Journal of Geodesy

, Volume 91, Issue 4, pp 345–360 | Cite as

CODE’s five-system orbit and clock solution—the challenges of multi-GNSS data analysis

  • Lars Prange
  • Etienne Orliac
  • Rolf Dach
  • Daniel Arnold
  • Gerhard Beutler
  • Stefan Schaer
  • Adrian Jäggi
Original Article

Abstract

This article describes the processing strategy and the validation results of CODE’s MGEX (COM) orbit and satellite clock solution, including the satellite systems GPS, GLONASS, Galileo, BeiDou, and QZSS. The validation with orbit misclosures and SLR residuals shows that the orbits of the new systems Galileo, BeiDou, and QZSS are affected by modelling deficiencies with impact on the orbit scale (e.g., antenna calibration, Earth albedo, and transmitter antenna thrust). Another weakness is the attitude and solar radiation pressure (SRP) modelling of satellites moving in the orbit normal mode—which is not yet correctly considered in the COM solution. Due to these issues, we consider the current state COM solution as preliminary. We, however, use the long-time series of COM products for identifying the challenges and for the assessment of model-improvements. The latter is demonstrated on the example of the solar radiation pressure (SRP) model, which has been replaced by a more generalized model. The SLR validation shows that the new SRP model significantly improves the orbit determination of Galileo and QZSS satellites at times when the satellite’s attitude is maintained by yaw-steering. The impact of this orbit improvement is also visible in the estimated satellite clocks—demonstrating the potential use of the new generation satellite clocks for orbit validation. Finally, we point out further challenges and open issues affecting multi-GNSS data processing that deserves dedicated studies.

Keywords

IGS CODE Multi-GNSS ECOM Solar radiation pressure model Orbit determination Satellite clock 

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Copyright information

© Springer-Verlag Berlin Heidelberg 2016

Authors and Affiliations

  1. 1.Astronomical Institute of the University of BernBernSwitzerland
  2. 2.Bundesamt für Landestopografie swisstopoWabernSwitzerland

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