the size selection window, setting the average value of pixels in the window as Mean A s (m-Deltax, n-Deltay) by the formulaRepresenting normalized cross-correlation coefficient rho (m, n) between coordinates (m, n) and (m-deltax, n-deltay), wherein Σ represents summation, traversing pixel points in a large-scale deformation area, calculating the maximum cross-correlation coefficient, acquiring pixel level registration offset between a main image and an auxiliary image, processing the pixel level registration offset by a cubic spline interpolation method, acquiring sub-pixel level registration offset, calculating offset caused by topography fluctuation by using priori DEM data and track data, removing the offset, acquiring registration offset corresponding to the large-scale deformation, performing geographic coding, converting the registration offset into a deformation corresponding to a real geographic position, and taking the deformation as a large-scale surface deformation.
And dividing the medium-small scale deformation region into a vegetation region and a non-vegetation region based on the high-low frequency band coherence joint constraint criterion according to the high-low frequency band coherence coefficient, the interference phase and the SAR amplitude.
The low-frequency band coherence of the vegetation area is larger than the high-frequency band, the high-frequency band coherence and the low-frequency band coherence of the non-vegetation area are not different, the high-frequency band coherence coefficient and the low-frequency band coherence coefficient are subjected to homonymous pixel point matching, the difference of threshold constraint coherence coefficients is set, the vegetation area is initially selected, isolated pseudo vegetation points are removed through median filtering, and the real vegetation area is identified.
By Cor L (m, n) represents the coherence coefficient of the low-band pixel point coordinates (m, n), cor X (m, n) represents the coherence coefficient of the high-band pixel point coordinates (m, n), ΔCor (m, n) represents the difference of the coherence coefficients, threshold represents a set Threshold value, for example, 0.18, p (m, n) represents the type of pixel point (m, n), 1 represents the vegetation region, 0 represents the non-vegetation region, and the formula isIndicating the high and low frequency band coherence joint constraint criteria.
Based on a principle of phase maximization separation of complex coherent coefficients, scattering phase centers of a vegetation region are separated, phases corresponding to the lowest scattering centers are selected, and deformation of the deepest penetration position of the vegetation region is obtained through differential interference treatment and is used as medium-small scale surface deformation of the vegetation region.
Representing the unit complex vector of the polarized scattering mechanism by omega 12 Representing a non-hermitian complex coherent matrix () H Represents the conjugate transpose of the matrix, j represents the imaginary unit, and the formula is usedAnd calculating a complex coherence coefficient phase value, solving the maximum value, taking the complex coherence coefficient as a complex coherence coefficient with the maximized phase difference, and carrying out differential interference treatment on the interference phase of the center of the lowest scattering phase to obtain the medium-small scale surface deformation of the vegetation region.
According to low-frequency interference data, using a SqueseAR algorithm under a polarization optimal coherence principle to obtain initial earth surface deformation, calculating deformation difference of adjacent pixels, setting a threshold to select a low-frequency band inapplicable region, according to frequency division interference data, using the SqueseAR algorithm under the polarization optimal coherence principle again to update earth surface deformation, calculating deformation difference of adjacent pixels again, setting the threshold to select the frequency division interference inapplicable region, and according to high-frequency interference data, using the SqueseAR algorithm under the polarization optimal coherence principle again to obtain a medium-and small-scale earth surface deformation result of a non-vegetation region.
The deformation difference of adjacent pixels in the surface deformation is represented by delta R, lambda L Represents the wavelength of the low frequency band lambda X Represents the wavelength of the high frequency band lambda M Represents the equivalent wavelength after the division of the high frequency band, eta represents the conversion coefficient, such as 0.93, and is expressed by the formula、/>The division principle of the low-frequency band application region, the frequency division interference application region and the high-frequency band application region is respectively represented.
The traditional SquesAR algorithm combines a permanent scatterer and a distributed scatterer, the number of observation points of a target area is increased, a high-density deformation field of the target area is obtained, and the obtained observation points are uneven in number distribution and low in point density due to complex scattering characteristics of different types of non-vegetation areas, so that the observation requirements cannot be met.
The SqueseAR algorithm under the polarization optimal coherence principle is used for performing PSIO processing on interference data, establishing an optimal coherence criterion according to coherence amplitude information, acquiring an optimal scattering mechanism and highest coherence, performing SquesAR processing, acquiring stable scattering points with uniform distribution and high density, and acquiring high-precision and high-reliability surface deformation.
With omega opt Represents an optimal scattering state vector, T 11 And T 22 Respectively represent the polarization coherence matrix and omega corresponding to two interference images H And T represents an intermediate variable, phi represents phase, gamma opt Representing the optimal complex coherence coefficient by the formula、/>Representing the optimal coherence criterion.
And fusing large-scale deformation, small-scale deformation in a vegetation area and small-scale deformation in a non-vegetation coverage area to obtain the multi-area and wide-scale surface deformation result of the complex scene.
The foregoing is illustrative of the present invention and is not to be construed as limiting thereof, but rather as being included within the spirit and scope of the present invention.

