Michael Sheng scite author profile

Abstract:The aim of this paper is to show a present state-of-the-art precise gravimetric geoid determination using the UNB Stokes-Helmert's technique in a simple schematic way. A detailed description of a practical application of this technique in the Auvergne test area is also provided. In this paper, we discuss the most problematic parts of the solution: correct application of topographic and atmospheric effects including the lateral topographical density variations, downward continuation of gravity anomalies from the Earth surface to the geoid, and the optimal incorporation of the global gravity field into the final geoid model. The final model is tested on 75 GNSS/levelling points supplied with normal Molodenskij heights, which for this investigation are transformed to rigorous orthometric heights. The standard deviation of the computed geoid model is 3.3 cm without applying any artificial improvement which is the same as that of the most accurate quasigeoid.

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In defense of the classical height system

Foroughi¹,

Vaníček²,

Sheng³

et al. 2017

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Michael Sheng

Formulation and validation of a global laterally varying topographical density model

Sub-centimetre geoid

Computation of precise geoid model of Auvergne using current UNB Stokes-Helmert’s approach

In defense of the classical height system

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