Abstract
Multipath is one of the most important error sources in Global Navigation Satellite System (GNSS) carrier-phase-based precise relative positioning. Its theoretical maximum is a quarter of the carrier wavelength (about 4.8 cm for the Global Positioning System (GPS) L1 carrier) and, although it rarely reaches this size, it must clearly be mitigated if millimetre-accuracy positioning is to be achieved. In most static applications, this may be accomplished by averaging over a sufficiently long period of observation, but in kinematic applications, a modelling approach must be used. This paper is concerned with one such approach: the use of ray-tracing to reconstruct the error and therefore remove it. In order to apply such an approach, it is necessary to have a detailed understanding of the signal transmitted from the satellite, the reflection process, the antenna characteristics and the way that the reflected and direct signal are processed within the receiver. This paper reviews all of these and introduces a formal ray-tracing method for multipath estimation based on precise knowledge of the satellite–reflector–antenna geometry and of the reflector material and antenna characteristics. It is validated experimentally using GPS signals reflected from metal, water and a brick building, and is shown to be able to model most of the main multipath characteristics. The method will have important practical applications for correcting for multipath in well-constrained environments (such as at base stations for local area GPS networks, at International GNSS Service (IGS) reference stations, and on spacecraft), and it can be used to simulate realistic multipath errors for various performance analyses in high-precision positioning.
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References
Bétaille D, Maenpa J, Euler H-J, Cross PA (2003) New approach to GPS phase multipath mitigation. In: Proceedings of ION national technical meeting 2003, Anaheim, California, 22–24 January, pp 243–253
Bétaille DF, Cross PA, Euler H-J (2006) Assessment and improvement of the capabilities of a window correlator to model GPS multipath phase errors. IEEE Trans Aerospace Electr Systems 42(2):705–717
Born M, Wolf E (1999) Principles of optics, 7th (expanded) edn. Cambridge University Press, Cambridge. ISBN 0-521-78449-2
Braasch MS (1996) Multipath effects, global positioning system: theory and applications. In: Parkinson BW, Spilker JJ, (eds) Vol. 1. American Institute of Aeronautics and Astronautics, pp 547–567. ISBN 1-56347-106-X
Brown A, Wang J (1999) High accuracy kinematic GPS performance using a digital bean-steering array. In: Proceedings of ION GPS 99, Nashville, TN, 14–17 September, pp 1685– 1693
Fenton PC, Jones J (2005) The theory and performance of NovAtel Inc.’s vision correlator. In: Proceedings of ION GNSS 2005, The Institute of Navigation, Long Beach, California, 13–16 September, pp 2178–2186
Gratton L, Khanafseh S, Pervan B, Pullen S, Warburton J (2004) Experimental observations and integrity monitor applications of LAAS IMLA carrier phase measurements. In: Proceedings of ION GNSS 2004, Long Beach, CA, 21–24 September, pp 2259–2270
ICD-GPS-200C (2003) Navstar GPS Space Segment/Navigation User Interfaces, Revision C, U.S. Air Force
Kim D, Jang J, Kee C (2004) Integer ambiguity search technique using separated Gaussian variables. In: Proceedings of The 2004 international symposium on GNSS/GPS, Sydney, Australia, 6–8 December
Kim D, Langley RB (2000) GPS ambiguity resolution for long-baseline kinematic applications. In: Proceedings of the GEOIDE second annual conference, Calgary, Canada, 25–26 May
Kraus JD, Fleisch DA (1999) Electromagnetics with applications, 5th edn. McGraw-Hill, New York. ISBN 0-07-116429-4
Kraus JD, Marhefka RJ (2002) Antennas for all applications, 3rd edn. McGraw-Hill, New York. ISBN 0-07-112240-0
Langley RB (1998) Propagation of the GPS signals. In: Teunissen PJG, Kleusberg A (eds) GPS for geodesy, 2nd edn. Springer, Heidelberg, pp 111–149. ISBN 3-540-63661-7
Lau KYL (2005) Phase Multipath Modelling and Mitigation in Multiple Frequency GPS and Galileo Positioning. PhD Thesis, University of London, London
Lau L, Cross P (2003) Impact of GPS modernization on precise carrier phase-based positioning in the presence of multipath. In: Proceedings of ION GPS/GNSS 2003, Portland, Oregon, 9–12 September, pp 2163–2172
Lau L, Cross P (2005) Use of signal-to-noise ratios for real-time GNSS phase multipath mitigation. In: Proceedings of NAV 05, Royal Institute of Navigation, Pinpoint Faraday and the United Kingdom Industrial Space Committee, London, 1–3 November
Lau L, Cross P (2006) Prospects for phase multipath mitigation using antenna arrays for very high precision real-time kinematic applications in the presence of new GNSS signals. In: Proceedings of European navigation conference GNSS 2006, Manchester, UK, 8–10 May
Lau L, Mok E (1999) Improvement of GPS relative positioning accuracy by using SNR. J Survey Eng 125(4):185–202. doi: 10.1061/(ASCE)0733-9453
Moore T, Hill C, Hide C, Cross P, Lau L, Walsh D, Cooper J, Ioannides R, Ochieng W, Feng S (2005) Development of a test bed facility for high accuracy positioning in difficult environments. In: Proceedings of ION GNSS 2005, The Institute of Navigation, Long Beach, 13–16 September
Mott H (1992) Antennas for radar and communications: a polarimetric approach. Wiley-Interscience, New York. ISBN 0471575380
Nalwa HS (1999) Handbook of low and high dielectric constant materials and their applications: materials and processing, vol. 1. Academic, New York. ISBN 0125139055
Park JG, Kim J, Lee JG, Park C, Jee G, Oh JT (1998) The enhancement of INS alignment using GPS measurements. In: Proceedings of position location and navigation symposium, IEEE, Palm Springs, CA, 20–23 April, pp 534–540. ISBN:0780343301, doi:10.1109/PLANS.1998.670209
Rao BR, Williams JH, Rosario EN, Davis RJ (2000) GPS microstrip antenna array on a resistivity tapered ground plane for multipath mitigation. In: Proceedings of ION GPS 2000, 19–22 September, Salt Lake City, Utah, pp 2468–2471
Ray J, Cannon ME (1999) Characterization of GPS carrier phase multipath. In: Proceedings of ION national technical meeting, San Diego, 25–27 January, pp 343–352
Ray J, Cannon ME, Fenton P (2000) Mitigation of carrier phase multipath effects using multiple closely-spaced antennas. Navigation 46(4):193–201
Samsonov GV (1968) Handbook of the physicochemical properties of the elements. IFI/Plenum, New York
Satirapod C, Rizos C (2005) Multipath mitigation by wavelet analysis for GPS base station applications. Survey Rev 38(295):2–10
Schupler BR, Clark TA (2001) Characterizing the behavior of geodetic GPS antennas. GPS World 12(2):48–55
Stewart M (2003) Report of special study group 1.182 “Multipath Mitigation”. In: International Association of Geodesy, http://www.gfy.ku.dk/∼iag/Travaux/html%5Csec1%5CSSG1. 182.htm
Wieser A, Brunner FK (2000) An extended weight model for GPS phase observations. Earth Planets Space 52:777–782
Wu JT, Wu SC, Hajj GA, Bertiger WI, Lichten SM (1993) Effect of antenna orientation on GPS carrier phase. Manuscr Geod 18:91–98
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Lau, L., Cross, P. Development and testing of a new ray-tracing approach to GNSS carrier-phase multipath modelling. J Geod 81, 713–732 (2007). https://doi.org/10.1007/s00190-007-0139-z
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DOI: https://doi.org/10.1007/s00190-007-0139-z