InSAR measurement of the deformation around Siling Co Lake: Inferences on the lower crust viscosity in central Tibet

Doin, Marie‐Pierre; Twardzik, Cédric; Ducret, Gabriel; Lasserre, Cécile; Guillaso, Stéphane; Sun, Jianbao

doi:10.1002/2014jb011768

Cited by 64 publications

(103 citation statements)

References 74 publications

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“…However, we decide to not use this correction because we noticed that for numerous corrected interferograms, the fringe gradient was not significantly decreased and sometimes even increased because of inaccuracy of ERA‐Interim model. Instead, we estimate, on each wrapped interferogram, an empirical relation between the wrapped phase and the elevation (e.g., Doin et al, ; Grandin et al, ). To do that, we begin to search the local linear ratio in subwindows (15 km

\times

15 km) between the phase and the elevation.…”

Section: Insar Data and Processingmentioning

confidence: 99%

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Independent Component Analysis and Parametric Approach for Source Separation in InSAR Time Series at Regional Scale: Application to the 2017–2018 Slow Slip Event in Guerrero (Mexico)

et al. 2020

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Separating different sources of signal in Interferometric Synthetic Aperture Radar (InSAR) studies over large areas is challenging, especially between the long‐wavelength changes of atmospheric conditions and tectonic deformations, both correlated to elevation. In this study, we focus on the 2017–2018 slow slip event (SSE) in the Guerrero state (Mexico) where (1) the permanent GPS network has a low spatial density (less than 30 stations in an area of 300 × 300 km) with uneven distribution; (2) the tropospheric phase delays can be as high as 20 cm of apparent ground displacements, with a complex temporal evolution; (3) the tested global weather models fail to correct interferograms with enough accuracy (with residual tropospheric signal higher than the tectonic signal); and (4) the surface displacement caused by the seismic cycle shows complex interactions between seismic sequences and aseismic events. To extract the SSE signal from Sentinel‐1 InSAR time series, we test two different approaches. The first (parametric method) consists of a least squares linear inversion, imposing a functional form for each deformation or atmospheric component. The second uses independent component analysis of the InSAR time series. We obtain time series maps of surface displacements along the radar line of sight associated with the SSE and validate these results with a comparison to GPS. Combining those two approaches, we propose a method to separate atmospheric delays and tectonic deformation on time series data not corrected from atmospheric delays. From the extracted ground deformation maps, we propose a first‐order slip inversion model at the subduction interface during this SSE.

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\times

15 km) between the phase and the elevation.…”

Section: Insar Data and Processingmentioning

confidence: 99%

“…We construct a phase time series using the New Small Baselines Subset method (Doin et al, ; López‐Quiroz et al, ) relative to the first date.

ϕ_{i} = ϕ_{d e f} + A P S + ϕ_{e r r o r}

…”

Section: Insar Data and Processingmentioning

confidence: 99%

Independent Component Analysis and Parametric Approach for Source Separation in InSAR Time Series at Regional Scale: Application to the 2017–2018 Slow Slip Event in Guerrero (Mexico)

et al. 2020

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“…The NSBAS method aims at reconstructing the phase at each acquisition with the simultaneous estimation of a modeled phase history, combining both methods previously described [López-Quiroz et al, 2009;Jolivet et al, 2012;Doin et al, 2015;Daout et al, 2017]. The addition of a set of function dictionary to adjust to the phase evolution allows to link temporally disconnected subsets in the case of low coherence.…”

Section: Three Time Series Analysis Formulationmentioning

confidence: 99%

A Multipixel Time Series Analysis Method Accounting for Ground Motion, Atmospheric Noise, and Orbital Errors

Jolivet

Simons

2018

Geophysical Research Letters

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Interferometric synthetic aperture radar time series methods aim to reconstruct time‐dependent ground displacements over large areas from sets of interferograms in order to detect transient, periodic, or small‐amplitude deformation. Because of computational limitations, most existing methods consider each pixel independently, ignoring important spatial covariances between observations. We describe a framework to reconstruct time series of ground deformation while considering all pixels simultaneously, allowing us to account for spatial covariances, imprecise orbits, and residual atmospheric perturbations. We describe spatial covariances by an exponential decay function dependent of pixel‐to‐pixel distance. We approximate the impact of imprecise orbit information and residual long‐wavelength atmosphere as a low‐order polynomial function. Tests on synthetic data illustrate the importance of incorporating full covariances between pixels in order to avoid biased parameter reconstruction. An example of application to the northern Chilean subduction zone highlights the potential of this method.

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“…To avoid unwrapping issues due to these fringes, we chose to mask them. Unwrapping was performed in 2-D with the NSBAS chain using a method similar than in Doin et al [2015]. The unwrapped interferograms were then systematically visually checked.…”

Section: Interferometric Synthetic Aperture Radar (Insar) Processingmentioning

confidence: 99%

Spatial and temporal variations in creep rate along the El Pilar fault at the Caribbean‐South American plate boundary (Venezuela), from InSAR

et al. 2016

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In eastern Venezuela, the Caribbean‐South American plate boundary follows the El Pilar fault system. Previous studies based on three GPS campaigns (2003–2005–2013) demonstrated that the El Pilar fault accommodates the whole relative displacement between the two tectonic plates (20 mm/yr) and proposed that 50–60% of the slip is aseismic. In order to quantify the possible variations of the aseismic creep in time and space, we conducted an interferometric synthetic aperture radar (InSAR) time series analysis, using the (NSBAS) New Small BAseline Subset method, on 18 images from the Advanced Land Observing Satellite (ALOS‐1) satellite spanning the 2007–2011 period. During this 3.5 year period, InSAR observations show that aseismic slip decreases eastward along the fault: the creep rate of the western segment reaches 25.3 ± 9.4 mm/yr on average, compared to 13.4 ± 6.9 mm/yr on average for the eastern segment. This is interpreted, through slip distribution models, as being related to coupled and uncoupled areas between the surface and ~ 20 km in depth. InSAR observations also show significant temporal creep rate variations (accelerations) during the considered time span along the western segment. The transient behavior of the creep is not consistent with typical postseismic afterslip following the 1997 Ms 6.8 earthquake. The creep is thus interpreted as persistent aseismic slip during an interseismic period, which has a pulse‐ or transient‐like behavior.

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InSAR measurement of the deformation around Siling Co Lake: Inferences on the lower crust viscosity in central Tibet

Cited by 64 publications

References 74 publications

Independent Component Analysis and Parametric Approach for Source Separation in InSAR Time Series at Regional Scale: Application to the 2017–2018 Slow Slip Event in Guerrero (Mexico)

Independent Component Analysis and Parametric Approach for Source Separation in InSAR Time Series at Regional Scale: Application to the 2017–2018 Slow Slip Event in Guerrero (Mexico)

A Multipixel Time Series Analysis Method Accounting for Ground Motion, Atmospheric Noise, and Orbital Errors

Spatial and temporal variations in creep rate along the El Pilar fault at the Caribbean‐South American plate boundary (Venezuela), from InSAR

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