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Dynamic Deep Learning Based Super-Resolution For The Shallow Water Equations

Machine Learning 2025-03-12 v2 Computational Physics Fluid Dynamics

Abstract

Using the nonlinear shallow water equations as benchmark, we demonstrate that a simulation with the ICON-O ocean model with a 20km resolution that is frequently corrected by a U-net-type neural network can achieve discretization errors of a simulation with 10km resolution. The network, originally developed for image-based super-resolution in post-processing, is trained to compute the difference between solutions on both meshes and is used to correct the coarse mesh every 12h. Our setup is the Galewsky test case, modeling transition of a barotropic instability into turbulent flow. We show that the ML-corrected coarse resolution run correctly maintains a balance flow and captures the transition to turbulence in line with the higher resolution simulation. After 8 day of simulation, the L2L_2-error of the corrected run is similar to a simulation run on the finer mesh. While mass is conserved in the corrected runs, we observe some spurious generation of kinetic energy.

Keywords

Cite

@article{arxiv.2404.06400,
  title  = {Dynamic Deep Learning Based Super-Resolution For The Shallow Water Equations},
  author = {Maximilian Witte and Fabricio Rodrigues Lapolli and Philip Freese and Sebastian Götschel and Daniel Ruprecht and Peter Korn and Christopher Kadow},
  journal= {arXiv preprint arXiv:2404.06400},
  year   = {2025}
}

Comments

17 pages, 12 figures

R2 v1 2026-06-28T15:48:56.947Z