Satellite interferometry for mapping surface deformation time series in one, two and three dimensions: A new method illustrated on a slow-moving landslide

Sergey Samsonov; Antoine Dille; Dewitte Olivier; François Kervyn; Nicolas d'Oreye

doi:10.1016/j.enggeo.2019.105471

Satellite interferometry for mapping surface deformation time series in one, two and three dimensions: A new method illustrated on a slow-moving landslide

Sergey Samsonov, Antoine Dille, Dewitte Olivier, François Kervyn, Nicolas d'Oreye

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Abstract

Space-borne Differential Interferometric Synthetic Aperture Radar (DInSAR) has been extensively used in the last two decades to measure ground surface deformation, providing key information for the characterization and understanding of many natural and anthropogenic processes. However, conventional DInSAR technique measures only one component of the surface deformation (i.e. the satellite's line-of-sight (LOS)), causing the interpretation of DInSAR measurements to be challenging and potentially narrowing the understanding of the mechanisms and dynamics of the deformation processes at work. Presently available methods that estimate 3D surface deformation from DInSAR generally operate on individual interferograms and therefore do not produce 3D surface deformation time series. However, the availability of time series is essential for studying surface deformation processes, bringing information on, e.g., temporally and spatially-variable external forcing conditions and characteristics of future deformation patterns. The Multidimensional Small Baseline Subset (MSBAS) method was already able to produce 2D (east and vertical) surface deformation time series from multi-tracks and multi-sensors DInSAR data. Here we propose a novel version of the MSBAS (MSBAS-3D) method that can produce 3D (north, east, and vertical) surface deformation time series from ascending and descending DInSAR data. This new method proposes measuring the surface deformation for processes producing motion parallel to the surface, such as landslides and glacier flows, while conserving the DInSAR accuracy. The ability of MSBAS-3D to capture the full 3D deformation pattern of processes with a surface signature is illustrated for a large, slow-moving, deep-seated landslide, for which long DInSAR and dGNSS time series, as well as ground truth data, are available. Surface deformation is measured over a four-year period using 1D (LOS), 2D and 3D MSBAS methods, and the advantages and limitations of each approach are described. In this case, the novel MSBAS-3D technique produces superior results that greatly simplify interpretation of the processes at work. The MSBAS-3D software can be downloaded from http://insar.ca/.

Original language	English
Article number	105471
Number of pages	13
Journal	Engineering Geology
Volume	266
DOIs	https://doi.org/10.1016/j.enggeo.2019.105471
Publication status	Published - 5 Mar 2020

Bibliographical note

Funding Information:
COSMO-SkyMed images were acquired through RESIST ( SR/00/305 ) and MODUS ( SR/00/358 ) projects ( http://resist.africamuseum.be/ , http://resist.africamuseum.be/MODUS ) funded by the Belgian Federal Science and Policy Office (BELSPO) and the CEOS Landslide Pilot . The images are under an Italian Space Agency (ASI) licence. Special thanks go to Université Officielle de Bukavu, and particularly to the members of the Department of Geology. They made possible to execute fieldwork in the study area, provided crucial help for the dGNSS acquisition campaigns and useful information on landslide occurrences in the area. We credit OpenStreetMap contributors for providing street data. Figures were plotted with GMT, GDAL and GNUPLOT, and statistical analysis was performed with R software. The work of Antoine Dille was funded by the MODUS SR/00/358 projet. The work of Nicolas d'Oreye was funded by the Luxembourg National Research Fund (FNR) under RESIST and SMMIP projects (INTER/STEREOIII/13/05/RESIST/d'Oreye and INTER/MOBILITY/17/11462632/SMMIP/d'Oreye). We deeply thank Elise Monsieurs for her involvement in processing and conducting the dGNSS campaigns.

