Ruizhi Chen, Antti Hyttinen, Yuwei Chen
Finnish Geodetic Institute, Finland, Geodeetinrinne 2, Pl-15, FIN-02431, Masala, Finland.
DOI:    PDF    HTML     1,326 Downloads   2,863 Views   Citations

Abstract

In order to access the Satellite Based Augmentation System (SBAS) service, the end user needs to have a direct line of sight to at least one of the Geostationary Earth Orbit (GEO) satellites transmitting the augmentation messages. This requirement is critical for users in environments such as city canyons, valleys and fjords since high buildings and mountains in the vicinity of the end user can easily block the lines of sight to the GEO satellites. The situation becomes worse at high latitudes because of the low elevation angles to the GEO satellites. Even a very low obstacle can block the lines of sight to the GEO satellites. This limitation reduces SBAS Signal in Space (SIS) availability significantly at high latitude especially for land applications. This paper presents a solution of transmitting the European Geostationary Navigation Overlay Service (EGNOS) SIS using a pseudolite. The EGNOS pseudolite functions in a similar way as a GEO satellite. It will provide not only a terrestrial-based solution for transmitting the EGNOS SIS, but also a ranging measurement for the navigation solution. The EGNOS pseudolite system mainly consists of a Master Control Station, an EGNOS Data Server, EGNOS pseudolites and the user terminal. A preliminary test on a surveyed site has been carried out to verify the functionalities of the system. The data set collected from the test has been processed with two scenarios: one with four GPS satellites, while the other with three GPS satellites plus an EGNOS pseudolite. Both data processing scenarios have similar satellite geometries. The test result shows that the positioning accuracies are similar for both scenarios.

Keywords

EGNOS, Pseudolite, SBAS

Share and Cite:

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	Chen R., M. Str?m, M. Tossaint, M. Sven, M. Cristoforo, A. Hyttinen, X. Li, Y. Chen, T. Johler, H. Laitinen ,V. Bos (2006) Preliminary Test Results of Positioning with EGNOS Pseudolite. Proceedings of the 3rd ESA Workshop on Satellite Navigation User Equipment Technologies NAVITEC '2006, 11 - 13 December 2006, ESTEC, Noordwijk, The Netherlands.
[2]	Chen R. and Li X. (2004) Virtual Differential GPS Based on SBAS Signal. GPS Solutions (2004). Vol. 8, Nr. 4, pp 238-244.
[3]	Chen R., Li X. and Weber G. (2004) Test Results of an Internet RTK System Based on the NTRIP Protocol. Proceedings of the GNSS 2004 conference, May, 16-19, 2004, Rotterdam, the Netherlands.
[4]	Chen R., Torán F., and J. Ventura-Traveset (2003) Access to the EGNOS Signal In Space Over Mobile-IP. GPS Solutions (2003) Vol 7, No. 1, pp 16-22.
[5]	Chen R (2003) EGNOS Positioning at High Latitude with a GPRS-based EGNOS SIS receiver. Proceedings of ION GPS 2003, September 09-12, Portland, Oregon, US, pp 2828 –2832.
[6]	Cobb S. (1997) GPS Pseudolite: Theory, design and application. Ph. D Thesis, Stanford University. Redeborn J., Richccardo N.e and Gunther A. (2003) EGNOS Terrestrial Regional Augmentation Network- Executive Final Report). ESA Project Report.
[7]	Toran-Marti F., J. Ventura-Traveset, and R. Chen (2002a) The ESA SISNeT Technology: Real-Time Access to the EGNOS Services through Wireless Networks and the Internet. Proceedings of the ION GPS 2002, September 24-27, Portland, Oregon, U.S.
[8]	Toran-Marti F., Ventura-Traveset J. and de Mateo J.C. (2002b) Satellite Navigation and the Internet: Introducing SISNET Technology, Dr. Dobb's Journal, March 2002.
[9]	Toran-Marti F., J. Ventura-Traveset (2005) The EGNOS Data Access System (EDAS). Proceedings of the European Navigation Conference, 19th-27th, July 2005, Munich, Germany.
[10]	Wang J. (2002) Applications of pseudolites in geodetic positioning: Progress and problems. Journal of Global Positioning Systems, 1(1): 48-56.