Spectral-element method with an optimal mass matrix for seismic wave modelling

IF 0.6 4区地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS Exploration Geophysics Pub Date : 2022-03-08 DOI:10.1080/08123985.2022.2043126

Shaolin Liu, Dinghui Yang, Xi-wei Xu, Wenshuai Wang, Xiaofan Li, Xueli Meng

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引用次数: 1

Abstract

The spectral-element method (SEM), which combines the flexibility of the finite element method (FEM) with the accuracy of spectral method, has been successfully applied to simulate seismic wavefields in geological models on different scales. One kind of SEMs that adopts orthogonal Legendre polynomials is widely used in seismology community. In the SEM with orthogonal Legendre polynomials, the Gauss-Lobatto-Legendre (GLL) quadrature rule is employed to calculate the integrals involved in the SEM leading to a diagonal mass matrix. However, the GLL quadrature rule can exactly approximate only integrals with a polynomial degree below 2N-1 (N is the interpolation order in space) and cannot exactly calculate those of polynomials with degree 2N involved in the mass matrix. Therefore, the error of the mass matrix originating from inexact numerical integration may reduce the accuracy of the SEM. To improve the SEM accuracy, we construct a least-squares objective function in terms of numerical and exact integrals to increase the accuracy of the GLL quadrature rule. Then, we utilise the conjugate gradient method to solve the objective function and obtain a set of optimal quadrature weights. The optimal mass matrix can be obtained simultaneously by utilising the GLL quadrature rule with optimal integration weights. The improvement in the numerical accuracy of the SEM with an optimal mass matrix (OSEM) is demonstrated by theoretical analysis and numerical examples.

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地震波模型的最优质量矩阵谱元法

谱元法将有限元法的灵活性与谱法的准确性相结合，已成功应用于不同尺度地质模型中的地震波场模拟。一种采用正交勒让德多项式的SEMs在地震学界得到了广泛的应用。在具有正交勒让德多项式的SEM中，采用高斯-洛巴特-勒让德（GLL）求积规则来计算SEM中涉及的积分，从而得到对角质量矩阵。然而，GLL求积规则只能精确地近似多项式次数低于2N-1的积分（N是空间中的插值阶），并且不能精确地计算质量矩阵中涉及的多项式次数为2N的积分。因此，由不精确的数值积分引起的质量矩阵误差可能会降低SEM的精度。为了提高SEM的精度，我们在数值积分和精确积分方面构造了一个最小二乘目标函数，以提高GLL求积规则的精度。然后，我们利用共轭梯度法求解目标函数，得到一组最优的正交权值。通过利用具有最优积分权重的GLL正交规则，可以同时获得最优质量矩阵。通过理论分析和数值算例表明，采用最优质量矩阵（OSEM）可以提高扫描电镜的数值精度。

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来源期刊

Exploration Geophysics 地学-地球化学与地球物理

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Exploration Geophysics is published on behalf of the Australian Society of Exploration Geophysicists (ASEG), Society of Exploration Geophysics of Japan (SEGJ), and Korean Society of Earth and Exploration Geophysicists (KSEG). The journal presents significant case histories, advances in data interpretation, and theoretical developments resulting from original research in exploration and applied geophysics. Papers that may have implications for field practice in Australia, even if they report work from other continents, will be welcome. ´Exploration and applied geophysics´ will be interpreted broadly by the editors, so that geotechnical and environmental studies are by no means precluded. Papers are expected to be of a high standard. Exploration Geophysics uses an international pool of reviewers drawn from industry and academic authorities as selected by the editorial panel. The journal provides a common meeting ground for geophysicists active in either field studies or basic research.