English

LEVDA: Latent Ensemble Variational Data Assimilation via Differentiable Dynamics

Machine Learning 2026-02-24 v1 Optimization and Control

Abstract

Long-range geophysical forecasts are fundamentally limited by chaotic dynamics and numerical errors. While data assimilation can mitigate these issues, classical variational smoothers require computationally expensive tangent-linear and adjoint models. Conversely, recent efficient latent filtering methods often enforce weak trajectory-level constraints and assume fixed observation grids. To bridge this gap, we propose Latent Ensemble Variational Data Assimilation (LEVDA), an ensemble-space variational smoother that operates in the low-dimensional latent space of a pretrained differentiable neural dynamics surrogate. By performing four-dimensional ensemble-variational (4DEnVar) optimization within an ensemble subspace, LEVDA jointly assimilates states and unknown parameters without the need for adjoint code or auxiliary observation-to-latent encoders. Leveraging the fully differentiable, continuous-in-time-and-space nature of the surrogate, LEVDA naturally accommodates highly irregular sampling at arbitrary spatiotemporal locations. Across three challenging geophysical benchmarks, LEVDA matches or outperforms state-of-the-art latent filtering baselines under severe observational sparsity while providing more reliable uncertainty quantification. Simultaneously, it achieves substantially improved assimilation accuracy and computational efficiency compared to full-state 4DEnVar.

Keywords

Cite

@article{arxiv.2602.19406,
  title  = {LEVDA: Latent Ensemble Variational Data Assimilation via Differentiable Dynamics},
  author = {Phillip Si and Peng Chen},
  journal= {arXiv preprint arXiv:2602.19406},
  year   = {2026}
}
R2 v1 2026-07-01T10:46:40.872Z