English

A PDE-Informed Latent Diffusion Model for 2-m Temperature Downscaling

Machine Learning 2025-10-29 v1 Artificial Intelligence

Abstract

This work presents a physics-conditioned latent diffusion model tailored for dynamical downscaling of atmospheric data, with a focus on reconstructing high-resolution 2-m temperature fields. Building upon a pre-existing diffusion architecture and employing a residual formulation against a reference UNet, we integrate a partial differential equation (PDE) loss term into the model's training objective. The PDE loss is computed in the full resolution (pixel) space by decoding the latent representation and is designed to enforce physical consistency through a finite-difference approximation of an effective advection-diffusion balance. Empirical observations indicate that conventional diffusion training already yields low PDE residuals, and we investigate how fine-tuning with this additional loss further regularizes the model and enhances the physical plausibility of the generated fields. The entirety of our codebase is available on Github, for future reference and development.

Keywords

Cite

@article{arxiv.2510.23866,
  title  = {A PDE-Informed Latent Diffusion Model for 2-m Temperature Downscaling},
  author = {Paul Rosu and Muchang Bahng and Erick Jiang and Rico Zhu and Vahid Tarokh},
  journal= {arXiv preprint arXiv:2510.23866},
  year   = {2025}
}
R2 v1 2026-07-01T07:08:38.372Z