Seismic imaging and optimal transport

Commun. Inf. Syst. Pub Date : 2018-08-14 DOI:10.4310/cis.2019.v19.n2.a1

Bjorn Engquist, Yunan Yang

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引用次数: 14

Abstract

Seismology has been an active science for a long time. It changed character about 50 years ago when the earth's vibrations could be measured on the surface more accurately and more frequently in space and time. The full wave field could be determined, and partial differential equations (PDE) started to be used in the inverse process of finding properties of the interior of the earth. We will briefly review earlier techniques but mainly focus on Full Waveform Inversion (FWI) for the acoustic formulation. FWI is a PDE constrained optimization in which the variable velocity in a forward wave equation is adjusted such that the solution matches measured data on the surface. The minimization of the mismatch is usually coupled with the adjoint state method, which also includes the solution to an adjoint wave equation. The least-squares norm is the conventional objective function measuring the difference between simulated and measured data, but it often results in the minimization trapped in local minima. One way to mitigate this is by selecting another misfit function with better convexity properties. Here we propose using the quadratic Wasserstein metric as a new misfit function in FWI. The optimal map defining the quadratic Wasserstein metric can be computed by solving a Monge-Ampere equation. Theorems pointing to the advantages of using optimal transport over the least-squares norm will be discussed, and a number of large-scale computational examples will be presented.

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地震成像和最佳运输

地震学长期以来是一门活跃的科学。大约50年前，当地球表面的振动可以在空间和时间上更精确、更频繁地测量时，它的性质发生了变化。整个波场可以确定，偏微分方程(PDE)开始应用于寻找地球内部性质的逆过程。我们将简要回顾早期的技术，但主要集中在声学公式的全波形反演(FWI)。FWI是一种PDE约束优化方法，通过调整正向波动方程中的变速，使其解与地面上的测量数据相匹配。对不匹配的最小化通常与伴随状态法相结合，伴随状态法还包括伴随波动方程的解。最小二乘范数是测量模拟数据与实测数据之差的传统目标函数，但其结果往往是被局部极小值所困。缓解这种情况的一种方法是选择另一个具有更好凸性的失拟函数。本文提出使用二次Wasserstein度量作为FWI中的一种新的失配函数。定义二次瓦瑟斯坦度规的最优映射可以通过求解蒙日-安培方程来计算。指出使用最优传输优于最小二乘范数的定理将被讨论，并将给出一些大规模的计算示例。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Commun. Inf. Syst.

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