XAI4Extremes: An interpretable machine learning framework for understanding extreme-weather precursors under climate change

• URL: http://arxiv.org/abs/2503.08163v1
• Date: Tue, 11 Mar 2025 08:27:08 GMT
• Title: XAI4Extremes: An interpretable machine learning framework for understanding extreme-weather precursors under climate change
• Authors: Jiawen Wei, Aniruddha Bora, Vivek Oommen, Chenyu Dong, Juntao Yang, Jeff Adie, Chen Chen, Simon See, George Karniadakis, Gianmarco Mengaldo,
• Abstract summary: Extreme weather events are increasing in frequency and intensity due to climate change.<n>While prediction skills are increasing with advances in numerical weather prediction and artificial intelligence tools, extreme weather still present challenges.<n>We propose to use post-hoc interpretability methods to construct relevance weather maps that show the key extreme-weather precursors identified by deep learning models.<n>We then bin these relevant maps into different multi-year time periods to understand the role that climate change is having on these precursors.
• Score: 9.795404493806402
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Extreme weather events are increasing in frequency and intensity due to climate change. This, in turn, is exacting a significant toll in communities worldwide. While prediction skills are increasing with advances in numerical weather prediction and artificial intelligence tools, extreme weather still present challenges. More specifically, identifying the precursors of such extreme weather events and how these precursors may evolve under climate change remain unclear. In this paper, we propose to use post-hoc interpretability methods to construct relevance weather maps that show the key extreme-weather precursors identified by deep learning models. We then compare this machine view with existing domain knowledge to understand whether deep learning models identified patterns in data that may enrich our understanding of extreme-weather precursors. We finally bin these relevant maps into different multi-year time periods to understand the role that climate change is having on these precursors. The experiments are carried out on Indochina heatwaves, but the methodology can be readily extended to other extreme weather events worldwide.

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