Physical informed neural networks with soft and hard boundary constraints for solving advection-diffusion equations using Fourier expansions
Journal article
Li, Xi-An, Deng, Jiaxin, Wu, Jinran, Zhang, Shaotong, Li, Weide and Wang, You-Gan. (2024). Physical informed neural networks with soft and hard boundary constraints for solving advection-diffusion equations using Fourier expansions. Computers and Mathematics with Applications. 159, pp. 60-75. https://doi.org/10.1016/j.camwa.2024.01.021
Authors | Li, Xi-An, Deng, Jiaxin, Wu, Jinran, Zhang, Shaotong, Li, Weide and Wang, You-Gan |
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Abstract | Deep learning methods have gained considerable interest in the numerical solution of various partial differential equations (PDEs). One particular focus is physics-informed neural networks (PINN), which integrate physical principles into neural networks. This transforms the process of solving PDEs into optimization problems for neural networks. To address a collection of advection-diffusion equations (ADE) in a range of difficult circumstances, this paper proposes a novel network structure. This architecture integrates the solver, a multi-scale deep neural networks (MscaleDNN) utilized in the PINN method, with a hard constraint technique known as HCPINN. This method introduces a revised formulation of the desired solution for ADE by utilizing a loss function that incorporates the residuals of the governing equation and penalizes any deviations from the specified boundary and initial constraints. By surpassing the boundary constraints automatically, this method improves the accuracy and efficiency of the PINN technique. To address the “spectral bias” phenomenon in neural networks, a subnetwork structure of MscaleDNN and a Fourier-induced activation function are incorporated into the HCPINN, resulting in a hybrid approach called SFHCPINN. The effectiveness of SFHCPINN is demonstrated through various numerical experiments involving ADE in different dimensions. The numerical results indicate that SFHCPINN outperforms both standard PINN and its subnetwork version with Fourier feature embedding. It achieves remarkable accuracy and efficiency while effectively handling complex boundary conditions and high-frequency scenarios in ADE. |
Keywords | Advection-Diffusion equation; PINN; Hard constraint; Subnetworks; Fourier feature mapping |
Year | 01 Jan 2024 |
Journal | Computers and Mathematics with Applications |
Journal citation | 159, pp. 60-75 |
Publisher | Elsevier Ltd. (UK) - Pergamon Press |
ISSN | 0898-1221 |
Digital Object Identifier (DOI) | https://doi.org/10.1016/j.camwa.2024.01.021 |
Web address (URL) | https://www.sciencedirect.com/science/article/abs/pii/S0898122124000348?via%3Dihub |
Open access | Open access |
Research or scholarly | Research |
Page range | 60-75 |
Author's accepted manuscript | License File Access Level Open |
Publisher's version | License All rights reserved File Access Level Controlled |
Output status | Published |
Publication dates | |
Online | 09 Feb 2024 |
Publication process dates | |
Accepted | 27 Jan 2024 |
Deposited | 06 Sep 2024 |
Additional information | © 2024 Elsevier Ltd. All rights reserved. |
This study was supported by the National Natural Science Foundation of China (No. 42130113, 42276215) | |
AM: Preprint submitted to Elsevier December 19, 2023 | |
Place of publication | United Kingdom |
https://acuresearchbank.acu.edu.au/item/90xx6/physical-informed-neural-networks-with-soft-and-hard-boundary-constraints-for-solving-advection-diffusion-equations-using-fourier-expansions
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Author's accepted manuscript
OA_Wu_2023_Physical_informed_neural_networks_with_soft.pdf | |
License: CC BY-NC-ND 4.0 | |
File access level: Open |
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