Funding Information:
COSMO-SkyMed images were acquired through RESIST (SR/00/305) and MODUS (SR/00/358) projects (http://resist.africamuseum.be/, http://resist.africamuseum.be/MODUS) funded by the Belgian Federal Science and Policy Office (BELSPO) and the CEOS Landslide Pilot. The images are under an Italian Space Agency (ASI) licence. Special thanks go to Universit? Officielle de Bukavu, and particularly to the members of the Department of Geology. They made possible to execute fieldwork in the study area, provided crucial help for the dGNSS acquisition campaigns and useful information on landslide occurrences in the area. We credit OpenStreetMap contributors for providing street data. Figures were plotted with GMT, GDAL and GNUPLOT, and statistical analysis was performed with R software. The work of Antoine Dille was funded by the MODUS SR/00/358 projet. The work of Nico?las d'Oreye was funded by the Lux?em?bourg Na?tional Re?search Fund (FNR) un?der RE?SIST and SMMIP pro?jects (INTER/STEREOIII/13/05/RESIST/d'Oreye and INTER/MOBILITY/17/11462632/SMMIP/d'Oreye). We deeply thank Elise Monsieurs for her involvement in processing and conducting the dGNSS campaigns.

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© 2020

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Copyright 2020 Elsevier B.V., All rights reserved.

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title = "Satellite interferometry for mapping surface deformation time series in one, two and three dimensions: A new method illustrated on a slow-moving landslide",

abstract = "Space-borne Differential Interferometric Synthetic Aperture Radar (DInSAR) has been extensively used in the last two decades to measure ground surface deformation, providing key information for the characterization and understanding of many natural and anthropogenic processes. However, conventional DInSAR technique measures only one component of the surface deformation (i.e. the satellite's line-of-sight (LOS)), causing the interpretation of DInSAR measurements to be challenging and potentially narrowing the understanding of the mechanisms and dynamics of the deformation processes at work. Presently available methods that estimate 3D surface deformation from DInSAR generally operate on individual interferograms and therefore do not produce 3D surface deformation time series. However, the availability of time series is essential for studying surface deformation processes, bringing information on, e.g., temporally and spatially-variable external forcing conditions and characteristics of future deformation patterns. The Multidimensional Small Baseline Subset (MSBAS) method was already able to produce 2D (east and vertical) surface deformation time series from multi-tracks and multi-sensors DInSAR data. Here we propose a novel version of the MSBAS (MSBAS-3D) method that can produce 3D (north, east, and vertical) surface deformation time series from ascending and descending DInSAR data. This new method proposes measuring the surface deformation for processes producing motion parallel to the surface, such as landslides and glacier flows, while conserving the DInSAR accuracy. The ability of MSBAS-3D to capture the full 3D deformation pattern of processes with a surface signature is illustrated for a large, slow-moving, deep-seated landslide, for which long DInSAR and dGNSS time series, as well as ground truth data, are available. Surface deformation is measured over a four-year period using 1D (LOS), 2D and 3D MSBAS methods, and the advantages and limitations of each approach are described. In this case, the novel MSBAS-3D technique produces superior results that greatly simplify interpretation of the processes at work. The MSBAS-3D software can be downloaded from http://insar.ca/.",

author = "Sergey Samsonov and Antoine Dille and Dewitte Olivier and Fran{\c c}ois Kervyn and Nicolas d'Oreye",

