Predicting atmospheric optical properties for radiative transfer computations using neural networks
Abstract
The radiative transfer equations are well-known, but radiation parametrizations in atmospheric models are computationally expensive. A promising tool for accelerating parametrizations is the use of machine learning techniques. In this study, we develop a machine learning-based parametrization for the gaseous optical properties by training neural networks to emulate a modern radiation parameterization (RRTMGP). To minimize computational costs, we reduce the range of atmospheric conditions for which the neural networks are applicable and use machine-specific optimised BLAS functions to accelerate matrix computations. To generate training data, we use a set of randomly perturbed atmospheric profiles and calculate optical properties using RRTMGP. Predicted optical properties are highly accurate and the resulting radiative fluxes have average errors within \SI{0.5}{\flux} compared to RRTMGP. Our neural network-based gas optics parametrization is up to 4 times faster than RRTMGP, depending on the size of the neural networks. We further test the trade-off between speed and accuracy by training neural networks for the narrow range of atmospheric conditions of a single large-eddy simulation, so smaller and therefore faster networks can achieve a desired accuracy. We conclude that our machine learning-based parametrization can speed-up radiative transfer computations whilst retaining high accuracy.
Keywords
Cite
@article{arxiv.2005.02265,
title = {Predicting atmospheric optical properties for radiative transfer computations using neural networks},
author = {Menno A. Veerman and Robert Pincus and Robin Stoffer and Caspar van Leeuwen and Damian Podareanu and Chiel C. van Heerwaarden},
journal= {arXiv preprint arXiv:2005.02265},
year = {2021}
}
Comments
13 pages,5 figures, submitted to Philosophical Transactions A