Machine-Learned Preconditioners for Linear Solvers in Geophysical Fluid Flows
Abstract
It is tested whether machine learning methods can be used for preconditioning to increase the performance of the linear solver -- the backbone of the semi-implicit, grid-point model approach for weather and climate models. Embedding the machine-learning method within the framework of a linear solver circumvents potential robustness issues that machine learning approaches are often criticized for, as the linear solver ensures that a sufficient, pre-set level of accuracy is reached. The approach does not require prior availability of a conventional preconditioner and is highly flexible regarding complexity and machine learning design choices. Several machine learning methods are used to learn the optimal preconditioner for a shallow-water model with semi-implicit timestepping that is conceptually similar to more complex atmosphere models. The machine-learning preconditioner is competitive with a conventional preconditioner and provides good results even if it is used outside of the dynamical range of the training dataset.
Cite
@article{arxiv.2010.02866,
title = {Machine-Learned Preconditioners for Linear Solvers in Geophysical Fluid Flows},
author = {Jan Ackmann and Peter D. Düben and Tim N. Palmer and Piotr K. Smolarkiewicz},
journal= {arXiv preprint arXiv:2010.02866},
year = {2020}
}
Comments
To be submitted to GRL, 15 pages, 3 figures