Spectrally Adapted Physics-Informed Neural Networks for Solving
Unbounded Domain Problems
- URL: http://arxiv.org/abs/2202.02710v1
- Date: Sun, 6 Feb 2022 05:25:22 GMT
- Title: Spectrally Adapted Physics-Informed Neural Networks for Solving
Unbounded Domain Problems
- Authors: Mingtao Xia, Lucas B\"ottcher, Tom Chou
- Abstract summary: In this work, we combine two classes of numerical methods: (i) physics-informed neural networks (PINNs) and (ii) adaptive spectral methods.
The numerical methods that we develop take advantage of the ability of physics-informed neural networks to easily implement high-order numerical schemes to efficiently solve PDEs.
We then show how recently introduced adaptive techniques for spectral methods can be integrated into PINN-based PDE solvers to obtain numerical solutions of unbounded domain problems that cannot be efficiently approximated by standard PINNs.
- Score: 0.0
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: Solving analytically intractable partial differential equations (PDEs) that
involve at least one variable defined in an unbounded domain requires efficient
numerical methods that accurately resolve the dependence of the PDE on that
variable over several orders of magnitude. Unbounded domain problems arise in
various application areas and solving such problems is important for
understanding multi-scale biological dynamics, resolving physical processes at
long time scales and distances, and performing parameter inference in
engineering problems. In this work, we combine two classes of numerical
methods: (i) physics-informed neural networks (PINNs) and (ii) adaptive
spectral methods. The numerical methods that we develop take advantage of the
ability of physics-informed neural networks to easily implement high-order
numerical schemes to efficiently solve PDEs. We then show how recently
introduced adaptive techniques for spectral methods can be integrated into
PINN-based PDE solvers to obtain numerical solutions of unbounded domain
problems that cannot be efficiently approximated by standard PINNs. Through a
number of examples, we demonstrate the advantages of the proposed spectrally
adapted PINNs (s-PINNs) over standard PINNs in approximating functions, solving
PDEs, and estimating model parameters from noisy observations in unbounded
domains.
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