Tackling the curse of dimensionality in fractional and tempered fractional PDEs with physics-informed neural networks
Abstract
Fractional and tempered fractional partial differential equations (PDEs) are effective models of long-range interactions, anomalous diffusion, and non-local effects. Traditional numerical methods for these problems are mesh-based, thus struggling with the curse of dimensionality (CoD). Physics-informed neural networks (PINNs) offer a promising solution due to their universal approximation, generalization ability, and mesh-free training. In principle, Monte Carlo fractional PINN (MC-fPINN) estimates fractional derivatives using Monte Carlo methods and thus could lift CoD. However, this may cause significant variance and errors, hence affecting convergence; in addition, MC-fPINN is sensitive to hyperparameters. In general, numerical methods and specifically PINNs for tempered fractional PDEs are under-developed. Herein, we extend MC-fPINN to tempered fractional PDEs to address these issues, resulting in the Monte Carlo tempered fractional PINN (MC-tfPINN). To reduce possible high variance and errors from Monte Carlo sampling, we replace the one-dimensional (1D) Monte Carlo with 1D Gaussian quadrature, applicable to both MC-fPINN and MC-tfPINN. We validate our methods on various forward and inverse problems of fractional and tempered fractional PDEs, scaling up to 100,000 dimensions. Our improved MC-fPINN/MC-tfPINN using quadrature consistently outperforms the original versions in accuracy and convergence speed in very high dimensions. Code is available at https://github.com/zheyuanhu01/Tempered_Fractional_PINN.
- Publication:
-
Computer Methods in Applied Mechanics and Engineering
- Pub Date:
- December 2024
- DOI:
- 10.1016/j.cma.2024.117448
- arXiv:
- arXiv:2406.11708
- Bibcode:
- 2024CMAME.43217448H
- Keywords:
-
- Physics-informed neural networks;
- Curse of dimensionality;
- Fractional and tempered fractional PDEs;
- High-dimensional PDEs;
- Mathematics - Numerical Analysis;
- Computer Science - Machine Learning;
- Mathematics - Dynamical Systems;
- F.2.2;
- I.2.7
- E-Print:
- 15 pages