Ambient Physics: Training Neural PDE Solvers with Partial Observations
Abstract
In many scientific settings, acquiring complete observations of PDE coefficients and solutions can be expensive, hazardous, or impossible. Recent diffusion-based methods can reconstruct fields given partial observations, but require complete observations for training. We introduce Ambient Physics, a framework for learning the joint distribution of coefficient-solution pairs directly from partial observations, without requiring a single complete observation. The key idea is to randomly mask a subset of already-observed measurements and supervise on them, so the model cannot distinguish "truly unobserved" from "artificially unobserved", and must produce plausible predictions everywhere. Ambient Physics achieves state-of-the-art reconstruction performance. Compared with prior diffusion-based methods, it achieves a 62.51 reduction in average overall error while using 125 fewer function evaluations. We also identify a "one-point transition": masking a single already-observed point enables learning from partial observations across architectures and measurement patterns. Ambient Physics thus enables scientific progress in settings where complete observations are unavailable.
Cite
@article{arxiv.2602.13873,
title = {Ambient Physics: Training Neural PDE Solvers with Partial Observations},
author = {Harris Abdul Majid and Giannis Daras and Francesco Tudisco and Steven McDonagh},
journal= {arXiv preprint arXiv:2602.13873},
year = {2026}
}