具有傅立叶特征的物理信息神经网络用于时域非光滑复杂介质中的地震波场模拟

Yi Ding, Su Chen, Hiroe Miyake, Xiaojun Li
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引用次数: 0

摘要

物理信息神经网络(PINNs)在地震波的正演建模和反演方面具有极大的灵活性和有效性。然而,基于坐标的神经网络(NNs)普遍存在 "频谱偏差 "病理,极大地限制了其在尖锐复杂介质中模拟高频波传播的能力。我们提出了一个统一的傅里叶特征物理信息神经网络(FF-PINNs)框架,用于求解时域波方程。该框架将随机梯度下降(SGD)策略与预先训练的波速代理模型相结合,以减轻点源处的奇异性。通过消磁实验讨论了激活函数和梯度下降策略的性能。此外,我们还评估了从不同分布系列(高斯分布、拉普拉斯分布和均匀分布)采样的傅里叶特征映射的精度比较。在损失函数中加入了基于二阶准轴近似的边界条件,作为消除虚假边界反射的软调节器。通过非光滑马尔穆西模型和推力模型案例,我们强调了吸收边界条件(ABC)约束的必要性。一系列数值实验结果证明了所提出的方法对尖锐和复杂介质中高频波传播建模的准确性和有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Physics-informed Neural Networks with Fourier Features for Seismic Wavefield Simulation in Time-Domain Nonsmooth Complex Media
Physics-informed neural networks (PINNs) have great potential for flexibility and effectiveness in forward modeling and inversion of seismic waves. However, coordinate-based neural networks (NNs) commonly suffer from the "spectral bias" pathology, which greatly limits their ability to model high-frequency wave propagation in sharp and complex media. We propose a unified framework of Fourier feature physics-informed neural networks (FF-PINNs) for solving the time-domain wave equations. The proposed framework combines the stochastic gradient descent (SGD) strategy with a pre-trained wave velocity surrogate model to mitigate the singularity at the point source. The performance of the activation functions and gradient descent strategies are discussed through ablation experiments. In addition, we evaluate the accuracy comparison of Fourier feature mappings sampled from different families of distributions (Gaussian, Laplace, and uniform). The second-order paraxial approximation-based boundary conditions are incorporated into the loss function as a soft regularizer to eliminate spurious boundary reflections. Through the non-smooth Marmousi and Overthrust model cases, we emphasized the necessity of the absorbing boundary conditions (ABCs) constraints. The results of a series of numerical experiments demonstrate the accuracy and effectiveness of the proposed method for modeling high-frequency wave propagation in sharp and complex media.
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