3D large-scale forward modeling of gravitational fields using triangular spherical prisms with polynomial densities in depth

IF 3.9 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
Fang Ouyang, Long-wei Chen, Leyuan Wu
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Abstract

To take the sphericity of the Earth into account, tesseroids are often utilized as grid elements in large-scale gravitational forward modeling. However, such elements in a latitude–longitude mesh suffer from degenerating into poorly shaped triangles near poles. Moreover, tesseroids have limited flexibility in describing laterally variable density distributions with irregular boundaries and also face difficulties in achieving completely equivalent division over a spherical surface that may be desired in a gravity inversion. We develop a new method based on triangular spherical prisms (TSPs) for 3D gravitational modeling in spherical coordinates. A TSP is defined by two spherical surfaces of triangular shape, with one of which being the radial projection of the other. Due to the spherical triangular shapes of the upper and lower surfaces, TSPs enjoy more advantages over tesseroids in describing mass density with different lateral resolutions. In addition, such an element also allows subdivisions with nearly equal weights in spherical coordinates. To calculate the gravitational effects of a TSP, we assume the density in each element to be polynomial along radial direction so as to accommodate a complex density environment. Then, we solve the Newton’s volume integral using a mixed Gaussian quadrature method, in which the surface integral over the spherical triangle is calculated using a triangle-based Gaussian quadrature rule via a radial projection that transforms the spherical triangles into linear ones. A 2D adaptive discretization strategy and an extension technique are also combined to improve the accuracy at observation points near the mass sources. The numerical experiments based on spherical shell models show that the proposed method achieves good accuracy from near surface to a satellite height in the case of TSPs with various dimensions and density variations. In comparison with the classical tesseroid-based method, the proposed algorithm enjoys better accuracy and much higher flexibility for density models with laterally irregular shapes. It shows that to achieve the same accuracy, the number of elements required by the proposed method is much less than that of the tesseroid-based method, which substantially speeds up the calculation by more than 2 orders. The application to the tessellated LITHO1.0 model further demonstrates its capability and practicability in realistic situations. The new method offers an attractive tool for gravity forward and inverse problems where the irregular grids are involved.

Abstract Image

利用深度多项式密度三角形球面棱镜进行引力场三维大尺度正演建模
为了将地球的球面性考虑在内,在大规模引力前向建模中,通常会使用方格网作为网格元素。然而,纬度-经度网格中的此类元素在极点附近会退化为形状不佳的三角形。此外,在描述具有不规则边界的横向可变密度分布时,棋盘格的灵活性有限,而且在实现重力反演所需的球面完全等效划分方面也面临困难。我们开发了一种基于三角球面棱镜(TSP)的新方法,用于球面坐标中的三维重力建模。TSP 由两个三角形球面定义,其中一个是另一个的径向投影。由于上下表面均为球形三角形,因此 TSP 在描述不同横向分辨率的质量密度时,比方块体具有更多优势。此外,这种元素还允许在球面坐标中以几乎相等的权重进行细分。为了计算 TSP 的重力效应,我们假设每个元素的密度沿径向为多项式,以适应复杂的密度环境。然后,我们使用混合高斯正交法求解牛顿体积积分,其中球面三角形上的表面积分是通过将球面三角形转化为线性三角形的径向投影,使用基于三角形的高斯正交规则计算的。此外,还结合了二维自适应离散化策略和扩展技术,以提高质量源附近观测点的精度。基于球壳模型的数值实验表明,在具有不同尺寸和密度变化的 TSP 的情况下,所提出的方法从近表面到卫星高度都能达到很好的精度。与经典的基于魔方的方法相比,所提出的算法对于横向不规则形状的密度模型具有更好的精度和更高的灵活性。结果表明,在达到相同精度的情况下,拟议方法所需的元素数量远远少于基于魔方的方法,这大大加快了计算速度 2 个数量级以上。对 LITHO1.0 网格模型的应用进一步证明了该方法在现实情况下的能力和实用性。新方法为涉及不规则网格的重力正演和反演问题提供了极具吸引力的工具。
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来源期刊
Journal of Geodesy
Journal of Geodesy 地学-地球化学与地球物理
CiteScore
8.60
自引率
9.10%
发文量
85
审稿时长
9 months
期刊介绍: The Journal of Geodesy is an international journal concerned with the study of scientific problems of geodesy and related interdisciplinary sciences. Peer-reviewed papers are published on theoretical or modeling studies, and on results of experiments and interpretations. Besides original research papers, the journal includes commissioned review papers on topical subjects and special issues arising from chosen scientific symposia or workshops. The journal covers the whole range of geodetic science and reports on theoretical and applied studies in research areas such as: -Positioning -Reference frame -Geodetic networks -Modeling and quality control -Space geodesy -Remote sensing -Gravity fields -Geodynamics
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