note = "Funding Information: COSMO-SkyMed images were acquired through RESIST ( SR/00/305 ) and MODUS ( SR/00/358 ) projects ( http://resist.africamuseum.be/ , http://resist.africamuseum.be/MODUS ) funded by the Belgian Federal Science and Policy Office (BELSPO) and the CEOS Landslide Pilot . The images are under an Italian Space Agency (ASI) licence. Special thanks go to Universit{\'e} Officielle de Bukavu, and particularly to the members of the Department of Geology. They made possible to execute fieldwork in the study area, provided crucial help for the dGNSS acquisition campaigns and useful information on landslide occurrences in the area. We credit OpenStreetMap contributors for providing street data. Figures were plotted with GMT, GDAL and GNUPLOT, and statistical analysis was performed with R software. The work of Antoine Dille was funded by the MODUS SR/00/358 projet. The work of Nicolas d'Oreye was funded by the Luxembourg National Research Fund (FNR) under RESIST and SMMIP projects (INTER/STEREOIII/13/05/RESIST/d'Oreye and INTER/MOBILITY/17/11462632/SMMIP/d'Oreye). We deeply thank Elise Monsieurs for her involvement in processing and conducting the dGNSS campaigns. Funding Information: COSMO-SkyMed images were acquired through RESIST (SR/00/305) and MODUS (SR/00/358) projects (http://resist.africamuseum.be/, http://resist.africamuseum.be/MODUS) funded by the Belgian Federal Science and Policy Office (BELSPO) and the CEOS Landslide Pilot. The images are under an Italian Space Agency (ASI) licence. Special thanks go to Universit? Officielle de Bukavu, and particularly to the members of the Department of Geology. They made possible to execute fieldwork in the study area, provided crucial help for the dGNSS acquisition campaigns and useful information on landslide occurrences in the area. We credit OpenStreetMap contributors for providing street data. Figures were plotted with GMT, GDAL and GNUPLOT, and statistical analysis was performed with R software. The work of Antoine Dille was funded by the MODUS SR/00/358 projet. The work of Nico?las d'Oreye was funded by the Lux?em?bourg Na?tional Re?search Fund (FNR) un?der RE?SIST and SMMIP pro?jects (INTER/STEREOIII/13/05/RESIST/d'Oreye and INTER/MOBILITY/17/11462632/SMMIP/d'Oreye). We deeply thank Elise Monsieurs for her involvement in processing and conducting the dGNSS campaigns. Publisher Copyright: {\textcopyright} 2020 Copyright: Copyright 2020 Elsevier B.V., All rights reserved.",

year = "2020",

month = mar,

day = "5",

doi = "10.1016/j.enggeo.2019.105471",

language = "English",

volume = "266",

journal = "Engineering Geology",

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TY - JOUR

T1 - Satellite interferometry for mapping surface deformation time series in one, two and three dimensions: A new method illustrated on a slow-moving landslide

AU - Samsonov, Sergey

AU - Dille, Antoine

AU - Olivier, Dewitte

AU - Kervyn, François

AU - d'Oreye, Nicolas

N1 - Funding Information: COSMO-SkyMed images were acquired through RESIST ( SR/00/305 ) and MODUS ( SR/00/358 ) projects ( http://resist.africamuseum.be/ , http://resist.africamuseum.be/MODUS ) funded by the Belgian Federal Science and Policy Office (BELSPO) and the CEOS Landslide Pilot . The images are under an Italian Space Agency (ASI) licence. Special thanks go to Université Officielle de Bukavu, and particularly to the members of the Department of Geology. They made possible to execute fieldwork in the study area, provided crucial help for the dGNSS acquisition campaigns and useful information on landslide occurrences in the area. We credit OpenStreetMap contributors for providing street data. Figures were plotted with GMT, GDAL and GNUPLOT, and statistical analysis was performed with R software. The work of Antoine Dille was funded by the MODUS SR/00/358 projet. The work of Nicolas d'Oreye was funded by the Luxembourg National Research Fund (FNR) under RESIST and SMMIP projects (INTER/STEREOIII/13/05/RESIST/d'Oreye and INTER/MOBILITY/17/11462632/SMMIP/d'Oreye). We deeply thank Elise Monsieurs for her involvement in processing and conducting the dGNSS campaigns. Funding Information: COSMO-SkyMed images were acquired through RESIST (SR/00/305) and MODUS (SR/00/358) projects (http://resist.africamuseum.be/, http://resist.africamuseum.be/MODUS) funded by the Belgian Federal Science and Policy Office (BELSPO) and the CEOS Landslide Pilot. The images are under an Italian Space Agency (ASI) licence. Special thanks go to Universit? Officielle de Bukavu, and particularly to the members of the Department of Geology. They made possible to execute fieldwork in the study area, provided crucial help for the dGNSS acquisition campaigns and useful information on landslide occurrences in the area. We credit OpenStreetMap contributors for providing street data. Figures were plotted with GMT, GDAL and GNUPLOT, and statistical analysis was performed with R software. The work of Antoine Dille was funded by the MODUS SR/00/358 projet. The work of Nico?las d'Oreye was funded by the Lux?em?bourg Na?tional Re?search Fund (FNR) un?der RE?SIST and SMMIP pro?jects (INTER/STEREOIII/13/05/RESIST/d'Oreye and INTER/MOBILITY/17/11462632/SMMIP/d'Oreye). We deeply thank Elise Monsieurs for her involvement in processing and conducting the dGNSS campaigns. Publisher Copyright: © 2020 Copyright: Copyright 2020 Elsevier B.V., All rights reserved.

