A new strategy for the atmospheric gravity effect in gravimetric geoid determination
Journal article, Peer reviewed
Accepted version
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https://hdl.handle.net/11250/3066426Utgivelsesdato
2004Metadata
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Sammendrag
Prior to Stokes integration, the gravitational effect of atmospheric masses must be removed from the gravity anomaly g. One theory for the atmospheric gravity effect on the geoid is the well-known International Association of Geodesy approach in connection with Stokes integral formula. Another strategy is the use of a spherical harmonic representation of the topography, i.e. the use of a global topography computed from a set of spherical harmonics. The latter strategy is improved to account for local information. A new formula is derived by combining the local contribution of the atmospheric effect computed from a detailed digital terrain model and the global contribution computed from a spherical harmonic model of the topography. The new formula is tested over Iran and the results are compared with corresponding results from the old formula which only uses the global information. The results show significant differences. The differences between the two formulas reach 17 cm in a test area in Iran. Key words: Atmospheric effect - Geoid - Stokes formula - Spherical harmonics A new strategy for the atmospheric gravity effect in gravimetric geoid determination