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Main Authors: Gan, Yanhai, Chen, Yipeng, Li, Ning, Liu, Xingguo, Dong, Junyu, Chen, Xianyao
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.02050
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author Gan, Yanhai
Chen, Yipeng
Li, Ning
Liu, Xingguo
Dong, Junyu
Chen, Xianyao
author_facet Gan, Yanhai
Chen, Yipeng
Li, Ning
Liu, Xingguo
Dong, Junyu
Chen, Xianyao
contents The El Ni{~n}o-Southern Oscillation (ENSO) exerts profound influence on global climate variability, yet its prediction remains a grand challenge. Recent advances in deep learning have significantly improved forecasting skill, but the opacity of these models hampers scientific trust and operational deployment. Here, we introduce a mathematically grounded interpretability framework based on bounded variation function. By rescuing the "dead" neurons from the saturation zone of the activation function, we enhance the model's expressive capacity. Our analysis reveals that ENSO predictability emerges dominantly from the tropical Pacific, with contributions from the Indian and Atlantic Oceans, consistent with physical understanding. Controlled experiments affirm the robustness of our method and its alignment with established predictors. Notably, we probe the persistent Spring Predictability Barrier (SPB), finding that despite expanded sensitivity during spring, predictive performance declines-likely due to suboptimal variable selection. These results suggest that incorporating additional ocean-atmosphere variables may help transcend SPB limitations and advance long-range ENSO prediction.
format Preprint
id arxiv_https___arxiv_org_abs_2601_02050
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Explore the Ideology of Deep Learning in ENSO Forecasts
Gan, Yanhai
Chen, Yipeng
Li, Ning
Liu, Xingguo
Dong, Junyu
Chen, Xianyao
Machine Learning
The El Ni{~n}o-Southern Oscillation (ENSO) exerts profound influence on global climate variability, yet its prediction remains a grand challenge. Recent advances in deep learning have significantly improved forecasting skill, but the opacity of these models hampers scientific trust and operational deployment. Here, we introduce a mathematically grounded interpretability framework based on bounded variation function. By rescuing the "dead" neurons from the saturation zone of the activation function, we enhance the model's expressive capacity. Our analysis reveals that ENSO predictability emerges dominantly from the tropical Pacific, with contributions from the Indian and Atlantic Oceans, consistent with physical understanding. Controlled experiments affirm the robustness of our method and its alignment with established predictors. Notably, we probe the persistent Spring Predictability Barrier (SPB), finding that despite expanded sensitivity during spring, predictive performance declines-likely due to suboptimal variable selection. These results suggest that incorporating additional ocean-atmosphere variables may help transcend SPB limitations and advance long-range ENSO prediction.
title Explore the Ideology of Deep Learning in ENSO Forecasts
topic Machine Learning
url https://arxiv.org/abs/2601.02050