Abstract
Since the first pair of BeiDou satellites was deployed in 2000, China has made continuous efforts to establish its own independent BeiDou Navigation Satellite System (BDS) to provide the regional radio determination satellite service as well as regional and global radio navigation satellite services, which rely on the high quality of orbit and clock products. This article summarizes the achievements in the precise orbit determination (POD) of BDS satellites in the past decade with the focus on observation and orbit dynamic models. First, the disclosed metadata of BDS satellites is presented and the contribution to BDS POD is addressed. The complete optical properties of the satellite bus as well as solar panels are derived based on the absorbed parameters as well the material properties. Secondly, the status and tracking capabilities of the L-band data from accessible ground networks are presented, while some low earth orbiter satellites with onboard BDS tracking capability are listed. The topological structure and measurement scheme of BDS Inter-Satellite-Link (ISL) data are described. After highlighting the progress on observation models as well as orbit perturbations for BDS, e.g., phase center corrections, satellite attitude, and solar radiation pressure, different POD strategies used for BDS are summarized. In addition, the urgent requirement for error modeling of the ISL data is emphasized based on the analysis of the observation noises, and the incompatible characteristics of orbit and clock derived with L-band and ISL data are illuminated and discussed. The further researches on the improvement of phase center calibration and orbit dynamic models, the refinement of ISL observation models, and the potential contribution of BDS to the estimation of geodetic parameters based on L-band or ISL data are identified. With this, it is promising that BDS can achieve better performance and provides vital contributions to the geodesy and navigation.
Highlights
Global Navigation Satellite System (GNSS) is the essential technology to provide space and time information
The results show that the discrepancy between the estimated and the ground calibrated Phase Center Offsets (PCO) is within a decimeter, and the estimation is affected by the receiver antenna models as well as the Solar radiation pressure (SRP) model
With FengYun-3C onboard data, the similar biases are identified for Inclined GeoSynchronous Orbit (IGSO) and Medium Earth Orbit (MEO) with the elevation angles above 40°, while larger discrepancy is observed for the elevation angles below 40° possibly due to that the measurements are smoothed (Zhao et al, 2017)
Summary
Global Navigation Satellite System (GNSS) is the essential technology to provide space and time information. Metadata of BDS satellites Satellite metadata, the definition and description of satellite properties, includes unique identifiers like Satellite Vehicle Number (SVN), time of life, the geometry properties (e.g., attitude, the position of mass center, transmit antenna and laser retroreflector array, the shape as well as the dimensions of satellite panels or bus), and the physical properties (e.g., materials, mass, transmit power of signals, optical and thermal properties) They are vital for the accurate modeling of GNSS satellites, for the non-conservative perturbation modeling. These disclosed metadata can be used for the precise analysis of BDS data It is not enough for orbit dynamic modeling, the SRP, Earth Radiation Pressure (ERP) and antenna thrust, as the specular and diffuse reflection coefficients as well as the signal transmit power are missing. At the beginning of 2019, except for Javad TRE-3 Delta receiver and iGMAS receivers capable to track all deployed BDS-3 satellites, Trimble receivers can only
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