Eikonal Solution Using Physics-Informed Neural Networks

U. Waheed, E. Haghighat, T. Alkhalifah, Chao Song, Q. Hao
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引用次数: 32

Abstract

The eikonal equation is utilized across a wide spectrum of science and engineering disciplines. In seismology, it regulates seismic wave traveltimes needed for applications like source localization, imaging, and inversion. Several numerical algorithms have been developed over the years to solve the eikonal equation. However, they suffer from computational bottleneck when repeated computations are needed for perturbations in the velocity model and/or the source location, particularly in large 3D models. Here, we employ the emerging paradigm of physics-informed neural networks (PINNs) to solve the eikonal equation. By minimizing a loss function formed by imposing the validity of the eikonal equation, we train a neural network to produce traveltimes that are consistent with the underlying partial differential equation. More specifically, to tackle point-source singularity, we use the factored eikonal equation. We observe sufficiently high traveltime accuracy for most applications of interest. We also demonstrate how machine learning techniques like transfer learning and surrogate modeling can be used to massively speed up traveltime computations for updated velocity models and source locations. These properties of the PINN eikonal solver are highly desirable in obtaining an efficient forward modeling engine for seismic inversion applications.
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使用物理信息神经网络的Eikonal解决方案
eikonal方程被广泛应用于科学和工程学科。在地震学中,它调节震源定位、成像和反演等应用所需的地震波传播时间。多年来,已经开发了几种数值算法来求解eikonal方程。然而,当需要对速度模型和/或源位置的扰动进行重复计算时,特别是在大型3D模型中,它们会遇到计算瓶颈。在这里,我们采用新兴的物理信息神经网络(pinn)范式来解决eikonal方程。通过最小化通过施加eikonal方程的有效性形成的损失函数,我们训练一个神经网络来产生与潜在的偏微分方程一致的旅行时间。更具体地说,为了解决点源奇点,我们使用了因式方程。对于大多数感兴趣的应用,我们观察到足够高的走时精度。我们还演示了如何使用迁移学习和代理建模等机器学习技术来大规模加快更新速度模型和源位置的旅行时间计算。PINN正交解算器的这些特性对于获得有效的地震反演正演引擎是非常理想的。
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