Physics-informed generative neural network: an application to troposphere temperature prediction
Abstract
The troposphere is one of the atmospheric layers where most weather phenomena occur. Temperature variations in the troposphere, especially at 500 hPa, a typical level of the middle troposphere, are significant indicators of future weather changes. Numerical weather prediction is effective for temperature prediction, but its computational complexity hinders a timely response. This paper proposes a novel temperature prediction approach in framework ofphysics-informed deep learning. The new model, called PGnet, builds upon a generative neural network with a mask matrix. The mask is designed to distinguish the low-quality predicted regions generated by the first physical stage. The generative neural network takes the mask as prior for the second-stage refined predictions. A mask-loss and a jump pattern strategy are developed to train the generative neural network without accumulating errors during making time-series predictions. Experiments on ERA5 demonstrate that PGnet can generate more refined temperature predictions than the state-of-the-art.
Cite
@article{arxiv.2107.06991,
title = {Physics-informed generative neural network: an application to troposphere temperature prediction},
author = {Zhihao Chen and Jie Gao and Weikai Wang and Zheng Yan},
journal= {arXiv preprint arXiv:2107.06991},
year = {2021}
}