2D Magnetotelluric Inversion Using Linear Finite Element Methods and a Discretize-Last Strategy With First and Second–Order Anisotropic Regularization

IF 2.9 3区 地球科学 Q2 ASTRONOMY & ASTROPHYSICS
Andrea Codd, Lutz Gross, Janelle Kerr
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Abstract

We present a new inversion scheme for 2D magnetotelluric data. In contrast to established approaches, it is based on a mesh-free formulation of the Quasi-Newton Broyden–Fletcher–Goldfarb–Shanno (BFGS) iteration which uses the cost function gradient to implicitly construct approximations of the Hessian inverse to update the unknown conductivity. We introduce conventional first–order regularization as well as second–order regularization where inversions based on the latter are more appropriate for sparse data and can be read as maximum likelihood estimation of the unknown conductivity. We apply first–order finite element method (FEM) discretizations of the inversion scheme, forward and adjoint problems, where the latter is required for the construction of the cost function gradients. We allow for unstructured first–order triangular meshes supporting an enhanced ground level resolution including topographical features and coarsening at the far field leading to significant reduction in computational costs from using structured mesh. Formulating the inversion iteration in continuous form prior to discretization eliminates bias due to local refinements in the mesh and gives way for computationally efficient sparse matrix techniques in the implementation. A keystone in the new scheme is the multi-grid approximation of the Hessian of the regularizations to construct efficient preconditioning for the inversion iteration. The method is applied to the Commeni4 benchmark and two field data sets. Tests show that for both first and second–order regularization an anisotropic approach is important to address the vast differences in horizontal and vertical spatial scale which in conventional approaches is implicitly introduced through the elongated shape of grid cells.

Abstract Image

使用线性有限元方法和带有一阶和二阶各向异性正则化的最后离散化策略进行二维磁位反演
我们针对二维磁突触数据提出了一种新的反演方案。与既有方法不同的是,它基于准牛顿布洛伊登-弗莱彻-戈德法布-山诺(BFGS)迭代的无网格表述,利用成本函数梯度来隐式构建赫塞斯逆近似值,以更新未知电导率。我们引入了传统的一阶正则化和二阶正则化,其中基于二阶正则化的反演更适合稀疏数据,并可理解为未知电导率的最大似然估计。我们采用一阶有限元法(FEM)对反演方案、正向问题和邻接问题进行离散化,其中邻接问题是构建成本函数梯度所必需的。我们允许使用非结构化的一阶三角形网格,支持增强的地面分辨率,包括地形特征和远场粗化,从而显著降低了使用结构化网格的计算成本。在离散化之前以连续形式进行反演迭代,消除了由于网格局部细化造成的偏差,并为实施计算效率高的稀疏矩阵技术提供了途径。新方案的关键是对正则化的 Hessian 进行多网格近似,从而为反演迭代构建高效的前提条件。该方法应用于 Commeni4 基准和两个实地数据集。测试表明,对于一阶和二阶正则化,各向异性方法对于解决水平和垂直空间尺度的巨大差异非常重要。
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来源期刊
Earth and Space Science
Earth and Space Science Earth and Planetary Sciences-General Earth and Planetary Sciences
CiteScore
5.50
自引率
3.20%
发文量
285
审稿时长
19 weeks
期刊介绍: Marking AGU’s second new open access journal in the last 12 months, Earth and Space Science is the only journal that reflects the expansive range of science represented by AGU’s 62,000 members, including all of the Earth, planetary, and space sciences, and related fields in environmental science, geoengineering, space engineering, and biogeochemistry.
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