球面径向基函数非线性优化在区域重力场建模中的应用

IF 0.5 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS
Hany Mahbuby, Yazdan Amerian, Amirhossein Nikoofard, Mehdi Eshagh
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引用次数: 3

摘要

重力场是地球质量分布和内部结构的标志,除了它的所有大地测量应用之外,特别是大地水准面确定和垂直基准统一。区域重力场模型的确定是一个重要的课题,需要进一步研究和发展。本文将球面径向基函数(sbf)应用于重力异常插值和物理大地测量学基本方程求解两种场景,以确定大地水准面或扰动势,并有可能通过全球导航卫星系统(GNSS)/水准测量数据进行验证。合理选择小波场的数量和最佳位置是提高估计精度的重要因素。在此基础上,采用截断奇异值分解的高斯-牛顿优化方法对重力异常进行插值,并提出了一种基于线搜索的准牛顿插值方法,以解决迭代次数较少的最小化问题。针对目标函数的Hessian矩阵不总是正定的情况,采用截断牛顿优化方法求解物理大地测量学基本方程。将这两种情况应用于地形粗糙的奥弗涅地区的地面自由空气重力异常。插值后的重力异常模型精度为1.7 mGal,其中点质量数约为观测数的30%,而在第二种情况下,使用的核数也为30%,其精度为1.5 mGal。这些精度是各监测点重力异常预测值与观测值之差的均方根误差(RMSE)。此外,利用第二种方案构建的最优模型,模型得出的重力高度异常与GNSS/水准点的几何高度异常之间的差异的RMSE为9 cm。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Application of the nonlinear optimisation in regional gravity field modelling using spherical radial base functions

The gravity field is a signature of the mass distribution and interior structure of the Earth, in addition to all its geodetic applications especially geoid determination and vertical datum unification. Determination of a regional gravity field model is an important subject and needs to be investigated and developed. Here, the spherical radial basis functions (SBFs) are applied in two scenarios for this purpose: interpolating the gravity anomalies and solving the fundamental equation of physical geodesy for geoid or disturbing potential determination, which has the possibility of being verified by the Global Navigation Satellite Systems (GNSS)/levelling data. Proper selections of the number of SBFs and optimal location of the applied SBFs are important factors to increase the accuracy of estimation. In this study, the gravity anomaly interpolation based on the SBFs is performed by Gauss-Newton optimisation with truncated singular value decomposition, and a Quasi-Newton method based on line search to solve the minimisation problems with a small number of iterations is developed. In order to solve the fundamental equation of physical geodesy by the SBFs, the truncated Newton optimisation is applied as the Hessian matrix of the objective function is not always positive definite. These two scenarios are applied on the terrestrial free-air gravity anomalies over the topographically rough area of Auvergne. The obtained accuracy for the interpolated gravity anomaly model is 1.7 mGal with the number of point-masses about 30% of the number of observations, and 1.5 mGal in the second scenario where the number of used kernels is also 30%. These accuracies are root mean square errors (RMSE) of the differences between predicted and observed gravity anomalies at check points. Moreover, utilising the optimal constructed model from the second scenario, the RMSE of 9 cm is achieved for the differences between the gravimetric height anomalies derived from the model and the geometric height anomalies from GNSS/levelling points.

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来源期刊
Studia Geophysica et Geodaetica
Studia Geophysica et Geodaetica 地学-地球化学与地球物理
CiteScore
1.90
自引率
0.00%
发文量
8
审稿时长
6-12 weeks
期刊介绍: Studia geophysica et geodaetica is an international journal covering all aspects of geophysics, meteorology and climatology, and of geodesy. Published by the Institute of Geophysics of the Academy of Sciences of the Czech Republic, it has a long tradition, being published quarterly since 1956. Studia publishes theoretical and methodological contributions, which are of interest for academia as well as industry. The journal offers fast publication of contributions in regular as well as topical issues.
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