Physics-informed Neural Networks (PINNs) for Wave Propagation and Full Waveform Inversions

TL;DR

This paper introduces a novel application of Physics-Informed Neural Networks (PINNs) to simulate wave propagation and perform full waveform inversions in seismology, demonstrating their effectiveness and flexibility in handling complex boundary conditions and inverse problems.

Contribution

The study develops and tests a PINNs-based algorithm for 2D acoustic wave equations, showing its capability for wave simulation and inversion with limited computational resources.

Findings

PINNs automatically satisfy absorbing boundary conditions.

PINNs provide excellent inversion results across various test cases.

PINNs are flexible for incorporating prior subsurface knowledge.

Abstract

We propose a new approach to the solution of the wave propagation and full waveform inversions (FWIs) based on a recent advance in deep learning called Physics-Informed Neural Networks (PINNs). In this study, we present an algorithm for PINNs applied to the 2D acoustic wave equation and test the model with both forward wave propagation and FWIs case studies. These synthetic case studies are designed to explore the ability of PINNs to handle varying degrees of structural complexity using both teleseismic plane waves and seismic point sources. PINNs meshless formalism allows for a flexible implementation of the wave equation and different types of boundary conditions. For instance, our models demonstrate that PINN automatically satisfies absorbing boundary conditions, a serious computational challenge for common wave propagation solvers. Furthermore, a priori knowledge of the subsurface structure can be seamlessly encoded in PINNs formulation. We find that the current state-of-the-art PINNs provide good results for the forward model, even though spectral element or finite difference methods are more efficient and accurate. More importantly, our results demonstrate that PINNs yield excellent results for inversions on all cases considered and with limited computational complexity. Using PINNs as a geophysical inversion solver offers exciting perspectives, not only for the full waveform seismic inversions, but also when dealing with other geophysical datasets (e.g., magnetotellurics, gravity) as well as joint inversions because of its robust framework and simple implementation.