English

Physically Consistent Global Atmospheric Data Assimilation with Machine Learning in Latent Space

Atmospheric and Oceanic Physics 2026-03-05 v2

Abstract

Data assimilation (DA) integrates observations with model forecasts to produce optimized atmospheric states, whose physical consistency is critical for stable weather forecasting and reliable climate research. Traditional Bayesian DA methods enforce these nonlinear, flow-dependent physical constraints through empirical and tunable covariance structures, but with limited accuracy and robustness. Here, we introduce Latent Data Assimilation (LDA), a framework that performs Bayesian DA in a latent space learned from multivariate global atmospheric data via an autoencoder. We demonstrate that the autoencoder can largely capture nonlinear physical relationships, enabling LDA to produce balanced analyses without explicitly modeling physical constraints. Assimilation in latent space also improves both analysis quality and forecast skill compared to traditional model-space DA, under both idealized and real observational settings. Furthermore, LDA exhibits strong robustness across latent dimensions and remains effective even when the autoencoder is trained on inaccurate but physically realistic forecasts, highlighting its flexibility for real-world applications.

Keywords

Cite

@article{arxiv.2502.02884,
  title  = {Physically Consistent Global Atmospheric Data Assimilation with Machine Learning in Latent Space},
  author = {Hang Fan and Lei Bai and Ben Fei and Yi Xiao and Kun Chen and Yubao Liu and Yongquan Qu and Fenghua Ling and Pierre Gentine},
  journal= {arXiv preprint arXiv:2502.02884},
  year   = {2026}
}
R2 v1 2026-06-28T21:32:59.777Z