Claims (8)

1. A wide-scale earth surface deformation refined remote sensing method based on multidimensional electromagnetic information depth fusion is characterized by comprising the following steps:
step one: acquiring high-frequency and low-frequency full-polarization SAR images by using a high-frequency and low-frequency full-polarization interference synthetic aperture radar system, and respectively carrying out image registration to acquire high-frequency and low-frequency full-polarization differential interference phases and coherence coefficients;
step two: according to the low-frequency band coherence coefficient obtained in the first step, a coherence loss region is identified, and a large-scale deformation region is determined by combining SAR amplitude information, and other regions are small-scale and medium-scale deformation regions, so that the deformation scale regions are divided;
step three: calculating the earth surface deformation of the large-scale deformation area determined in the second step by using a pixel tracking method based on the maximum cross correlation coefficient of the amplitude;
step four: dividing a medium-small-scale deformation area into a vegetation area and a non-vegetation area based on a high-low-frequency-band coherence joint constraint criterion according to the high-low-frequency-band coherence coefficient, the interference phase and the SAR amplitude obtained in the first step;
step five: separating scattering phase centers of the vegetation region based on a principle of phase maximization separation of complex coherence coefficients, selecting phases corresponding to the lowest scattering centers, and obtaining deformation of the deepest penetration position of the vegetation region through differential interference treatment to serve as medium-small scale surface deformation of the vegetation region;
step six: according to low-frequency interference data, using a SqueseAR algorithm under a polarization optimal coherence principle to obtain initial earth surface deformation, calculating deformation difference of adjacent pixels, setting a threshold to select a low-frequency band inapplicable region, according to frequency division interference data, using the SqueseAR algorithm under the polarization optimal coherence principle again to update earth surface deformation, calculating deformation difference of adjacent pixels again, setting the threshold to select the frequency division interference inapplicable region, and according to high-frequency interference data, using the SqueseAR algorithm under the polarization optimal coherence principle again to obtain a medium-and small-scale earth surface deformation result of a non-vegetation region;
step seven: and D, fusing the large-scale deformation obtained in the step three, the small-scale deformation in the vegetation area obtained in the step five and the small-scale deformation in the non-vegetation coverage area obtained in the step six, and obtaining the multi-area and wide-scale surface deformation results of the complex scene.
2. The method for refining the remote sensing of the surface deformation of the wide scale based on the depth fusion of the multidimensional electromagnetic information according to claim 1, wherein the third step comprises the following steps: let the coordinates and pixel values of the main image point be (m, n), A m (m, n), the corresponding auxiliary image homonymous point coordinates and pixel values are (m-Deltax, n-Deltay), A respectively s (m-Deltax, n-Deltay), selecting window with (m, n) as center and 5×5 as size, and setting average value of pixels in window as MeanA m (m, n), taking (m-Deltax, n-Deltay) as the center, 21×21 as the size selection window, setting the average value of pixels in the window as Mean A s (m-Deltax, n-Deltay) by the formulaRepresenting normalized cross-correlation coefficient rho (m, n) between coordinates (m, n) and (m-deltax, n-deltay), wherein Σ represents summation, traversing pixel points in a large-scale deformation area, calculating the maximum cross-correlation coefficient, acquiring pixel level registration offset between a main image and an auxiliary image, processing the pixel level registration offset by a cubic spline interpolation method, acquiring sub-pixel level registration offset, calculating offset caused by topography fluctuation by using priori DEM data and track data, removing the offset, acquiring registration offset corresponding to the large-scale deformation, performing geographic coding, converting the registration offset into a deformation corresponding to a real geographic position, and taking the deformation as a large-scale surface deformation.
