Precise orbit determination for BDS-3 satellites using satellite-ground and inter-satellite link observations

Since November 2017, eight BeiDou global navigation system (BDS-3) satellites equipped with Ka-band inter-satellite link (ISL) payloads have been launched into medium earth orbit. We present the precise orbit determination (POD) for BDS-3 satellites using both L-band satellite-ground and Ka-band ISL observations. The satellite-ground tracking data are collected from the international GNSS Monitoring and Assessment System stations. The data period is DOY (day of year) 127–156, 2018. The BDS-3 ISL measurements are described by a dual one-way observation model. After transforming the dual one-way observations to the same epoch, clock-free and geometry-free observables can be obtained by the addition and subtraction of dual one-way observations. Using the geometry-free observables, the ISL measurement noise is analyzed and confirmed to be less than 10 cm. Using the clock-free observables and ground tracking data, the precise orbits are determined together with combined ISL hardware delays. For the estimates of hardware delays, the mean STD is 0.08 ns. For the satellite orbits, the ground-only POD solutions are also computed for comparison. When using 16 globally distributed ground stations, the addition of the ISLs improves the POD performance. For example, the 3D RMS of orbit overlap differences is reduced from 15.9 cm to 9.2 cm, yielding an improvement of 42% compared to ground-only POD. When only 6 stations in China are used for POD, the addition of ISLs enables the 3D RMS to be reduced from 85.4 cm to 14.8 cm with a greater improvement of 83%.

[1]  P. Anderson,et al.  Communication architecture for GPS III , 2004, 2004 IEEE Aerospace Conference Proceedings (IEEE Cat. No.04TH8720).

[2]  Tianhe Xu,et al.  An Initial Analysis and Assessment on Final Products of iGMAS , 2016 .

[3]  Lorenzo Galleani,et al.  Inter-satellite links for satellite autonomous integrity monitoring , 2011 .

[4]  Wang Ziyu,et al.  Performance Analysis and Progress of Inter-satellite-link of Beidou System , 2017 .

[5]  Harold Bernstein,et al.  GPS User Position Accuracy with Block IIR Autonomous Navigation , 1993 .

[6]  Chengpan Tang,et al.  Time synchronization of new-generation BDS satellites using inter-satellite link measurements , 2018 .

[7]  Xiaogong Hu,et al.  Performance of the BDS3 experimental satellite passive hydrogen maser , 2018, GPS Solutions.

[8]  Bin Wang,et al.  Performance of BDS-3: Measurement Quality Analysis, Precise Orbit and Clock Determination , 2017, Sensors.

[9]  Gang Li,et al.  Globalization highlight: orbit determination using BeiDou inter-satellite ranging measurements , 2017, GPS Solutions.

[10]  G. Beutler,et al.  A new solar radiation pressure model for GPS , 1999 .

[11]  Qile Zhao,et al.  Precise orbit and clock determination for BeiDou-3 experimental satellites with yaw attitude analysis , 2017, GPS Solutions.

[12]  Feixue Wang,et al.  Optimization design of inter-satellite link (ISL) assignment parameters in GNSS based on genetic algorithm , 2017 .

[13]  Xiaogong Hu,et al.  Initial results of centralized autonomous orbit determination of the new-generation BDS satellites with inter-satellite link measurements , 2018, Journal of Geodesy.

[14]  Zhili Sun,et al.  Route strategy of satellite network in GNSS based on topology evolution law , 2014 .

[15]  Jun Yang,et al.  Timeslot scheduling of inter-satellite links based on a system of a narrow beam with time division , 2017, GPS Solutions.

[16]  Xingqun Zhan,et al.  Autonomous broadcast ephemeris improvement for GNSS using inter-satellite ranging measurements , 2012 .

[17]  Wei Zhang,et al.  A Unified Framework for Street-View Panorama Stitching , 2016, Sensors.

[18]  G. Beutler,et al.  A New Solar Radiation Pressure Model for GPS Satellites , 1999, GPS Solutions.

[19]  J. A. Rajan,et al.  Modernizing GPS Autonomous Navigation with Anchor Capability , 2003 .

[20]  Qile Zhao,et al.  Precise orbit determination for quad-constellation satellites at Wuhan University: strategy, result validation, and comparison , 2016, Journal of Geodesy.

[21]  A. S. Ganeshan,et al.  GNSS Satellite Geometry and Attitude Models , 2015 .

[22]  J. Langer,et al.  Crossfinks for the next-generation gps , 2003, 2003 IEEE Aerospace Conference Proceedings (Cat. No.03TH8652).

[23]  W. I. Bertiger,et al.  Effects of antenna orientation on GPS carrier phase , 1993, manuscripta geodaetica.

[24]  Tao Geng,et al.  Improving BDS integer ambiguity resolution using satellite-induced code bias correction for precise orbit determination , 2017, GPS Solutions.

[25]  Tianhe Xu,et al.  Orbit determination of the Next-Generation Beidou satellites with Intersatellite link measurements and a priori orbit constraints , 2017 .

[26]  H. Schuh,et al.  Global Mapping Function (GMF): A new empirical mapping function based on numerical weather model data , 2006 .

[27]  Liu Jing-nan,et al.  PANDA software and its preliminary result of positioning and orbit determination , 2003, Wuhan University Journal of Natural Sciences.

[28]  Francisco Amarillo Fernández,et al.  Inter-satellite ranging and inter-satellite communication links for enhancing GNSS satellite broadcast navigation data , 2011 .

[29]  John A. Rajan,et al.  Highlights of GPS II-R Autonomous Navigation , 2002 .

[30]  Qingming Gui,et al.  Establishment criteria, routing algorithms and probability of use of inter-satellite links in mixed navigation constellations , 2013 .

[31]  Jinping Chen,et al.  Orbit determination and time synchronization for new-generation Beidou satellites: Preliminary results , 2016 .