Abstract
Sentinel-1 mission with its wide spatial coverage (250 km), short revisit time (6 days), and rapid data dissemination opened new perspectives for large-scale interferometric synthetic aperture radar (InSAR) analysis. However, the spatiotemporal changes in troposphere limits the accuracy of InSAR measurements for operational deformation monitoring at a wide scale. Due to the coarse node spacing of the tropospheric models, like ERA-Interim and other external data like Global Navigation Satellite System (GNSS), the interpolation techniques are not able to well replicate the localized and turbulent tropospheric effects. In this study, we propose a new technique based on machine learning (ML) Gaussian processes (GP) regression approach using the combination of small-baseline interferograms and GNSS derived zenith total delay (ZTD) values to mitigate phase delay caused by troposphere in interferometric observations. By applying the ML technique over 12 Sentinel-1 images acquired between May–October 2016 along a track over Norway, the root mean square error (RMSE) reduces on average by 83% compared to 50% reduction obtained by using ERA-Interim model.
Highlights
The fast, accurate, and cost-effective detection and mapping of ground instabilities at regional to national scales can be extremely helpful for civil protection authorities
We focus on Norway, and use the unwrapped differential phase derived by large-scale interferograms of Sentinel-1 with short temporal baselines as primary input variables and the global navigation satellite system (GNSS) stations location as secondary input variables for the model training
Initial topographic phase components are subtracted from the small-baseline interferograms using a re-sampled digital elevation model (DEM) at 90m pixel spacing provided by the Norwegian Mapping Authority (NMA)
Summary
The fast, accurate, and cost-effective detection and mapping of ground instabilities at regional to national scales can be extremely helpful for civil protection authorities. It is expected that these methods are limited to map the effect of turbulent mixing To overcome these problems, we implement a new method for tropospheric correction of large-scale Sentinel-1 interferograms based on a machine learning (ML) approach, which exploits short-interval interferograms and ZTD values at GNSS stations. We evaluate the tropospheric corrections results using different methods and discuss the results in terms of the performance of the applied techniques
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