Abstract Intersatellite Link (ISL) technology helps to realize the auto update of broadcast ephemeris and clock error parameters for Global Navigation Satellite System (GNSS). ISL constitutes an important approach with which to both improve the observation geometry and extend the tracking coverage of China’s Beidou Navigation Satellite System (BDS). However, ISL-only orbit determination might lead to the constellation drift, rotation, and even lead to the divergence in orbit determination. Fortunately, predicted orbits with good precision can be used as a priori information with which to constrain the estimated satellite orbit parameters. Therefore, the precision of satellite autonomous orbit determination can be improved by consideration of a priori orbit information, and vice versa. However, the errors of rotation and translation in a priori orbit will remain in the ultimate result. This paper proposes a constrained precise orbit determination (POD) method for a sub-constellation of the new Beidou satellite constellation with only a few ISLs. The observation model of dual one-way measurements eliminating satellite clock errors is presented, and the orbit determination precision is analyzed with different data processing backgrounds. The conclusions are as follows. (1) With ISLs, the estimated parameters are strongly correlated, especially the positions and velocities of satellites. (2) The performance of determined BDS orbits will be improved by the constraints with more precise priori orbits. The POD precision is better than 45 m with a priori orbit constrain of 100 m precision (e.g., predicted orbits by telemetry tracking and control system), and is better than 6 m with precise priori orbit constraints of 10 m precision (e.g., predicted orbits by international GNSS monitoring & Assessment System (iGMAS)). (3) The POD precision is improved by additional ISLs. Constrained by a priori iGMAS orbits, the POD precision with two, three, and four ISLs is better than 6, 3, and 2 m, respectively. (4) The in-plane link and out-of-plane link have different contributions to observation configuration and system observability. The POD with weak observation configuration (e.g., one in-plane link and one out-of-plane link) should be tightly constrained with a priori orbits.
[1]
J. A. Rajan,et al.
Modernizing GPS Autonomous Navigation with Anchor Capability
,
2003
.
[2]
Liu Wanke.
Influence of Error and Prior Information to AOD of Navigation Satellites
,
2011
.
[3]
Qing Chang,et al.
On new measurement and communication techniques of GNSS inter-satellite links
,
2012
.
[4]
Yong Huang,et al.
Precise orbit determination for geostationary satellites with multiple tracking techniques
,
2010
.
[5]
J. Langer,et al.
Crossfinks for the next-generation gps
,
2003,
2003 IEEE Aerospace Conference Proceedings (Cat. No.03TH8652).
[6]
Shan Wu,et al.
Centralized autonomous orbit determination of Beidou navigation satellites with inter-satellite link measurements: preliminary results
,
2017
.
[7]
John A.Rajan,et al.
on-orbit validation of GPS IIR autonomous navigation
,
2003
.
[8]
Jinping Chen,et al.
Orbit determination and time synchronization for new-generation Beidou satellites: Preliminary results
,
2016
.
[9]
H. Bernstein,et al.
Ephemeris observability issues in the Global Positioning System (GPS) autonomous navigation (AUTONAV)
,
1994,
Proceedings of 1994 IEEE Position, Location and Navigation Symposium - PLANS'94.
[10]
Xingqun Zhan,et al.
Autonomous broadcast ephemeris improvement for GNSS using inter-satellite ranging measurements
,
2012
.
[11]
Peter Steigenberger,et al.
Broadcast versus precise ephemerides: a multi-GNSS perspective
,
2015,
GPS Solutions.
[12]
Ruan Rengu.
Equipment Delay Estimation for GNSS Satellite Combined Orbit Determination with Satellite-ground Link and Inter-Satellite Link Observations
,
2014
.