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Deep Learning-Based Coseismic Deformation Estimation From InSAR Interferograms

Chuanhua ZhuMinistry of Natural Resources (MNR) Key Laboratory for Geo-Environmental Monitoring of Great Bay Area, the Guangdong Key Laboratory of Urban Informatics, and the Shenzhen Key Laboratory of Spatial Smart Sensing and Services, School of Architecture and Urban Planning, Shenzhen University, Shenzhen, ChinaXue LiMinistry of Natural Resources (MNR) Key Laboratory for Geo-Environmental Monitoring of Great Bay Area, the Guangdong Key Laboratory of Urban Informatics, and the Shenzhen Key Laboratory of Spatial Smart Sensing and Services, School of Architecture and Urban Planning, Shenzhen University, Shenzhen, ChinaChisheng WangMinistry of Natural Resources (MNR) Key Laboratory for Geo-Environmental Monitoring of Great Bay Area, the Guangdong Key Laboratory of Urban Informatics, and the Shenzhen Key Laboratory of Spatial Smart Sensing and Services, School of Architecture and Urban Planning, Shenzhen University, Shenzhen, ChinaBochen ZhangCollege of Civil and Transportation Engineering, Shenzhen University, Shenzhen, ChinaBaogang LiSchool of Geoscience, China University of Petroleum (East China), Qingdao, China
2024en
ABI

Аннотация

Accurate automated extraction of coseismic deformation from Synthetic Aperture Radar (SAR) data can be challenging owing to interference from inherent atmospheric noise. Particularly, the limited displacement of small-to-moderate earthquakes (Mw<6.5) can easily be obscured by phase errors and/or noise. To address this issue, we developed an autoencoder model based on a deep learning framework (i.e., Pytorch) to automate the accurate extraction of coseismic displacement from Interferometric SAR (InSAR) interferograms. We constructed a training dataset using simulated interferograms. Our trained model performed well for interferograms with real noise. When applied to worldwide real earthquakes of various rupture styles, the model produced clear coseismic displacement with less noise and a better fit to coseismic fault models compared to the differential InSAR method without noise correction. Additionally, it achieved co-seismic deformation similar to popular InSAR time series and GNSS methods. The approach will enhance the proceduralization and popularization of InSAR applications in earthquake monitoring, providing improved constraints on the kinematic characteristics of earthquakes.

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