Traditional fluid dynamics simulation pipelines combine numerical solvers with rendering, producing highly realistic results but at considerable computational cost. Diffusion-based generative video models offer a faster alternative, yet often ignore physical laws and thus fail to capture consistent dynamics. We propose a physics-informed video diffusion framework that jointly generates visual outputs and physical states. Unlike prior two-stage approaches that first simulate the physical variables and then render, we directly integrate physics constraints into the generative process, enabling simultaneous prediction of physical states and realistic videos without a separate rendering step. Built on the two-dimensional shallow water equations with terrain topography, our method produces temporally coherent water flow while maintaining physical plausibility. Experiments show that it outperforms purely data-driven video diffusion baselines in both realism and physical fidelity, while generating videos significantly faster than traditional simulation-plus-rendering pipelines.
@article{arxiv.2603.15627,
title = {Physics-Informed Video Diffusion For Shallow Water Equations},
author = {Yang Bai and George Eskandar and Ziyuan Liu and Gitta Kutyniok},
journal= {arXiv preprint arXiv:2603.15627},
year = {2026}
}
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2026 IEEE International Conference on Acoustics, Speech, and Signal Processing