Abstract
The GOCE satellite was orbiting the Earth in a Sun-synchronous orbit at a very low altitude for more than 4 years. This low orbit and the availability of high-quality data make it worthwhile to assess the contribution of GOCE GPS data to the recovery of both the static and time-variable gravity fields. We use the kinematic positions of the official GOCE precise science orbit (PSO) product to perform gravity field determination using the Celestial Mechanics Approach. The generated gravity field solutions reveal severe systematic errors centered along the geomagnetic equator. Their size is significantly coupled with the ionospheric density and thus generally increasing over the mission period. The systematic errors may be traced back to the kinematic positions of the PSO product and eventually to the ionosphere-free GPS carrier phase observations used for orbit determination. As they cannot be explained by the current higher order ionospheric correction model recommended by the IERS Conventions 2010, an empirical approach is presented by discarding GPS data affected by large ionospheric changes. Such a measure yields a strong reduction of the systematic errors along the geomagnetic equator in the gravity field recovery, and only marginally reduces the set of useable kinematic positions by at maximum 6 % for severe ionosphere conditions. Eventually it is shown that GOCE gravity field solutions based on kinematic positions have a limited sensitivity to the largest annual signal related to land hydrology.
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Acknowledgments
This work was partly performed in the framework of the GOCE High-level Processing Facility (HPF), which is funded by ESA. The support of ESA is gratefully acknowledged. We also thank M. Weigelt for adopting the Kalman filter approach to the 20-day GOCE gravity field solutions.
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Jäggi, A., Bock, H., Meyer, U. et al. GOCE: assessment of GPS-only gravity field determination. J Geod 89, 33–48 (2015). https://doi.org/10.1007/s00190-014-0759-z
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DOI: https://doi.org/10.1007/s00190-014-0759-z