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Journal of Geodesy

, Volume 90, Issue 8, pp 727–739 | Cite as

Spherical gravitational curvature boundary-value problem

  • Michal ŠprlákEmail author
  • Pavel Novák
Original Article

Abstract

Values of scalar, vector and second-order tensor parameters of the Earth’s gravitational field have been collected by various sensors in geodesy and geophysics. Such observables have been widely exploited in different parametrization methods for the gravitational field modelling. Moreover, theoretical aspects of these quantities have extensively been studied and well understood. On the other hand, new sensors for observing gravitational curvatures, i.e., components of the third-order gravitational tensor, are currently under development. As the gravitational curvatures represent new types of observables, their exploitation for modelling of the Earth’s gravitational field is a subject of this study. Firstly, the gravitational curvature tensor is decomposed into six parts which are expanded in terms of third-order tensor spherical harmonics. Secondly, gravitational curvature boundary-value problems defined for four combinations of the gravitational curvatures are formulated and solved in spectral and spatial domains. Thirdly, properties of the corresponding sub-integral kernels are investigated. The presented mathematical formulations reveal some important properties of the gravitational curvatures and extend the so-called Meissl scheme, i.e., an important theoretical framework that relates various parameters of the Earth’s gravitational field.

Keywords

Boundary-value problem Differential operator Gravitational curvature Integral transformation  Tensor spherical harmonics 

Notes

Acknowledgments

The authors were supported by the project No. GA15-08045S of the Czech Science Foundation. Thoughtful and constructive comments of the three anonymous reviewers are gratefully acknowledged. Thanks are also extended to the editor-in-chief J. Kusche and the responsible editor W. Keller for handling our manuscript.

Supplementary material

190_2016_905_MOESM1_ESM.pdf (22 kb)
Supplementary material 1 (pdf 21 KB)

Supplementary material 2 (mpeg 11608 KB)

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Copyright information

© Springer-Verlag Berlin Heidelberg 2016

Authors and Affiliations

  1. 1.NTIS - New Technologies for the Information Society, Faculty of Applied SciencesUniversity of West BohemiaPlzeňCzech Republic

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