GPS RTK Performance Characteristics and Analysis

Positioning > Vol.1 No.13, January 2008

Yanming Feng, Jinling Wang
Faculty of Information Technology, Queensland University of Technology, Australia.
School of Surveying and Spatial Information Systems, The University of New South Wales, Australia.
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Abstract

Global Navigation Satellite Systems (GNSS) provide various types of positioning state solutions, such as single point positioning (SPP), precise point positioning (PPP), differential GPS (DGPS) and real time kinematic (RTK) solutions. These solutions are obtained involving different data types, receivers, samples, serving different classes of users. Previous studies on performance characteristics have mainly focused on SPP solutions for safety-of-life navigation applications. This paper defines various useful performance characteristics for carrier phase Ambiguity Resolution (AR) and Position Estimation (PE) solutions in the RTK context. These parameters, including base-rover distance, time-to-first fix (TTFF), AR reliability, RTK accuracy, availability and integrity, etc, effectively represent the performance of a commercial RTK system and can be used to evaluate RTK systems and algorithms, and processing strategies through extensive experimental results. Statistical results from extensive field experiments were obtained using a commercial RTK system, demonstrating convincing overall system performance in different perspectives. Experimental results from three baselines were also analysed using a version of research-oriented RTK software, showing that AR performance improvement of using Wide-lane (WL) and Narrow-lane (NL) signals with respect to the original L1 and L2 signals when the baselines exceed 20 kilometres.

Keywords

GNSS, real time kinematic (RTK) positioning, performance characteristics, ambiguity resolution (AR), RTK integrity.

Share and Cite:

Y. Feng and J. Wang, "GPS RTK Performance Characteristics and Analysis," Positioning, Vol. 1 No. 13, 2008, pp. -.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	Brown R G (1996) Receiver Autonomous Integrity Monitoring, Global Positioning System: Theory and Applications, Vol II, published by American Institute of Aeronautics and Astronautics, Washington D. C, 1996, pp143-165.
[2]	Feng Y (2008) GNSS Three Carrier Ambiguity Resolution Using Ionosphere-reduced Virtual Signals, Journal of Geodesy, http://dx.doi.org/10.1007/s00190-008-0209-x
[3]	Feng Y, Wang J (2007), Exploring GNSS RTK Performance Benefits with GPS and Virtual Galileo Measurements, Proceedings of IONNTM2007,pp 218-226,San Diego,CA.
[4]	Higgins M, (2007) GNSS, CORS and Positioning Infrastructure: Business and the Future, Presentation at FIG Regional Conference Costa Rica November 2007.
[5]	HandyNav (2005) HandyNav RTK Testing Report,provided for licensed users,2005.
[6]	Langley, R. B(1999) The Integrity of GPS,GPS World Vol 10, No 3, March 1999,pp60-63
[7]	Enge, P, Van Dierendonck, A J (1996) Wide Area Augmentation System, in Global Positioning System: Theory and Applications, Vol II, published by American Institute of Aeronautics and Astronautics,Washington D.C, 1996,pp117-142
[8]	Mirsa P, Enge P (2004) Global Positioning Systems, Signals, Measurements and Performance,Ganga-Jamuna Press,pp 227-254.
[9]	Pratt,M., B Burke, and P Misra (1997) Single-Epoch Integer Ambiguity Resolution with GPS Carrier Phase: Initial Results, Navigation, Vol 32, No4, Pp386-400
[10]	Positioning One consulting (2008), User Needs Analysis, Technical Report for Cooperative Research Centre for Spatial Information, July 2008.
[11]	Teunissen, P.J.G. (1995) The least-squares ambiguity decorrelation adjustment: a method for fast GPS integer ambiguity estimation. Journal of Geodesy, Vol. 70, No. 1-2, pp. 65-82.
[12]	Teunissen, P.J.G, P J De Jonge and C.C. J.M Tiberious (1997). Performance of the LAMBDA Method for fast GPS Ambiguity Resolution, Navigation, Vol 44, No 3, pp373-383.
[13]	Teunissen, P.J.G, Joosten P, Tiberius C.C.J.M (1999) Geometry-free ambiguity success rates in case of partial fixing. Proceedings of ION-NTM 1999, pp 201-207, Jan 25-27, San Diego CA
[14]	Walter. T. (2002) Introduction to the Wide Area Augmentation System, Journal of Global Positioning Systems 1(2), pp151-153.
[15]	Wang J. (2002) Introduction to the Wide Area Augmentation System, Journal of Global Positioning Systems 1(2), pp151-153.
[16]	Wang J, C. Satirapod & C. Rizos (2002) Stochastic assessment of GPS carrier phase measurements for precise static relative positioning, Journal of Geodesy, 76(2), 95-104

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