3. The method for refining the remote sensing of the surface deformation of the wide scale based on the depth fusion of the multidimensional electromagnetic information according to claim 1, wherein the fourth step comprises the following steps: and matching the high-frequency band coherence coefficient and the low-frequency band coherence coefficient with pixel points of the same name, setting a threshold value to restrict the difference of the coherence coefficients, primarily selecting a vegetation area, removing isolated pseudo vegetation points through median filtering, and identifying a real vegetation area.
4. The method for refining the remote sensing of the surface deformation of the wide scale based on the depth fusion of the multidimensional electromagnetic information according to claim 3, wherein the fourth step further comprises: by Cor L (m, n) represents the coherence coefficient of the low-band pixel point coordinates (m, n), cor X (m, n) representsThe coherence coefficient of the high-frequency pixel point coordinates (m, n), deltaCor (m, n) represents the difference of the coherence coefficients, threshold represents the set Threshold, p (m, n) represents the type of the pixel point (m, n), the value of 1 represents the vegetation area, the value of 0 represents the non-vegetation area, and the formula is usedIndicating the high and low frequency band coherence joint constraint criteria.
5. The method for refining the remote sensing of the surface deformation of the wide scale based on the depth fusion of the multidimensional electromagnetic information according to claim 1, wherein the fifth step comprises the following steps: representing the unit complex vector of the polarized scattering mechanism by omega 12 Representing a non-hermitian complex coherent matrix () H Represents the conjugate transpose of the matrix, j represents the imaginary unit, and the formula is usedAnd calculating a complex coherence coefficient phase value, solving the maximum value, taking the complex coherence coefficient as a complex coherence coefficient with the maximized phase difference, and carrying out differential interference treatment on the interference phase of the center of the lowest scattering phase to obtain the medium-small scale surface deformation of the vegetation region.
6. The method for refining the remote sensing of the surface deformation of the wide scale based on the depth fusion of the multidimensional electromagnetic information according to claim 1, wherein the step six comprises the following steps: the deformation difference of adjacent pixels in the surface deformation is represented by delta R, lambda L Represents the wavelength of the low frequency band lambda X Represents the wavelength of the high frequency band lambda M Represents the equivalent wavelength after the frequency division of the high frequency band, eta represents the conversion coefficient and uses the formula、/>、/>Respectively representThe method comprises the steps of dividing a low-frequency band applicable region, a frequency division interference applicable region and a high-frequency band applicable region.
7. The wide-scale earth surface deformation refined remote sensing method based on multidimensional electromagnetic information depth fusion according to claim 6, wherein the SqueeSAR algorithm under the polarization optimal coherence principle comprises the following steps: based on the polarization optimal coherence principle, PSIO processing is carried out on interference data, an optimal coherence criterion is established according to coherence amplitude information, an optimal scattering mechanism and highest coherence are obtained, and SqueseSAR processing is carried out.
8. The wide-scale earth surface deformation refined remote sensing method based on multidimensional electromagnetic information depth fusion according to claim 7, wherein the optimal coherence principle comprises the following steps: with omega opt Represents an optimal scattering state vector, T 11 And T 22 Respectively represent the polarization coherence matrix and omega corresponding to two interference images H And T represents an intermediate variable, phi represents phase, gamma opt Representing the optimal complex coherence coefficient by the formula、/>、/>Representing the optimal coherence criterion.
CN202311482394.4A 2023-11-09 2023-11-09 Wide-scale earth surface deformation refined remote sensing method based on multidimensional electromagnetic information depth fusion Active CN117214898B (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202311482394.4A CN117214898B (en) 2023-11-09 2023-11-09 Wide-scale earth surface deformation refined remote sensing method based on multidimensional electromagnetic information depth fusion

