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Advancing Ocean State Estimation with efficient and scalable AI

Machine Learning 2025-11-11 v1 Artificial Intelligence

Abstract

Accurate and efficient global ocean state estimation remains a grand challenge for Earth system science, hindered by the dual bottlenecks of computational scalability and degraded data fidelity in traditional data assimilation (DA) and deep learning (DL) approaches. Here we present an AI-driven Data Assimilation Framework for Ocean (ADAF-Ocean) that directly assimilates multi-source and multi-scale observations, ranging from sparse in-situ measurements to 4 km satellite swaths, without any interpolation or data thinning. Inspired by Neural Processes, ADAF-Ocean learns a continuous mapping from heterogeneous inputs to ocean states, preserving native data fidelity. Through AI-driven super-resolution, it reconstructs 0.25^\circ mesoscale dynamics from coarse 1^\circ fields, which ensures both efficiency and scalability, with just 3.7\% more parameters than the 1^\circ configuration. When coupled with a DL forecasting system, ADAF-Ocean extends global forecast skill by up to 20 days compared to baselines without assimilation. This framework establishes a computationally viable and scientifically rigorous pathway toward real-time, high-resolution Earth system monitoring.

Keywords

Cite

@article{arxiv.2511.06041,
  title  = {Advancing Ocean State Estimation with efficient and scalable AI},
  author = {Yanfei Xiang and Yuan Gao and Hao Wu and Quan Zhang and Ruiqi Shu and Xiao Zhou and Xi Wu and Xiaomeng Huang},
  journal= {arXiv preprint arXiv:2511.06041},
  year   = {2025}
}

Comments

29 papes, 10 Figures

R2 v1 2026-07-01T07:27:44.352Z