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Tackling the curse of dimensionality in fractional and tempered fractional PDEs with physics-informed neural networks

Zheyuan Hu, Kenji Kawaguchi, Zhongqiang Zhang, George Em Karniadakis

2024Computer Methods in Applied Mechanics and Engineering9 citationsDOIOpen Access PDF

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 .

Topics & Concepts

Curse of dimensionalityArtificial neural networkFractional calculusApplied mathematicsStatistical physicsMathematicsArtificial intelligenceComputer sciencePhysicsModel Reduction and Neural NetworksFractional Differential Equations SolutionsNanofluid Flow and Heat Transfer