Characteristics of inter-frequency clock bias for Block IIF satellites and its effect on triple-frequency GPS precise point positioning

The latest generation of GPS satellites, termed Block IIF, provides a new L5 signal. Multi-frequency signals open new prospects for precise positioning and fast ambiguity resolution and have become the trend in Global Navigation Satellite System (GNSS) development. However, a new type of inter-frequency clock bias (IFCB), i.e., the difference between the current clock products computed with L1/L2 and the satellite clocks computed with L1/L5, was noticed. Consequently, the L1/L2 clock products cannot be used for L1/L5 precise point positioning (PPP). In order to solve this issue, the IFCB should be estimated with a high accuracy. Datasets collected at 129 globally distributed Multi-GNSS Experiment (MGEX) stations from 2015 are employed to investigate the IFCB. The results indicate that the IFCB is satellite dependent and varies with the relative sun–spacecraft–earth geometry. Other factors, however, may also contribute to the IFCB variations according to the harmonic analysis of the single-day IFCB time series. In addition, the results show that the IFCB exhibits periodic signal with a notable period of 43,080 s and the peak-to-peak amplitude is 0.023–0.269 m. After considering a time lag of 240 s, the average cross-correlation coefficient between the IFCB series of two consecutive days is 0.943, and the prediction accuracy of IFCB is 0.006 m. A triple-frequency PPP model that takes the IFCB into account is proposed. When using 3-h datasets, the positioning accuracy of triple-frequency PPP can be improved by 19, 13 and 21 % compared with the L1/L2-based PPP in the east, north and up directions, respectively.

[1]  Mohamed Elsobeiey,et al.  Precise Point Positioning using Triple-Frequency GPS Measurements , 2015 .

[2]  George P. Gerdan A Comparison of Four Methods of Weighting Double Difference Pseudorange Measurements , 1995 .

[3]  Rock Santerre,et al.  Performance evaluation of single-frequency point positioning with GPS, GLONASS, BeiDou and Galileo , 2017 .

[4]  Jianjun Zhu,et al.  Combined GPS/GLONASS Precise Point Positioning with Fixed GPS Ambiguities , 2014, Sensors.

[5]  Bin Wu,et al.  Estimation of the inter-frequency clock bias for the satellites of PRN25 and PRN01 , 2012 .

[6]  Justine Spits,et al.  Total electron content monitoring using triple frequency GNSS data: A three-step approach , 2008 .

[7]  Bofeng Li,et al.  Improved method for estimating the inter-frequency satellite clock bias of triple-frequency GPS , 2016, GPS Solutions.

[8]  Peter Teunissen,et al.  A comparison of TCAR, CIR and LAMBDA GNSS ambiguity resolution , 2003 .

[9]  Xingxing Li,et al.  Accuracy and reliability of multi-GNSS real-time precise positioning: GPS, GLONASS, BeiDou, and Galileo , 2015, Journal of Geodesy.

[10]  Jingnan Liu,et al.  Analysis of BeiDou Satellite Measurements with Code Multipath and Geometry-Free Ionosphere-Free Combinations , 2016, Sensors.

[11]  Xiaogong Hu,et al.  Modeling and initial assessment of the inter-frequency clock bias for COMPASS GEO satellites , 2013 .

[12]  Peter Steigenberger,et al.  Orbit and Clock Determination of QZS‐1 Based on the CONGO Network , 2012 .

[13]  Lin Pan,et al.  A comparative analysis of measurement noise and multipath for four constellations: GPS, BeiDou, GLONASS and Galileo , 2016 .

[14]  I. Shapiro,et al.  Geodesy by radio interferometry: Effects of atmospheric modeling errors on estimates of baseline length , 1985 .

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

[16]  Vijay K. Madisetti,et al.  The Digital Signal Processing Handbook , 1997 .

[17]  Fan-Ren Chang,et al.  Using multi-frequency for GPS positioning and receiver autonomous integrity monitoring , 2004, Proceedings of the 2004 IEEE International Conference on Control Applications, 2004..

[18]  Haojun Li,et al.  Fast estimation and analysis of the inter-frequency clock bias for Block IIF satellites , 2013, GPS Solutions.

[19]  Peter Steigenberger,et al.  Signal, orbit and attitude analysis of Japan’s first QZSS satellite Michibiki , 2011, GPS Solutions.

[20]  Pierre Héroux,et al.  Precise Point Positioning Using IGS Orbit and Clock Products , 2001, GPS Solutions.

[21]  Peter Steigenberger,et al.  Initial assessment of the COMPASS/BeiDou-2 regional navigation satellite system , 2013, GPS Solutions.

[22]  Harald Schuh,et al.  Multi-GNSS Meteorology: Real-Time Retrieving of Atmospheric Water Vapor From BeiDou, Galileo, GLONASS, and GPS Observations , 2015, IEEE Transactions on Geoscience and Remote Sensing.

[23]  Peter Bona,et al.  Precision, Cross Correlation, and Time Correlation of GPS Phase and Code Observations , 2000, GPS Solutions.

[24]  Peter Steigenberger,et al.  Apparent clock variations of the Block IIF-1 (SVN62) GPS satellite , 2012, GPS Solutions.

[25]  Yang Gao,et al.  Precise point positioning with quad-constellations: GPS, BeiDou, GLONASS and Galileo , 2015 .

[26]  Peter Steigenberger,et al.  Three's the challenge: A close look at GPS SVN62 triple-frequency signal combinations finds carrier-phase variations on the new L5 , 2010 .