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202311482394.4A CN117214898B (en) 2023-11-09 2023-11-09 Wide-scale earth surface deformation refined remote sensing method based on multidimensional electromagnetic information depth fusion

Publications (2)

Publication Number Publication Date
CN117214898A true CN117214898A (en) 2023-12-12
CN117214898B CN117214898B (en) 2024-01-23

Family

ID=89043005

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202311482394.4A Active CN117214898B (en) 2023-11-09 2023-11-09 Wide-scale earth surface deformation refined remote sensing method based on multidimensional electromagnetic information depth fusion

Country Status (1)

Country Link
CN (1) CN117214898B (en)

Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103675790A (en) * 2013-12-23 2014-03-26 中国国土资源航空物探遥感中心 Method for improving earth surface shape change monitoring precision of InSAR (Interferometric Synthetic Aperture Radar) technology based on high-precision DEM (Digital Elevation Model)
GB201709525D0 (en) * 2017-06-15 2017-08-02 Univ Nottingham Land deformation measurement
CN110673145A (en) * 2019-10-24 2020-01-10 中国地质大学(北京) InSAR (interferometric synthetic Aperture Radar) surface deformation monitoring method and system based on discontinuous coherence
CN110888130A (en) * 2019-10-30 2020-03-17 华东师范大学 Coal mine area ground surface deformation monitoring method based on lifting rail time sequence InSAR
CN113405447A (en) * 2020-05-19 2021-09-17 湖南北斗微芯产业发展有限公司 Track traffic deformation monitoring method, device and equipment integrating InSAR and GNSS
CN114594479A (en) * 2022-05-07 2022-06-07 中国测绘科学研究院 Full scatterer FS-InSAR method and system
CN115343712A (en) * 2022-10-18 2022-11-15 中国电子科技集团公司第十四研究所 High-low frequency polarization interference test system for inversion of vegetation elevation
CN115453520A (en) * 2022-10-26 2022-12-09 中国电子科技集团公司第十四研究所 Surface deformation measurement method and device based on dual-frequency multi-polarization differential interference
CN116449365A (en) * 2022-11-21 2023-07-18 中交基础设施养护集团有限公司 Metro along-line surface two-dimensional deformation field monitoring method based on time sequence InSAR technology

Patent Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103675790A (en) * 2013-12-23 2014-03-26 中国国土资源航空物探遥感中心 Method for improving earth surface shape change monitoring precision of InSAR (Interferometric Synthetic Aperture Radar) technology based on high-precision DEM (Digital Elevation Model)
GB201709525D0 (en) * 2017-06-15 2017-08-02 Univ Nottingham Land deformation measurement
CN110673145A (en) * 2019-10-24 2020-01-10 中国地质大学(北京) InSAR (interferometric synthetic Aperture Radar) surface deformation monitoring method and system based on discontinuous coherence
CN110888130A (en) * 2019-10-30 2020-03-17 华东师范大学 Coal mine area ground surface deformation monitoring method based on lifting rail time sequence InSAR
CN113405447A (en) * 2020-05-19 2021-09-17 湖南北斗微芯产业发展有限公司 Track traffic deformation monitoring method, device and equipment integrating InSAR and GNSS
CN114594479A (en) * 2022-05-07 2022-06-07 中国测绘科学研究院 Full scatterer FS-InSAR method and system
CN115343712A (en) * 2022-10-18 2022-11-15 中国电子科技集团公司第十四研究所 High-low frequency polarization interference test system for inversion of vegetation elevation
CN115453520A (en) * 2022-10-26 2022-12-09 中国电子科技集团公司第十四研究所 Surface deformation measurement method and device based on dual-frequency multi-polarization differential interference
CN116449365A (en) * 2022-11-21 2023-07-18 中交基础设施养护集团有限公司 Metro along-line surface two-dimensional deformation field monitoring method based on time sequence InSAR technology

Non-Patent Citations (6)

