Low Earth Orbit Determination for GNSS Radio Occultation with Aspects of Uncertainty Estimation
Christian PockThis investigation focuses:
In the first part, on a precise orbit determination of Low Earth Orbiting (LEO) satellites. These LEO satellites, namely CHAMP, GRACE-A, FORMOSAT-3/COSMIC and MetOp-A, are very important for various scientific disciplines. In geodesy, for example, these missions are required for highly accurate measurements of the global Earth’s gravity field.
In the context of this work, these satellite missions are finally used for the GNSSradio occultation method, which is closely connected to climate research. This method is based on propagating radio signals through the atmosphere. These signals are emitted from GNSS satellites and received by LEOs. Due to the varying atmospheric density, this affects the radio signal and a phase path extension as a function of time occurs. Based on these measurements, other climate relevant parameters such as refractivity and temperature can be determined. To compute the atmospheric excess phase, highly accurate LEO positions and velocities are needed. Therefore, the required processing strategy has to ensure excellent orbit quality independent of the specified LEO mission. This goal has been achieved. An independent validation with data from the established analysis centers CODE, JPL, UCAR and EUMETSAT shows highly consistent results.
The second part of the work deals with the issue of position and velocity uncertainty. This includes both the LEO and the GNSS satellites. It is very difficult to quantify these uncertainties because usually the real orbit is unknown. Nevertheless, some ideas are collected to capture the uncertainty. This includes for example how uncertainties of the orbit positions are affecting the satellite velocity.