Precise Orbit Determination for GNSS Maneuvering Satellite with the Constraint of a Predicted Clock

Autor:	Jing Qiao, Yaquan Peng, Dai Zhiqiang, Xiaolei Dai, Yidong Lou, Chuang Shi, Caibo Hu
Jazyk:	angličtina
Rok vydání:	2019
Předmět:	010504 meteorology & atmospheric sciences Science BeiDou Navigation Satellite System Precise Point Positioning reverse precise point positioning 01 natural sciences 0103 physical sciences precise orbit determination satellite maneuver clock prediction 010303 astronomy & astrophysics 0105 earth and related environmental sciences Physics GNSS business.industry Geosynchronous orbit Precise orbit determination Satellite maneuver Clock prediction Reverse precise point positioning Geodesy GNSS applications Global Positioning System Geostationary orbit General Earth and Planetary Sciences Satellite Orbit determination business
Zdroj:	Remote Sensing, Vol 11, Iss 16, p 1949 (2019) Remote Sensing Volume 11 Issue 16 Pages: 1949 Remote Sensing, 11 (16)
ISSN:	2072-4292
Popis:	Precise orbit products are essential and a prerequisite for global navigation satellite system (GNSS) applications, which, however, are unavailable or unusable when satellites are undertaking maneuvers. We propose a clock-constrained reverse precise point positioning (RPPP) method to generate the rather precise orbits for GNSS maneuvering satellites. In this method, the precise clock estimates generated by the dynamic precise orbit determination (POD) processing before maneuvering are modeled and predicted to the maneuvering periods and they constrain the RPPP POD during maneuvering. The prediction model is developed according to different clock types, of which the 2-h prediction error is 0.31 ns and 1.07 ns for global positioning system (GPS) Rubidium (Rb) and Cesium (Cs) clocks, and 0.45 ns and 0.60 ns for the Beidou navigation satellite system (BDS) geostationary orbit (GEO) and inclined geosynchronous orbit (IGSO)/Median Earth orbit (MEO) satellite clocks, respectively. The performance of this proposed method is first evaluated using the normal observations without maneuvers. Experiment results show that, without clock-constraint, the average root mean square (RMS) of RPPP orbit solutions in the radial, cross-track and along-track directions is 69.3 cm, 5.4 cm and 5.7 cm for GPS satellites and 153.9 cm, 12.8 cm and 10.0 cm for BDS satellites. When the constraint of predicted satellite clocks is introduced, the average RMS is dramatically reduced in the radial direction by a factor of 7–11, with the value of 9.7 cm and 13.4 cm for GPS and BDS satellites. At last, the proposed method is further tested on the actual GPS and BDS maneuver events. The clock-constrained RPPP POD solution is compared to the forward and backward integration orbits of the dynamic POD solution. The resulting orbit differences are less than 20 cm in all three directions for GPS satellite, and less than 30 cm in the radial and cross-track directions and up to 100 cm in the along-track direction for BDS satellites. From the orbit differences, the maneuver start and end time is detected, which reveals that the maneuver duration of GPS satellites is less than 2 min, and the maneuver events last from 22.5 min to 107 min for different BDS satellites. Remote Sensing, 11 (16) ISSN:2072-4292
Databáze:	OpenAIRE
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