Abstract
So far, three methods have been developed to determine GNSS antenna phase center variations (PCV). For this reason, and because of some problems in introducing absolute models, there are presently three models of PCV receiver antennas (relative, absolute converted and absolute) and two satellite antennas (standard and absolute). Additionally, when simultaneously processing observations from different positioning systems (e.g. GPS and GLONASS), we can expect a further complication resulting from the different structure of signals and differences in satellite constellations. This paper aims at studying the height differences in short static GPS/GLONASS observation processing when different calibration models are used. The analysis was done using 3 days of GNSS data, collected with three different receivers and antennas, divided by half hour observation sessions. The results show that switching between relative and absolute PCV models may have a visible effect on height determination, particularly in high accuracy applications. The problem is especially important when mixed GPS/GLONASS observations are processed. The update of receiver antenna calibrations model from relative to absolute in our study (using LEIAT504GG, JAV_GRANT-G3T and TPSHIPER_PLUS antennas) induces a jump (depending on the measurement session) in the vertical component within to 1.3 cm (GPS-only solutions) or within 1.9 cm (GPS/GLONASS solutions).
Highlights
The electrical antenna phase center is the point in space where the GNSS signal is received
The aim of this paper is to study the height differences in short static GPS/GLONASS observation processing when different calibration models are used
This paper presents the height differences obtained in short baseline
Summary
The electrical antenna phase center is the point in space where the GNSS signal is received. That point varies depending on the frequency and the direction of the incoming signal, i.e. the elevation angle and azimuth to the satellite. Elevation is the pointing angle from the horizon to the satellite. Some antenna points must be defined (Figure 1). The first of them is the mean position of the electrical antenna phase center (MPC). The antenna reference point (ARP) is defined by the IGS as the intersection of antenna’s vertical axis of symmetry with the bottom of the antenna. The antenna phase center offset (PCO) is a 3d displacement vector between the average frequency-dependent phase center and the antenna reference point. The antenna phase center variations (PCV) is the deviation between the positions of the electrical antenna phase center of an individual measurement and the mean electrical antenna phase center
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