Roger Fraser, Adam Mowlam, Philip Collier
Department of Geomatics, The University of Melbourne, Australia.
DOI:    PDF    HTML     1,397 Downloads   3,007 Views   Citations

Abstract

Low–cost GPS receivers can produce positions almost instantly, however they have a limited use and application due to the impact of random and systematic errors associated with real time autonomous positioning. To achieve higher levels of accuracy and precision, some other form of correction or augmentation information must be applied. There are various real time augmentation alternatives, such as WAAS/LAAS, integrated sensors and systems, receiver based optimal estimation algorithms, and potentially, combined GNSS. To improve the accuracy of low–cost GPS receivers, a feasible option is Differential GPS (DGPS). A popular means for transferring real time DGPS corrections is via the RTCM SC–104 protocol over radio transmission. In recent times, the Internet has been shown to be an efficient and reliable form of data communication. In this paper, the Web services architecture is examined as a viable protocol and communication alternative for disseminating DGPS augmentation information over the Internet. Preliminary results from a simple prototype indicate that Web services offers a practical, efficient and secure method for exchanging CORS network data, and augmenting GPS enabled mobile devices capable of wirelessly reaching the internet. Web services are further shown to provide advantages for disseminating other GPS related data, such as IGS satellite orbit data, carrier–phase data for location–centric augmentation, and a host of other LBS information.

Keywords

Low–cost GPS, Internet DGPS, Web Services, Mobile Devices

Share and Cite:

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	Gao Y and Liu Z (2001): Differential GPS Positioning over Internet. Journal of Geospatial Engineering, Vol. 3, No. 1, 1–7.
[2]	Hofmann–Wellenhof B, Lichtenegger H and Collins J (2001): GPS Theory and Practice (5th Ed., revised). Springer–Verlag Wien, New York.
[3]	Kechine MO, Tiberius CCJM and van der Marel H (2003): Network Differential GPS: Kinematic Positioning with NASA’s Internet-based Global Differential GPS. Journal of Global Positioning Systems, Vol. 2, No. 2, 139–143
[4]	Lenz E (2004): Networked Transport of RTCM via Internet Protocol (NTRIP). Proceedings of the FIG Working Week 2004, Athens, Greece, 22–27 May.
[5]	Monteiro LS, Moore T and Hill CJ (2004): What is the Accuracy of DGPS? Presented at the European Navigation Conference GNSS 2004, Rotterdam, The Netherlands, May.
[6]	Muellerschoen R J, Bertiger WI and Lough M (2000): Results of an Internet-Based Dual-Frequency Global Differential GPS System. Proceedings of the IAIN World Congress, San Diego, CA, June.
[7]	RTCM SC–104, (2001): RTCM Recommended Standards for Differential GNSS Service. Version 2.3, 20 August, Radio Technical Commission for Maritime Services, Alexandria, Virginia.
[8]	Satirapod C, Rizos C and Wang J (2001): GPS Single Point Positioning With SA Off: How Accurate Can We Get? Survey Review, 36(282), 255-262.
[9]	SiRF (2004): SiRF Binary Protocol Reference Manual. SiRF Technology, San Jose, CA, Revision 1.1, February 2004.
[10]	Weber G, Dettmering D and Gebhard H (2004): Networked Transport of RTCM via Internet Protocol (NTRIP). unpublished, Available online: http://igs.ifag.de/pdf/NtripPaper.pdf.
[11]	W3C (2002): XML Encryption Syntax and Processing – W3C Recommendation. Eastlake D, Reagle J (Eds), 10 December, Available online: http://www.w3.org/TR/xmlenc-core/.