Error bounds for the spectral approximation of the potential of a homogeneous almost spherical body

Error bounds for the spectral approximation of the potential of a homogeneous almost spherical body

Several kinds of approximation of the gravitational potential of a homogeneous body by truncated spherical harmonics series are in use in physical geodesy. However, only one of them is capable of a representation converging to the true potential in the whole layer between the Brillouin sphere and th...

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Bibliographic Details
Published in:Studia geophysica et geodaetica Vol. 65; no. 3-4; pp. 235 - 260
Main Authors: Bucha, Blažej, Rossi, Lorenzo, Sansò, Fernando
Format: Journal Article
Language:English
Published: Dordrecht Springer Netherlands 01-10-2021
Springer Nature B.V
Subjects:
Approximation
Atmospheric Sciences
Computation
Convergence
Distribution functions
Earth and Environmental Science
Earth Sciences
Errors
Geodesy
Geophysics/Geodesy
Gravity
Mathematical analysis
Norms
Spherical harmonics
Structural Geology
Upper bounds
gravity field
convergence theory
numerical bounds
homogeneous bodies
spectral approximation
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Summary:Several kinds of approximation of the gravitational potential of a homogeneous body by truncated spherical harmonics series are in use in physical geodesy. However, only one of them is capable of a representation converging to the true potential in the whole layer between the Brillouin sphere and the Bjerhammar sphere of the body. We aim at providing various majorizations, namely upper bounds, of the error with the double purpose of proving explicitly the convergence in the sense of different norms and of giving computable bounds, that might be used in numerical studies. The first aim is reached for all the norms. For the second, however, it turns out that among the bounds, when applied to the example of the terrain correction of the Earth, only those referring to the mean absolute error and the mean squared error at the level of Brillouin sphere of minimum radius give significant and useful results. In order to make the computation an easy exercise, a simple approximate formula has been developed requiring only the use of the distribution function of the heights of the surface of the body with respect to the Bjerhammar sphere.
ISSN:0039-3169
1573-1626
DOI:10.1007/s11200-021-0730-4