Physics-Informed Graph Convolutional Networks: Towards a generalized framework for complex geometries (2310.14948v4)
Abstract: Since the seminal work of [9] and their Physics-Informed neural networks (PINNs), many efforts have been conducted towards solving partial differential equations (PDEs) with Deep Learning models. However, some challenges remain, for instance the extension of such models to complex three-dimensional geometries, and a study on how such approaches could be combined to classical numerical solvers. In this work, we justify the use of graph neural networks for these problems, based on the similarity between these architectures and the meshes used in traditional numerical techniques for solving partial differential equations. After proving an issue with the Physics-Informed framework for complex geometries, during the computation of PDE residuals, an alternative procedure is proposed, by combining classical numerical solvers and the Physics-Informed framework. Finally, we propose an implementation of this approach, that we test on a three-dimensional problem on an irregular geometry.
- Numerical modeling of electrical upsetting manufacturing processes based on forge® environment. In AIP Conference Proceedings, volume 1896, page 120003. AIP Publishing LLC, 2017.
- Relational inductive biases, deep learning, and graph networks. arXiv preprint arXiv:1806.01261, 2018.
- Combining differentiable pde solvers and graph neural networks for fluid flow prediction. In International Conference on Machine Learning, pages 2402–2411. PMLR, 2020.
- Grand: Graph neural diffusion. In International Conference on Machine Learning, pages 1407–1418. PMLR, 2021.
- Physics-informed graph neural galerkin networks: A unified framework for solving pde-governed forward and inverse problems. Computer Methods in Applied Mechanics and Engineering, 390:114502, 2022.
- T. N. Kipf and M. Welling. Semi-supervised classification with graph convolutional networks. arXiv preprint arXiv:1609.02907, 2016.
- Artificial neural networks for solving ordinary and partial differential equations. IEEE transactions on neural networks, 9(5):987–1000, 1998.
- Pytorch: An imperative style, high-performance deep learning library. In H. Wallach, H. Larochelle, A. Beygelzimer, F. d'Alché-Buc, E. Fox, and R. Garnett, editors, Advances in Neural Information Processing Systems 32, pages 8024–8035. Curran Associates, Inc., 2019.
- Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations. Journal of Computational Physics, 378:686–707, 2019.
- Graph neural network-based surrogate models for finite element analysis. In 2022 21st International Symposium on Distributed Computing and Applications for Business Engineering and Science (DCABES), pages 54–57. IEEE, 2022.
- Understanding and mitigating gradient flow pathologies in physics-informed neural networks. SIAM Journal on Scientific Computing, 43(5):A3055–A3081, 2021.
- Dynamic graph cnn for learning on point clouds. Acm Transactions On Graphics (tog), 38(5):1–12, 2019.
- A comprehensive survey on graph neural networks. IEEE transactions on neural networks and learning systems, 32(1):4–24, 2020.
- Rbf-mgn: Solving spatiotemporal pdes with physics-informed graph neural network. arXiv preprint arXiv:2212.02861, 2022.
- Marien Chenaud (2 papers)
- José Alves (4 papers)
- Frédéric Magoulès (47 papers)