Offline-Online Change Detection for Sentinel-1 InSAR Time Series

Hussain, Ekbal; Novellino, Alessandro; Jordan, Colm; Bateson, Luke

doi:10.3390/rs13091656

Cited by 9 publications

(4 citation statements)

References 36 publications

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“…Concerning satellite SAR, displacement time series are the most advanced product of any multitemporal interferometric processing and provide the temporal pattern of deformation of each MP for each acquisition over the observed period. When supported by other instrumentation and field surveys, visual 114 , semi-automatic 115 and automatic analysis 116 of time series can support the characterization and monitoring of landslide kinematics 117 , zonation of sectors 118 , the identification of post-seismic 119 and rainfall-induced 120 velocity changes, seasonal variations 121 and the monitoring of remedial works performance 122 . Furthermore, the shorter than a week revisiting time of satellites such as Sentinel-1, TerraSAR-X or COSMO-SkyMed makes landslide monitoring at the regional scale feasible with a systematic regularity 123 .…”

Section: Technical Reviewmentioning

confidence: 99%

Landslide detection, monitoring and prediction with remote-sensing techniques

Intrieri

Tofani

Gigli

et al. 2023

Nat Rev Earth Environ

186

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Landslides are widespread occurrences that can become catastrophic when they occur near settlements and infrastructure. Detection, monitoring and prediction are fundamental to managing landslide risks and often rely on remote-sensing techniques (RSTs) that include the observation of Earth from space, laser scanning and ground-based interferometry. In this Technical Review, we describe the use of RSTs in landslide analysis and management. Satellite RSTs are used to detect and measure landslide displacement, providing a synoptic view over various spatiotemporal scales. Ground-based sensors (including ground-based interferometric radar, Doppler radar and lidar) monitor smaller areas, but combine accuracy, high acquisition frequency and configuration flexibility, and are therefore increasingly used in real-time monitoring and early warning of landslides. Each RST has advantages and limitations that depend on the application (detection, monitoring or prediction), the size of the area of concern, the type of landslide, deformation pattern and risks posed by landslide. The integration of various technologies is, therefore, often best. More effective landslide risk management requires greater leveraging of big data, more strategic use of monitoring resources and better communication with residents of landslide-prone areas.Sections improvement in temporal observation frequency is provided by the adoption of virtual constellation of mid-resolution multispectral satellites 29 . Jointly, Landsat-8 and Landsat-9 (a repeat cycle of 8 days) and Sentinel-2a and Sentinel-2b (a repeat cycle of 5 days) provide a global median average revisit interval of 2.3 days 30 .The swath width (or footprint) also varies between sensors, ranging from several kilometres for VHR satellites (about 13 km for World-View-3 and WorldView-4) to 120 km for SPOT-5, 185 km for Landsat-7 and 290 km for Sentinel-2. Ground sampling distance varies depending Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author selfarchiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.

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Section: Technical Reviewmentioning

confidence: 99%

Landslide detection, monitoring and prediction with remote-sensing techniques

Intrieri

Tofani

Gigli

et al. 2023

Nat Rev Earth Environ

186

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“…When combined with near-real time processing of InSAR data these detectors, particularly the gradient change, could be used to detect incipient ground deformation associated. The results of this work were published in [5]. Electronic copy available at: https://ssrn.com/abstract=4286039…”

Section: Improving Acquisition and Processing Of Satellite Insar Data...mentioning

confidence: 99%

Monitoring CO2 Storage Sites Onshore and Offshore using InSAR Data and Strain Sensing Fibre Optics Cables

et al. 2022

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“…These changes have led to an increase in the amount of information that can be extracted from these datasets and have resulted in a more comprehensive understanding of the evolution of the Earth's surface and subsurface processes. However, until a few years ago InSAR interpretation was mainly limited to analysis of the average displacement rates [19], but advances in innovative big data analysis methods change this and enable exploitation of the full displacement time series [20][21][22] In the case of large InSAR datasets, traditional manual analysis is a complex and timeconsuming process and more automated techniques are necessary. Previous work has used a variety of methods to help interpret InSAR time series, ranging from semi-automatic [21,23,24] and automatic statistical approaches [25], to the use of supervised [26,27] and unsupervised [20,28,29] machine learning algorithms.…”

Section: Introductionmentioning

confidence: 99%

A Clustering Approach for the Analysis of InSAR Time Series: Application to the Bandung Basin (Indonesia)

Rygus,

Novellino,

Hussain

et al. 2023

Remote Sensing

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Interferometric Synthetic Aperture (InSAR) time series measurements are widely used to monitor a variety of processes including subsidence, landslides, and volcanic activity. However, interpreting large InSAR datasets can be difficult due to the volume of data generated, requiring sophisticated signal-processing techniques to extract meaningful information. We propose a novel framework for interpreting the large number of ground displacement measurements derived from InSAR time series techniques using a three-step process: (1) dimensionality reduction of the displacement time series from an InSAR data stack; (2) clustering of the reduced dataset; and (3) detecting and quantifying accelerations and decelerations of deforming areas using a change detection method. The displacement rates, spatial variation, and the spatio-temporal nature of displacement accelerations and decelerations are used to investigate the physical behaviour of the deforming ground by linking the timing and location of changes in displacement rates to potential causal and triggering factors. We tested the method over the Bandung Basin in Indonesia using Sentinel-1 data processed with the small baseline subset InSAR time series technique. The results showed widespread subsidence in the central basin with rates up to 18.7 cm/yr. We identified 12 main clusters of subsidence, of which three covering a total area of 22 km2 show accelerating subsidence, four clusters over 52 km2 show a linear trend, and five show decelerating subsidence over an area of 22 km2. This approach provides an objective way to monitor and interpret ground movements, and is a valuable tool for understanding the physical behaviour of large deforming areas.

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Offline-Online Change Detection for Sentinel-1 InSAR Time Series

Cited by 9 publications

References 36 publications

Landslide detection, monitoring and prediction with remote-sensing techniques

Landslide detection, monitoring and prediction with remote-sensing techniques

Monitoring CO2 Storage Sites Onshore and Offshore using InSAR Data and Strain Sensing Fibre Optics Cables

A Clustering Approach for the Analysis of InSAR Time Series: Application to the Bandung Basin (Indonesia)

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