An Interpretable Approach to the Solutions of High-Dimensional Partial Differential Equations

Authors

  • Lulu Cao School of Informatics, Key Laboratory of Digital Protection and Intelligent Processing of Intangible Cultural Heritage of Fujian and Taiwan, Ministry of Culture and Tourism, Xiamen University Key Laboratory of Multimedia Trusted Perception and Efficient Computing, Ministry of Education of China, Xiamen University
  • Yufei Liu School of Informatics, Key Laboratory of Digital Protection and Intelligent Processing of Intangible Cultural Heritage of Fujian and Taiwan, Ministry of Culture and Tourism, Xiamen University Key Laboratory of Multimedia Trusted Perception and Efficient Computing, Ministry of Education of China, Xiamen University
  • Zhenzhong Wang Department of Computing, The Hong Kong Polytechnic University
  • Dejun Xu School of Informatics, Key Laboratory of Digital Protection and Intelligent Processing of Intangible Cultural Heritage of Fujian and Taiwan, Ministry of Culture and Tourism, Xiamen University Key Laboratory of Multimedia Trusted Perception and Efficient Computing, Ministry of Education of China, Xiamen University
  • Kai Ye School of Informatics, Key Laboratory of Digital Protection and Intelligent Processing of Intangible Cultural Heritage of Fujian and Taiwan, Ministry of Culture and Tourism, Xiamen University Key Laboratory of Multimedia Trusted Perception and Efficient Computing, Ministry of Education of China, Xiamen University
  • Kay Chen Tan Department of Computing, The Hong Kong Polytechnic University
  • Min Jiang School of Informatics, Key Laboratory of Digital Protection and Intelligent Processing of Intangible Cultural Heritage of Fujian and Taiwan, Ministry of Culture and Tourism, Xiamen University Key Laboratory of Multimedia Trusted Perception and Efficient Computing, Ministry of Education of China, Xiamen University

DOI:

https://doi.org/10.1609/aaai.v38i18.30050

Keywords:

SO: Evolutionary Computation, APP: Natural Sciences, CSO: Search, ML: Evolutionary Learning, ML: Optimization, ML: Transfer, Domain Adaptation, Multi-Task Learning, ML: Transparent, Interpretable, Explainable ML

Abstract

In recent years, machine learning algorithms, especially deep learning, have shown promising prospects in solving Partial Differential Equations (PDEs). However, as the dimension increases, the relationship and interaction between variables become more complex, and existing methods are difficult to provide fast and interpretable solutions for high-dimensional PDEs. To address this issue, we propose a genetic programming symbolic regression algorithm based on transfer learning and automatic differentiation to solve PDEs. This method uses genetic programming to search for a mathematically understandable expression and combines automatic differentiation to determine whether the search result satisfies the PDE and boundary conditions to be solved. To overcome the problem of slow solution speed caused by large search space, we propose a transfer learning mechanism that transfers the structure of one-dimensional PDE analytical solution to the form of high-dimensional PDE solution. We tested three representative types of PDEs, and the results showed that our proposed method can obtain reliable and human-understandable real solutions or algebraic equivalent solutions of PDEs, and the convergence speed is better than the compared methods. Code of this project is at https://github.com/grassdeerdeer/HD-TLGP.
AAAI-24 / IAAI-24 / EAAI-24 Proceedings Cover

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Published

2024-03-24

How to Cite

Cao, L., Liu, Y., Wang, Z., Xu, D., Ye, K., Tan, K. C., & Jiang, M. (2024). An Interpretable Approach to the Solutions of High-Dimensional Partial Differential Equations. Proceedings of the AAAI Conference on Artificial Intelligence, 38(18), 20640-20648. https://doi.org/10.1609/aaai.v38i18.30050

Issue

Vol. 38 No. 18: AAAI-24 Technical Tracks 18

Section

AAAI Technical Track on Search and Optimization