Normalizing flow-based deep variational Bayesian network for seismic multi-hazards and impacts estimation from InSAR imagery
Abstract
Onsite disasters like earthquakes can trigger cascading hazards and impacts, such as landslides and infrastructure damage, leading to catastrophic losses; thus, rapid and accurate estimates are crucial for timely and effective post-disaster responses. Interferometric Synthetic aperture radar (InSAR) data is important in providing high-resolution onsite information for rapid hazard estimation. Most recent methods using InSAR imagery signals predict a single type of hazard and thus often suffer low accuracy due to noisy and complex signals induced by co-located hazards, impacts, and irrelevant environmental changes (e.g., vegetation changes, human activities). We introduce a novel stochastic variational inference with normalizing flows derived to jointly approximate posteriors of multiple unobserved hazards and impacts from noisy InSAR imagery.
Keywords
Cite
@article{arxiv.2310.13805,
title = {Normalizing flow-based deep variational Bayesian network for seismic multi-hazards and impacts estimation from InSAR imagery},
author = {Xuechun Li and Paula M. Burgi and Wei Ma and Hae Young Noh and David J. Wald and Susu Xu},
journal= {arXiv preprint arXiv:2310.13805},
year = {2024}
}
Comments
This paper needs to be reviewed by the USGS