Wei, Shu; Li, Yanjie; Yu, Lina; Wu, Min; Li, Weijun; Hao, Meilan; Li, Wenqiang; Liu, Jingyi; Deng, Yusong

Source: arXiv, May 23, 2024; E-ISSN: 23318422; DOI: 10.48550/arXiv.2405.14620; Repository: arXiv

Author affiliation:

AnnLab, Institute of Semiconductors, Chinese Academy of Sciences Haidian, Beijing, 100083, CN University of Chinese Academy of Sciences Huairou, Beijing, 101408, CN

Abstract:

Solving partial differential equations (PDEs) in Euclidean space with closed-form symbolic solutions has long been a dream for mathematicians. Inspired by deep learning, Physics-Informed Neural Networks (PINNs) have shown great promise in numerically solving PDEs. However, since PINNs essentially approximate solutions within the continuous function space, their numerical solutions fall short in both precision and interpretability compared to symbolic solutions. This paper proposes a novel framework: a closed-form Symbolic framework for PDEs (SymPDE), exploring the use of deep reinforcement learning to directly obtain symbolic solutions for PDEs. SymPDE alleviates the challenges PINNs face in fitting high-frequency and steeply changing functions. To our knowledge, no prior work has implemented this approach. Experiments on solving the Poisson’s equation and heat equation in time-independent and spatiotemporal dynamical systems respectively demonstrate that SymPDE can provide accurate closed-form symbolic solutions for various types of PDEs.