LARGE SCALE RANDOMIZED LEARNING GUIDED BY PHYSICAL LAWS WITH APPLICATIONS IN FULL WAVEFORM INVERSION.

... IEEE Global Conference on Signal and Information Processing. IEEE Global Conference on Signal and Information Processing Pub Date : 2018-11-01 Epub Date: 2019-02-21 DOI:10.1109/GlobalSIP.2018.8646507

Rui Xie, Fangyu Li, Zengyan Wang, WenZhan Song

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引用次数: 2

Abstract

The rapid convergence rate, high fidelity learning outcome and low computational cost are key targets in solving the learning problem of the complex physical system. Guided by physical laws of wave propagation, in full waveform inversion (FWI), we learn the subsurface images through optimizing the media velocity model in a large scale non-linear problem. In this paper, we combine randomized subsampling techniques with a second-order optimization algorithm to propose the Sub-Sampled Newton (SSN) method for learning velocity model of FWI. By incorporating the curvature information, SSN preserves comparable convergence rate to Newtons method and significantly reduces the iteration cost by approximating the Hessian matrix through a non-uniform subsampling scheme. The numerical experiments demonstrate that the proposed SSN method has a faster convergence rate, and achieves a more accurate velocity model in terms of mean squared error than commonly used methods.

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基于物理定律的大规模随机学习及其在全波形反演中的应用。

快速的收敛速度、高保真的学习结果和低的计算成本是解决复杂物理系统学习问题的关键目标。在全波形反演(FWI)中，以波传播的物理规律为指导，通过优化大规模非线性问题的介质速度模型来学习地下图像。本文将随机子抽样技术与二阶优化算法相结合，提出了一种用于FWI学习速度模型的子抽样牛顿(SSN)方法。通过结合曲率信息，SSN保持了与牛顿方法相当的收敛速度，并通过非均匀次抽样方案近似Hessian矩阵，显著降低了迭代成本。数值实验表明，该方法具有更快的收敛速度，并且在均方误差方面获得了比常用方法更精确的速度模型。

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... IEEE Global Conference on Signal and Information Processing. IEEE Global Conference on Signal and Information Processing

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