PY - 2020/3/5

Y1 - 2020/3/5

N2 - Space-borne Differential Interferometric Synthetic Aperture Radar (DInSAR) has been extensively used in the last two decades to measure ground surface deformation, providing key information for the characterization and understanding of many natural and anthropogenic processes. However, conventional DInSAR technique measures only one component of the surface deformation (i.e. the satellite's line-of-sight (LOS)), causing the interpretation of DInSAR measurements to be challenging and potentially narrowing the understanding of the mechanisms and dynamics of the deformation processes at work. Presently available methods that estimate 3D surface deformation from DInSAR generally operate on individual interferograms and therefore do not produce 3D surface deformation time series. However, the availability of time series is essential for studying surface deformation processes, bringing information on, e.g., temporally and spatially-variable external forcing conditions and characteristics of future deformation patterns. The Multidimensional Small Baseline Subset (MSBAS) method was already able to produce 2D (east and vertical) surface deformation time series from multi-tracks and multi-sensors DInSAR data. Here we propose a novel version of the MSBAS (MSBAS-3D) method that can produce 3D (north, east, and vertical) surface deformation time series from ascending and descending DInSAR data. This new method proposes measuring the surface deformation for processes producing motion parallel to the surface, such as landslides and glacier flows, while conserving the DInSAR accuracy. The ability of MSBAS-3D to capture the full 3D deformation pattern of processes with a surface signature is illustrated for a large, slow-moving, deep-seated landslide, for which long DInSAR and dGNSS time series, as well as ground truth data, are available. Surface deformation is measured over a four-year period using 1D (LOS), 2D and 3D MSBAS methods, and the advantages and limitations of each approach are described. In this case, the novel MSBAS-3D technique produces superior results that greatly simplify interpretation of the processes at work. The MSBAS-3D software can be downloaded from http://insar.ca/.

AB - Space-borne Differential Interferometric Synthetic Aperture Radar (DInSAR) has been extensively used in the last two decades to measure ground surface deformation, providing key information for the characterization and understanding of many natural and anthropogenic processes. However, conventional DInSAR technique measures only one component of the surface deformation (i.e. the satellite's line-of-sight (LOS)), causing the interpretation of DInSAR measurements to be challenging and potentially narrowing the understanding of the mechanisms and dynamics of the deformation processes at work. Presently available methods that estimate 3D surface deformation from DInSAR generally operate on individual interferograms and therefore do not produce 3D surface deformation time series. However, the availability of time series is essential for studying surface deformation processes, bringing information on, e.g., temporally and spatially-variable external forcing conditions and characteristics of future deformation patterns. The Multidimensional Small Baseline Subset (MSBAS) method was already able to produce 2D (east and vertical) surface deformation time series from multi-tracks and multi-sensors DInSAR data. Here we propose a novel version of the MSBAS (MSBAS-3D) method that can produce 3D (north, east, and vertical) surface deformation time series from ascending and descending DInSAR data. This new method proposes measuring the surface deformation for processes producing motion parallel to the surface, such as landslides and glacier flows, while conserving the DInSAR accuracy. The ability of MSBAS-3D to capture the full 3D deformation pattern of processes with a surface signature is illustrated for a large, slow-moving, deep-seated landslide, for which long DInSAR and dGNSS time series, as well as ground truth data, are available. Surface deformation is measured over a four-year period using 1D (LOS), 2D and 3D MSBAS methods, and the advantages and limitations of each approach are described. In this case, the novel MSBAS-3D technique produces superior results that greatly simplify interpretation of the processes at work. The MSBAS-3D software can be downloaded from http://insar.ca/.

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DO - 10.1016/j.enggeo.2019.105471

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JO - Engineering Geology

JF - Engineering Geology

M1 - 105471

ER -

Satellite interferometry for mapping surface deformation time series in one, two and three dimensions: A new method illustrated on a slow-moving landslide

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