Performance Improvement of the Wald Test for GPS RTK with the Assistance of INS

Abdel-Hafez, Mamoun F.;Kim, Dae-Je;Lee, Eun-Sung;Chun, Se-Bum;Lee, Young-Jae;Kang, Tae-Sam;Sung, Sang-Kyung;

International Journal of Control, Automation, and Systems

Volume 6 Issue 4
/
Pages.534-543
/
2008
/
1598-6446(pISSN)
/
2005-4092(eISSN)

Institute of Control, Robotics and Systems (제어로봇시스템학회)

Performance Improvement of the Wald Test for GPS RTK with the Assistance of INS

Abdel-Hafez, Mamoun F. (American University of Sharjah, Sharjah, United Arab Emirates) ;
Kim, Dae-Je (R&D center at the Hyundai Rotem) ;
Lee, Eun-Sung (Korea Aerospace Research Institute) ;
Chun, Se-Bum (Microinfinity Co., Ltd.) ;
Lee, Young-Jae (Department of Aerospace Engineering, Konkuk University) ;
Kang, Tae-Sam (Department of Aerospace Engineering, Konkuk University) ;
Sung, Sang-Kyung (Department of Aerospace Engineering, Konkuk University)

Published : 2008.08.31

PDF KSCI

Download PDF

⟨ Previous Next ⟩

Abstract

To use the Global Positioning System (GPS) carrier phase measurement for precise positioning, the integer ambiguities at the early stage of most algorithms must be determined. Furthermore, if a precise positioning is to be applied to real time navigation, fast determination and validation methods for integer ambiguity are essential. In this paper, the Wald test that simultaneously determines and validates integer ambiguities is used with assistance of the Inertial Navigation System (INS) to improve its performance. As the Wald test proceeds, it assigns a higher probability to the candidate that is considered to be true at each time step. The INS information is added during the Wald test process. Large performance improvements were achieved in convergence time as well as in requiring fewer observable GPS satellites. To test the performance improvement of the Wald test with the INS information, experimental tests were conducted using a ground vehicle. The vehicle moved in a prescribed trajectory and observed seven GPS satellites. To verify the effect of the INS information on the Wald test, the convergence times were compared with cases that considered the INS information and cases that did not consider the INS information. The results show that the benefits of using the INS were emphasized as fewer GPS satellites were observable. The performance improvement obtained by the proposed algorithm was shown through the fast convergence to the true hypothesis when using the INS measurements.

Keywords

References

P. J. G. Teunissen, "The least-squares ambiguity decorrelation adjustment: A method for fast GPS integer ambiguity estimation," Journal of Geodesy, vol. 70, no. 1-2, pp. 65-82, November 1995 https://doi.org/10.1007/BF00863419
J. D. Wolfe, W. R. Williamson, and J. L. Speyer, "Hypothesis testing for resolving integer ambiguity in GPS," Navigation: Journal of the Institution of Navigation, vol. 50, no. 1, pp. 45- 56, March 2003
M. F. Abdel-Hafez, Y. J. Lee, W. R. Williamson, J. D. Wolfe, and J. L. Speyer "A high-integrity and efficient GPS integer ambiguity resolution method," Navigation: Journal of the Institute of Navigation, vol. 50, no. 4, pp. 295-310, November 2003
D. H. Titterton and J. L. Weston, Strapdown Inertial Navigation Technology, Stevenage, U. K., Peregrinus, 1997
M. Forrest, T. Spracklen, and N. Ryan, "An inertial navigation data fusion system employing an artificial neural network as the data integrator," Proc. ION NTM, Anaheim, CA, pp. 153-158, January 2000
N. El-Sheimy and K. P. Schwarz, "Integrating differential GPS receivers with an inertial navigation system (INS) and CCD cameras for a mobile GIS data collection system," Proc. of ISPRS94, Ottawa, Canada, pp. 241-248, October 1994
S. Hong, Y. Chang, S. Ha, and M. Lee, "Estimation of alignment error in GPS/INS integration," Proc. of ION GPS 2002, Portland, Oregon, pp. 527-534, September 2002
M. G. Petovello, M. E. Cannon, G. Lachapelle, J. Wang, C. K. H. Wilson, O. S. Salychv, and V. V. Voronov, "Development and testing of a realtime GPS/INS reference system for autonomous automobile navigation," Proc. of ION GPS 2001, Salt Lake City, Utah, pp. 2634-2641, September 2001
K. Chiang and E. Naser, "GPS/INS integration using neural networks for land vehicle navigation applications," Proc. of ION GPS 2002, Portland, Oregon, pp. 535-544, September 2002
E. Lee, S. Chun, Y. J. Lee, T. Kang, G. Jee, and M. F. Abdel-Hafez, "Performance improvement of wald test for resolving GPS integer ambiguity using a baseline-length constraint," International Journal of Control, Automation, and Systems, vol. 4, no. 3, pp. 333-343, June 2006
J. Seo, H. K. Lee, J. G. Lee, and C. G. Park, "Lever arm compensation for GPS/INS/ odometer integrated system," International Journal of Control, Automation, and Systems, vol. 4, no. 3, pp. 333-343, June 2006
C. Park, D. J. Cho, E. J. Cha, D.-H. Hwang, and S. J. Lee, "Error analysis of 3-dimensional GPS attitude determination system," International Journal of Control, Automation, and Systems, vol. 4, no. 4, pp. 480-485, 2006