Abstract
High-rate precise satellite clock corrections are essential for precise point positioning (PPP) with global navigation satellite system (GNSS), especially for kinematic PPP (KPPP) for low earth orbiting satellites or moving vehicles on the ground where positioning precision of a few centimeters is demanded. To estimate high-rate clock corrections in a full network solution using zero-difference observations from a large tracking network (e.g., 100 stations) is quite time-consuming which even goes worse with increasing satellites. An efficient approach with estimation of high-rate epoch-difference clocks and a densification procedure to compute high-rate zero-difference clocks based on lower rate zero-difference clocks is developed at Xi’an Research Institute of Surveying and Mapping (XISM) to routinely produce 30-s “rapid” and “final” satellite clocks for the existing GNSS: GPS, GLONASS, BDS, and Galileo. In this paper, basic principle and data processing procedure are described in detail. The GPS clocks at XISM are compared with IGS final clocks to validate their quality and it is demonstrated that both the XISM 30-s and 5-min clocks are in essence the same in quality as clocks provided by IGS analysis centers. When the XISM clocks are used to assess the frequency stability performance of GPS satellites, a good agreement with IGS final clocks is again demonstrated,which further confirms the good quality of clock products at XISM. With the 30-s clocks, the frequency stability performance of GPS, GLONASS, BDS, and Galileo satellites is assessed for a time interval ranging from 30 s to about 15,000 s, which demonstrate a pretty good stability performance of BDS satellites for short intervals, even superior to GPS Block IIR and GLONASS-M satellites. Finally, experiments for KPPP with individual GPS, GLONASS, or BDS are conducted with the XISM 30-s and 5-min clocks to evaluate the impact of clock sampling rate. The result shows that, compared with the result with 5-min clocks, 3D repeatability with 30-s clocks is improved by about 67, 72, and 24% for GPS-, GLONASS-, and BDS KPPP, respectively, and it is interesting that when using 5-min clocks, KPPP with BDS has better repeatability performance than using GPS or GLONASS, which may benefit from the comparative good stability performance of almost the whole BDS constellation for short time interval.
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References
Blewitt G (1990) An automatic editing algorithm for GPS data. Geophys Res Lett 17:199–202
Bock H, Dach R, Jggi A, Beutler G (2009) High-rate GPS clock corrections from CODE: support of 1 Hz applications. J Geodesy 83: 1083–1094
Chen J, Zhang Y, Zhou X, Pei X, Wang J, Wu B (2013) GNSS clock corrections densification at SHAO: from 5 min to 30 s Sci China-Phys Mech Astron 56: 1–10
Jiao W (2012) Architecture and current development of iGMAS CSNC 2012. Guangzhou, China
Kleusberg A, Teunissen PJG (eds) (1996) GPS for Geodesy. Springer, Berlin
Lichten SM, Border JS (1987) Strategies for high-precision global positioning system orbit determination. J Geophys Res 92:12751–12762
Mccarthy DD, Petit GE (2004) IERS conventions (2003). In: Mccarthy DD, Petit GE (eds) IERS technical note no. 32. Verlag des Bundesamtes für Kartographie und Geodäsie, Frankfurt am Main 2004
Montenbruck O, Gill E, Kroes R (2005) Rapid orbit determination of LEO satellites using IGS clock and ephemeris products. GPS Solutions 2005:226–235
Montenbruck O, Steigenberger P, Khachikyan R, Weber G, Langley RB, Mervart L, Hugentobler U (2014) IGS-MGEX: preparing the ground for multi-constellation GNSS science. InsideGNSS 9:42–49
Ruan R (2009) Study on GPS precise point positioning using un-differenced carrier phase. Zhengzhou, China, Information Engineering University
Ruan R, Jia X, Wu X, Feng L, Zhu Y (2014) SPODS software and its result of precise orbit determination for GNSS satellites. China Satellite Navigation Conference (CSNC) 2014 Proceedings, vol III. Nanjing
Schmid R, Dach R, Collilieux X, Jggi A, Schmitz M, Dilssner F (2016) Absolute IGS antenna phase center model igs08.atx: status and potential improvements. J Geodesy 90: 343–364
Senior KL, Ray JR, Beard RL (2008) Characterization of periodic variations in the GPS satellite clocks. GPS Solutions 12:211–225
Steigenberger P, Hugentobler U, Hauschild A, Montenbruck O (2013) Orbit and clock analysis of compass GEO and IGSO satellites. J Geodesy 87:515–525
Wei Z, Ruan R, Jia X, Wu X, Song X, Mao Y, Feng L, Zhu Y (2014) Satellite positioning and orbit determination system SPODS: theory and test. Acta Geodaetica Cartogr Sin 43:1–4
Wu JT, Wu SC, Hajj GA, Bertiger WI, Lichten SM (1993) Effects of antenna orientation on GPS carrier phase. Manuscripta Geodaetic: 91–98
Zumberge JF, Heftin MB, Jefferson DC, Watkins MM, Webb FH (1997) Precise point positioning for the efficient and robust analysis of GPS data from large networks. J Geophys Res 102:5005–5017
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Ruan, R., Wei, Z., Jia, X. (2017). Estimation, Validation, and Application of 30-s GNSS Clock Corrections. In: Sun, J., Liu, J., Yang, Y., Fan, S., Yu, W. (eds) China Satellite Navigation Conference (CSNC) 2017 Proceedings: Volume III. CSNC 2017. Lecture Notes in Electrical Engineering, vol 439. Springer, Singapore. https://doi.org/10.1007/978-981-10-4594-3_3
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DOI: https://doi.org/10.1007/978-981-10-4594-3_3
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