Pseudo-differential-enhanced physics-informed neural networks

TL;DR

This paper introduces pseudo-differential enhanced PINNs, extending gradient enhancement into Fourier space to improve training efficiency, accuracy, and frequency learning, especially for fractional derivatives and complex domains.

Contribution

It proposes a novel Fourier space augmentation for PINNs that enhances spectral learning, improves convergence, and is compatible with advanced techniques and complex geometries.

Findings

Achieves superior PINN versus numerical error in fewer iterations.

Enhances spectral eigenvalue decay of the neural tangent kernel.

Effective for fractional derivatives and complex domain geometries.

Abstract

We present pseudo-differential enhanced physics-informed neural networks (PINNs), an extension of gradient enhancement but in Fourier space. Gradient enhancement of PINNs dictates that the PDE residual is taken to a higher differential order than prescribed by the PDE, added to the objective as an augmented term in order to improve training and overall learning fidelity. We propose the same procedure after application via Fourier transforms, since differentiating in Fourier space is multiplication with the Fourier wavenumber under suitable decay. Our methods are fast and efficient. Our methods oftentimes achieve superior PINN versus numerical error in fewer training iterations, potentially pair well with few samples in collocation, and can on occasion break plateaus in low collocation settings. Moreover, our methods are suitable for fractional derivatives. We establish that our methods, due to the dynamical effects, improve spectral eigenvalue decay of the neural tangent kernel (NTK), and so our methods contribute towards the learning of high frequencies in early training, mitigating the effects of frequency bias up to the polynomial order and possibly greater with smooth activations. Our methods accommodate advanced techniques in PINNs, such as Fourier feature embeddings. A pitfall of discrete Fourier transforms via the Fast Fourier Transform (FFT) is mesh subjugation, and so we demonstrate compatibility of our methods for greater mesh flexibility and invariance on alternative Euclidean and non-Euclidean domains via Monte Carlo methods and otherwise.