SeismicNet: Physics-informed neural networks for seismic wave modeling
in semi-infinite domain
- URL: http://arxiv.org/abs/2210.14044v1
- Date: Tue, 25 Oct 2022 14:25:07 GMT
- Title: SeismicNet: Physics-informed neural networks for seismic wave modeling
in semi-infinite domain
- Authors: Pu Ren, Chengping Rao, Hao Sun, Yang Liu
- Abstract summary: We present a novel physics-informed neural network (PINN) model for seismic wave modeling in semi-infinite domain without the nedd of labeled data.
In terms of computational efficiency, we consider a sequential training strategy via temporal domain decomposition to improve the scalability of the network and solution accuracy.
Various numerical experiments have been implemented to evaluate the performance of the proposed PINN model.
- Score: 11.641708412097659
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: There has been an increasing interest in integrating physics knowledge and
machine learning for modeling dynamical systems. However, very limited studies
have been conducted on seismic wave modeling tasks. A critical challenge is
that these geophysical problems are typically defined in large domains (i.e.,
semi-infinite), which leads to high computational cost. In this paper, we
present a novel physics-informed neural network (PINN) model for seismic wave
modeling in semi-infinite domain without the nedd of labeled data. In specific,
the absorbing boundary condition is introduced into the network as a soft
regularizer for handling truncated boundaries. In terms of computational
efficiency, we consider a sequential training strategy via temporal domain
decomposition to improve the scalability of the network and solution accuracy.
Moreover, we design a novel surrogate modeling strategy for parametric loading,
which estimates the wave propagation in semin-infinite domain given the seismic
loading at different locations. Various numerical experiments have been
implemented to evaluate the performance of the proposed PINN model in the
context of forward modeling of seismic wave propagation. In particular, we
define diverse material distributions to test the versatility of this approach.
The results demonstrate excellent solution accuracy under distinctive
scenarios.
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