Near real-time spatial prediction of earthquake-induced landslides: A novel interpretable self-supervised learning method

Near real-time spatial prediction of earthquake-induced landslides (EQILs) can rapidly forecast the occurrence position of widespread landslides just after a violent earthquake; thus, EQIL prediction is very crucial to the 72-hour 'golden window' for survivors. This work focuses on a serie...

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Bibliographic Details
Published inInternational journal of digital earth Vol. 16; no. 1; pp. 1885 - 1906
Main Authors Wang, Xuewen, Wang, Xianmin, Zhang, Xinlong, Wang, Lizhe, Guo, Haixiang, Li, Dongdong
Format Journal Article
LanguageEnglish
Published Abingdon Taylor & Francis 31.12.2023
Taylor & Francis Ltd
Taylor & Francis Group
Subjects
Coseismic landslide
Deep learning
Earthquake prediction
Earthquakes
False alarms
interpretable artificial intelligence
Landslides
Landslides & mudslides
Machine learning
Modules
near real-time
Real time
Seismic activity
Seismic response
Self-supervised learning
Spatial distribution
spatial distribution prediction
Survival
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Summary:Near real-time spatial prediction of earthquake-induced landslides (EQILs) can rapidly forecast the occurrence position of widespread landslides just after a violent earthquake; thus, EQIL prediction is very crucial to the 72-hour 'golden window' for survivors. This work focuses on a series of earthquake events from 2008 to 2022 occurring in the Tibetan Plateau, a famous seismically-active zone, and proposes a novel interpretable self-supervised learning (ISeL) method for the near real-time spatial prediction of EQILs. This new method innovatively introduces swap noise at the unsupervised mechanism, which can improve the generalization performance and transferability of the model, and can effectively reduce false alarm and improve accuracy through supervised fine-tuning. An interpretable module is built based on a self-attention mechanism to reveal the importance and contribution of various influencing factors to EQIL spatial distribution. Experimental results demonstrate that the ISeL model is superior to the excellent state-of-the-art machine learning and deep learning methods. Furthermore, according to the interpretable module in the ISeL method, the critical controlling and triggering factors are revealed. The ISeL method can also be applied in other earthquake-frequent regions worldwide because of its good generalization and transferability.
ISSN:1753-8947
1753-8955
DOI:10.1080/17538947.2023.2216029