Abstract
Precise Point Positioning (PPP), initially developed for the analysis of the Global Positing System (GPS) data from a large geodetic network, gradually becomes an effective tool for positioning, timing, remote sensing of atmospheric water vapor, and monitoring of Earth’s ionospheric Total Electron Content (TEC). The previous studies implicitly assumed that the receiver code biases stay constant over time in formulating the functional model of PPP. In this contribution, it is shown this assumption is not always valid and can lead to the degradation of PPP performance, especially for Slant TEC (STEC) retrieval and timing. For this reason, the PPP functional model is modified by taking into account the time-varying receiver code biases of the two frequencies. It is different from the Modified Carrier-to-Code Leveling (MCCL) method which can only obtain the variations of Receiver Differential Code Biases (RDCBs), i.e., the difference between the two frequencies’ code biases. In the Modified PPP (MPPP) model, the temporal variations of the receiver code biases become estimable and their adverse impacts on PPP parameters, such as ambiguity parameters, receiver clock offsets, and ionospheric delays, are mitigated. This is confirmed by undertaking numerical tests based on the real dual-frequency GPS data from a set of global continuously operating reference stations. The results imply that the variations of receiver code biases exhibit a correlation with the ambient temperature. With the modified functional model, an improvement by 42% to 96% is achieved in the Differences of STEC (DSTEC) compared to the original PPP model with regard to the reference values of those derived from the Geometry-Free (GF) carrier phase observations. The medium and long term (1 × 104 to 1.5 × 104 s) frequency stability of receiver clocks are also significantly improved.
Highlights
In exploring the potential of Global Positioning System (GPS) for a variety of applications, Precise Point Positioning (PPP) has been developed as a tool for processing code and phase observations from a stand-alone GPS receiver at the undifferenced level (Zumberge et al 1997a) along with the use of precise satellite orbit andZhang et al Satell Navig (2021) 2:11 land-vehicle navigation (Rabbou and El-Rabbany 2015; Wielgosz et al 2005)
The original PPP model cannot give optimal results, because it implicitly assumes receiver code biases are constant over the time course of interest
To account for this, the PPP functional model was modified by assuming that the receiver code biases can vary freely in time
Summary
In exploring the potential of Global Positioning System (GPS) for a variety of applications, Precise Point Positioning (PPP) has been developed as a tool for processing code and phase observations from a stand-alone GPS receiver at the undifferenced level (Zumberge et al 1997a) along with the use of precise satellite orbit andZhang et al Satell Navig (2021) 2:11 land-vehicle navigation (Rabbou and El-Rabbany 2015; Wielgosz et al 2005). In the implementation of PPP, one needs to formulate the functional model (i.e., observation equations), relating the GPS observations to the parameters to be estimated. One assumption underlying this formulation is that the receiver code biases do not change significantly over time (Banville and Langley 2011b; Håkansson et al 2017). For the ionospheric Slant Total Electron Content (STEC) retrieval, the Modified Carrier-to-Code Leveling (MCCL) method (Zhang et al 2019), as well as the integer-levelling procedure (Banville and Langley 2011a; Banville et al 2012) can both effectively eliminate the effect of receiver code bias variations. As far as the GPSbased timing application is concerned, there are still a limited amount of research focusing on how to cope with the time-varying receiver code biases
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