Performance of a solution of the direct geodetic problem by Taylor series of Cartesian coordinates

IF 0.9 Q4 REMOTE SENSING
C. Marx
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引用次数: 1

Abstract

Abstract The direct geodetic problem is regarded on the biaxial and triaxial ellipsoid. A known solution method suitable for low eccentricities, which uses differential equations in Cartesian coordinates and Taylor series expansions of these coordinates, is advanced in view of its practical application. According to previous works, this approach has the advantages that no singularities occur in the determination of the coordinates, its mathematical formulation is simple and it is not computationally intensive. The formulas of the solution method are simplified in the present contribution. A test of this method using an extensive test data set on a biaxial earth ellipsoid shows its accuracy and practicability for distances of any length. Based on the convergence behavior of the series of the test data set, a truncation criterion for the series expansions is compiled taking into account accuracy requirements of the coordinates. Furthermore, a procedure is shown which controls the truncation of the series expansions by accuracy requirements of the direction to be determined in the direct problem. The conducted tests demonstrate the correct functioning of the methods for the series truncation. However, the considered solution method turns out to be significantly slower than another current method for biaxial ellipsoids, which makes it more relevant for triaxial ellipsoids.
用笛卡尔坐标的泰勒级数求解直接大地测量问题的表现
摘要研究了双轴和三轴椭球体上的直接大地测量问题。结合实际应用,提出了一种已知的低偏心率问题的求解方法,即利用笛卡尔坐标系下的微分方程及其泰勒级数展开。根据前人的工作,该方法的优点是在确定坐标时不出现奇点,数学公式简单,计算量小。本文对求解法的公式进行了简化。在双轴地球椭球上对该方法进行了广泛的测试数据集测试,结果表明该方法对任意长度的距离都具有准确性和实用性。基于测试数据集序列的收敛性,考虑坐标精度要求,编制了序列展开式的截断准则。在此基础上,给出了一种根据直接问题中待确定方向的精度要求来控制级数展开截断的方法。所进行的测试证明了该方法对序列截断的正确作用。然而,所考虑的求解方法比目前的另一种求解双轴椭球体的方法要慢得多,这使得它更适用于三轴椭球体。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Geodetic Science
Journal of Geodetic Science REMOTE SENSING-
CiteScore
1.90
自引率
7.70%
发文量
3
审稿时长
14 weeks
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