* Cited by examiner, † Cited by third party
Title
CHEN, HN: "SURFACE DEFORMATION OF KANGDING AIRPORT, QINGHAI-TIBET PLATEAU, CHINA USING INSAR TECHNIQUES AND MULTI-TEMPORAL SENTINEL-1 DATASETS", IGARSS 2018 - 2018 IEEE INTERNATIONAL GEOSCIENCE AND REMOTE SENSING SYMPOSIUM *
ZHANG, ZK: "A time-series InSAR processing chain for wide-area geohazard identification", NATURAL HAZARDS *
刘媛媛: "不同尺度综合地表形变InSAR时序监测与机理分析", 《中国优秀博士学位论文全文数据库 基础科学辑》 *
李治斌: "基于PS-InSAR技术的珠海市地表沉降监测及预测研究", 《中国优秀硕士学位论文全文数据库 基础科学辑》 *
葛仕奇: "基于模数的干涉相位自适应中值滤波法", 《电子与信息学报》 *
葛大庆;王艳;范景辉;刘圣伟;郭小方;王毅;: "地表形变D-InSAR监测方法及关键问题分析", 国土资源遥感, no. 04 *

Also Published As

Publication number Publication date
CN117214898B (en) 2024-01-23

Similar Documents

Publication Publication Date Title
Zhao et al. Generation of long-term InSAR ground displacement time-series through a novel multi-sensor data merging technique: The case study of the Shanghai coastal area
Ng et al. Assessments of land subsidence in the Gippsland Basin of Australia using ALOS PALSAR data
Joyce et al. Mapping and monitoring geological hazards using optical, LiDAR, and synthetic aperture RADAR image data
Raucoules et al. Use of SAR interferometry for detecting and assessing ground subsidence
Zhang et al. Subsidence monitoring in coal area using time-series InSAR combining persistent scatterers and distributed scatterers
Hu et al. An underground-mining detection system based on DInSAR
Yocky et al. Monitoring Surface Phenomena Created by an Underground Chemical Explosion Using Fully Polarimetric VideoSAR.
Anjasmara et al. Application of time series InSAR (SBAS) method using sentinel-1A data for land subsidence detection in Surabaya city
Dai et al. Applicability analysis of potential landslide identification by InSAR in alpine-canyon terrain—Case study on Yalong River
Haque et al. Time series analysis of subsidence in Dhaka City, Bangladesh using Insar
Borghero Feasibility study of dam deformation monitoring in Northern Sweden using Sentinel1 SAR interferometry
CN117214898B (en) Wide-scale earth surface deformation refined remote sensing method based on multidimensional electromagnetic information depth fusion
Bonano et al. DInSAR for the Monitoring of Cultural Heritage Sites: Differential SAR Interferometry for the Investigation of Deformations Affecting Cultural Heritage Sites: The Case Study of the Ancient Roman City of Pompeii (Italy)
Is et al. Ground deformation monitoring in cultural heritage areas by time series SAR interferometry: The case of ancient Olympia site (Western Greece)
Du et al. Towards a wide-scale land subsidence product in Eastern states of Australia
Ramirez The Application of Interferometric Synthetic Aperture Radar (InSar) on Damaged Area Mapping: The Case of the 2020 Taal Volcano Eruption
Niraj et al. Estimating the period of probable landslide event using advanced D-InSAR technique for time-series deformation study of Kotrupi region
Kalaranjini et al. Landslide investigation using SAR Interferometry on selected regions of Idukki district, Kerala, India
Lira et al. Subsidence and morphologic variations in Mexico city generated by the earthquakes of September 2017
Shankar et al. Investigation of groundwater induced land subsidence in Ludhiana City using InSAR and Sentinel-1 data
Takami Monitoring Artificial Islands Subsidence in North Jakarta Using Persistent and Distributed Scatterers InSAR Analysis
Shao et al. Monitoring Geological Hazards with InSAR
Nonaka et al. Analysis of the Trend of the Deformation around Kanto Region Estimated by Time Series of PALSAR-2 Data
Rao et al. Assessment of geo-coding and height accuracy of the DEM derived from preliminary data sets of X-band SRTM
Zoran Data fusion technique for analysis of Vrancea seismic region, Romania

Legal Events

Date Code Title Description
PB01 Publication
PB01 Publication
SE01 Entry into force of request for substantive examination
SE01 Entry into force of request for substantive examination
GR01 Patent grant
GR01 Patent grant