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A Physics-Constrained Neural Differential Equation Framework for Data-Driven Snowpack Simulation

Machine Learning 2025-11-13 v3 Atmospheric and Oceanic Physics

Abstract

This paper presents a physics-constrained neural differential equation framework for parameterization, and employs it to model the time evolution of seasonal snow depth given hydrometeorological forcings. When trained on data from multiple SNOTEL sites, the parameterization predicts daily snow depth with under 9% median error and Nash Sutcliffe Efficiencies over 0.94 across a wide variety of snow climates. The parameterization also generalizes to new sites not seen during training, which is not often true for calibrated snow models. Requiring the parameterization to predict snow water equivalent in addition to snow depth only increases error to ~12%. The structure of the approach guarantees the satisfaction of physical constraints, enables these constraints during model training, and allows modeling at different temporal resolutions without additional retraining of the parameterization. These benefits hold potential in climate modeling, and could extend to other dynamical systems with physical constraints.

Keywords

Cite

@article{arxiv.2412.06819,
  title  = {A Physics-Constrained Neural Differential Equation Framework for Data-Driven Snowpack Simulation},
  author = {Andrew Charbonneau and Katherine Deck and Tapio Schneider},
  journal= {arXiv preprint arXiv:2412.06819},
  year   = {2025}
}

Comments

This Work has been accepted to Artificial Intelligence for Earth Systems. The AMS does not guarantee that the copy provided here is an accurate copy of the Version of Record (VoR). Please view the VoR at https://doi.org/10.1175/AIES-D-24-0040.1

R2 v1 2026-06-28T20:28:23.778Z