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A Guideline to Establish DGPS Reference Station Requirements

Published online by Cambridge University Press:  10 December 2007

Changdon Kee*
Affiliation:
(Seoul National University)
Byungwoon Park
Affiliation:
(Seoul National University)
Jeonghan Kim
Affiliation:
(Seoul National University)
Allen Cleveland
Affiliation:
(United States Coast Guard)
Michael Parsons
Affiliation:
(United States Coast Guard)
David Wolfe
Affiliation:
(United States Coast Guard)
*

Abstract

After Selective Availability (SA) was turned off, the rate of change with time of the DGPS common errors (atmospheric delay, satellite orbit and clock error) became quite slow. This inevitably leads to a requirement to modify various configurations of DGPS correction message broadcasting, and reference station (RS) managers need to examine the characteristics of GPS measurement errors with SA-off. GPS error sources are temporally and spatially decorrelated, so the DGPS user position accuracy is varied by the baud-rate of the RS, the distance between the user and the station, and the noise statistics of the receiver. We identify the minimum and maximum size of correction data, interval time, the coverage range and the baud-rate that are required to maintain the existing DGPS service. Moreover, the compatibility and accuracy can be assessed to meet the users' requirements without measurements being needed. The results in this paper are used in the study and testing for the redesign of United States Coast Guard (USCG) RS. We hope that our study will be a great help in determining the flexible factors of both the RS and the user.

Type
Research Article
Copyright
Copyright © The Royal Institute of Navigation 2007

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References

REFERENCES

Parkinson, B. et al. (1996). Global Positioning System: Theory and Applications II. Progress in Astronautics and Aeronautics, pp 350.CrossRefGoogle Scholar
Kee, C. (1996). Quality Control Algorithm on Wide-area Reference Station for WAAS, ION 52nd Annual Meeting, Cambridge, Massachusetts, pp 487495.Google Scholar
Kee, C., Park, B., Kim, J., Choi, S. (2004). PRC Generation in Time-Latency: IS RRC Still Required Even If S/A Has Been Turned Off?ION 2004 NTM, San Diego, CA, pp 869874.Google Scholar
Wolfe, D. B., Judy, C. L., Kritz, A. B., Chop, J. A., Parsons, M. W. (2003). Nationwide DGPS: 2003 and Beyond. ION 2003 NTM, Anaheim, CA, pp 548557.Google Scholar
Misra, P., Enge, P. (2001). Global Positioning System – Signals, Measurements, and Performance. Ganga-Jamuna Press, pp 132196.Google Scholar
Doherty, P., Raffi, E., Klobuchar, J., Bakry El-Arini, M. (1994). Statistics of Time Rate of Change of Ionospheric Range Delay. ION GPS-94 Proceedings, Salt Lake City, UT, pp 15891598.Google Scholar
RTCA (1999) Minimum Operational Performance Standards for Global Positioning System/Wide Area Augmentation System Airborne Equipment. RTCA, pp A8A12.Google Scholar
Brown, R. H. (1994). A Technical Report to the Secretary of Transportation on a National Approach to Augmented GPS Services. NTIA Special Publication 94-30. pp 1845.Google Scholar
Tralli, D. M., Lichten, S. M. (1990). Stochastic Estimation of Tropospheric Path Delays in Global Positioning System Geodetic Measurements. Bull. Geod. 64, 2, 1990, 127159.CrossRefGoogle Scholar