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Characterisation of GNSS Space Service Volume

Published online by Cambridge University Press:  30 July 2014

Shuai Jing ,
Xingqun Zhan ,
Jun Lu ,
Shaojun Feng  and
Washington Y. Ochieng
Shuai Jing*
Affiliation:
(School of Aeronautics and Astronautics, Shanghai Jiao Tong University)
Xingqun Zhan
Affiliation:
(School of Aeronautics and Astronautics, Shanghai Jiao Tong University)
Jun Lu
Affiliation:
(Beijing Institute of Tracking & Telecommunication Technology)
Shaojun Feng
Affiliation:
(Centre for Transport Studies, Imperial College London)
Washington Y. Ochieng
Affiliation:
(Centre for Transport Studies, Imperial College London)
*
(E-mail: [email protected])
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Abstract

There is increasing demand for navigation capability for space vehicles. The idea to extend the application of Global Navigation Satellite Systems (GNSS) from terrestrial to space applications by the use of main beam and side lobe signals has been shown to be feasible. In order to understand the performance and the potential space applications GNSS can support, this paper characterises the Space Service Volume (SSV) in terms of the four parameters of minimum received power, satellite visibility, pseudorange accuracy and Geometric Dilution of Precision (GDOP). This new definition enables the position errors to be estimated. An analytical methodology is proposed to characterise minimum received power for the worst location. Satellite visibility and GDOP are assessed based on grid points at different height layers (to capture the relationship between height and visibility) for single and multiple GNSS constellations, the former represented by BeiDou III (BDS III) and the latter, BDS III in various combinations with GPS, GLONASS and GALILEO. Additional simulation shows that GNSS can potentially support lunar exploration spacecraft at the Earth phasing orbit. This initial assessment of SSV shows the potential of GNSS for space vehicle navigation.

Keywords

GNSSBDSSpace Service VolumeLunar Exploration
Type
Research Article
Information
The Journal of Navigation , Volume 68 , Issue 1 , January 2015 , pp. 107 - 125
Copyright
Copyright © The Royal Institute of Navigation 2014 

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References

REFERENCES

Bamford, W., Naasz, B. and Moreau, M.C. (2006), Navigation Performance in High Earth Orbits Using Navigator GPS Receiver, 29th Annual AAS Guidance and Control Conference, Breckenridge, CO.Google Scholar
Bauer, F.H., Moreau, M.C., Dahle-Melsaether, M.E., Petrofski, W.P., Stanton, B.J., Thomason, S., Harris, G.A., Sena, R. P. and Temple, L. P. III (2006), The GPS Space Service Volume. In: Proceedings of the ION GNSS 2006, Fort Worth, Texas. 2503–2514.Google Scholar
Cáceres, M. (2008), A Look at The Next 20 Years. Aerospace America, 46, 2022.Google Scholar
GPS World staff (2013). GIOVE-A uses GPS side lobe signals for far-Out space navigation. GPS World, April 12, 2013.Google Scholar
GPS SPS PS. (2008). Global Positioning System Standard Positioning Service Performance Standard. In: http://www.pnt.gov/public/docs/2008/, 4th Edition.Google Scholar
Hogg, D.C. (1993), Fun with the Friis Free-space Transmission Formula. Antennas and Propagation Magazine, IEEE, 35(4), 3335.CrossRefGoogle Scholar
ICD-BDS. (2012). BeiDou Navigation Satellite System Signal in Space Interface Control Document Open Service Signal B1I (Version 1.0).Google Scholar
ICD-GALILEO. (2010). Galileo Open Service, Signal In Space Interface Control Document, OS SIS ICD, Issue 1·1. September, 2010.Google Scholar
ICD-GLONASS. (2008). GLONASS Interface Control Document, Navigational radio signal In bands L1, L2, Edition 5.1. 2008.Google Scholar
Kaplan, E.D. and Hegarty, C. (2006), Understanding GPS: Principles and Applications, Second Version. Norwood, MA: Artech House.Google Scholar
Kronman, J.D. (2000), Experience Using GPS for Orbit Determination of a Geosynchronous Satellite, Proceedings of ION GPS 2000, Salt Lake City, UT. 1622–1626.Google Scholar
Moreau, M.C., Axelrad, P., Garrison, J.L., Wennersten, M. and Long, A.C. (2001). Test Results of the PiVoT Receiver in High Earth Orbits using a GSS GPS Simulator, Proceedings of ION GPS 2001, Salt Lake City, UT. 2316–2326.Google Scholar
Moreau, M.C., Davis, E.P., Carpenter, J.R., Davis, G.W., Jackson, L.A. and Axelrad, P. (2002). Results from the GPS Flight Experiment on the High Earth Orbit AMSAT AO-40 Spacecraft, Proceedings of the ION GPS 2002, Portland, OR. 1–12.Google Scholar
Miller, J.J. and Moreau, M.C. (2012). Enabling a Fully Interoperable GNSS Space Service Volume, ICG WG-B Interim Meeting, Vienna, Austria, 6 June 2012.Google Scholar
Stanton, B.J., Parker Temple, L. III and Edgar, C.E. (2006). Analysis of Signal Availability in the GPS Space Service Volume, Proceedings of the ION GNSS 2006, Fort Worth, Texas. 2531–2541.Google Scholar
Van Dierendonck, A.J., Fenton, P. and Ford, T. (1992). Theory and Performance of Narrow Correlator Spacing in a GPS Receiver, Journal of the Institute of Navigation, 39(3), 265283.Google Scholar
Yang, W. (2010). Phasing Orbit Design for Chinese Lunar Satellite CE-1, Chinese Space Science and Technology, 30(1), 1824.Google Scholar
Yu, C., Cui, G., Zheng, Y., Chen, H. and Nie, Q. (2009). The Adaptability Study of Bursa Model, Information Technology and Applications, 3, 620623.Google Scholar
Zarlink Semiconductor. (1999). GPS2000: GPS Receiver Hardware Design, Application Note 855, Issue 2·0 October 1999.Google Scholar