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On-line Detection of Tracking Loss in Aviation GPS Receivers Using Frequency-Lock Loops

Published online by Cambridge University Press:  12 March 2009

Hyoungmin So ,
Sujin Choi ,
Sanghoon Jeon  and
Changdon Kee
Hyoungmin So*
Affiliation:
(Seoul National University)
Sujin Choi
Affiliation:
(Korea Aerospace Research Institute)
Sanghoon Jeon
Affiliation:
(Seoul National University)
Changdon Kee
Affiliation:
(Seoul National University)
*
(Email: so97@snu.ac.kr)
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Abstract

For high-precision real-time kinematics (RTK) and safety-of-life Global Navigation Satellite Systems (GNSS), it is critical to track the carrier reliably without interruptions. We develop hardware-oriented robust on-line cycle slip and loss detection logic for a single-frequency stand-alone aviation receiver. The moving average statistics of time-differenced frequency-lock loop (FLL) are shown to provide a robust and fixed detection threshold for cycle loss detection. A Monte-Carlo simulation shows that the detection performance remains robust when aviation dynamics from minimum operational performance standard (MOPS) are added to a simulated strong scintillation.

Keywords

Cycle slip detectionFrequency lock loopGPS
Type
Research Article
Information
The Journal of Navigation , Volume 62 , Issue 2 , April 2009 , pp. 263 - 281
Copyright
Copyright © The Royal Institute of Navigation 2009

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References

REFERENCES

Cahn, C.R. (1974). Phase Tracking and Demodulation with Delay, IEEE Trans. on Information Theory, vol. rr-20, no. 1.CrossRefGoogle Scholar
Ganguly, S., Jovancevic, A., Brown, A., Kirchner, M., Zigic, S., Beach, T., and Groves, K.M.. (2004). Ionospheric scintillation monitoring and mitigation using a software GPS receiver. Radio Sci., 39.CrossRefGoogle Scholar
Hofmann-Wellenhof, B., Lichtenegger, H. and Collins, J.. (1994). GPS Theory and Practice, Springer-Verlag Wien New York.Google Scholar
Humphreys, T.E., Psiaki, M.L., Kintner, P.M. and Ledvina, B.M.. (2005). GPS Carrier Tracking Loop Performance in the Presence of Ionospheric Scintillations. Proceedings of the Institute of Navigation ION GNSS 2005, Long Beach, CA.Google Scholar
Kim, T., Conker, R.S., El-Arini, M.B., Ericson, S.D., Hegarty, C.J. and Tran, M.. (2003). Preliminary Evaluation of the Effects of Scintillation on L5 GPS and SBAS Receivers Using a Frequency Domain Scintillation Model and Simulated and Analytical Receiver Models, Proceedings of the National Technical Meeting of the Satellite Division of the Institute of Navigation, ION NTM 2003, Anaheim, CA.Google Scholar
Lee, H.K., Wang, J. and Rizos, C.. (2003). Effective Cycle Slip Detection and Identification for High Precision GPS/INS Integrated Systems. The Journal of Navigation, 56, 475486.Google Scholar
McGraw, G. and Schnaufer, B. (1995). A Modified Frequency-Locked Loop for Improved WAAS Carrier Tracking. Proceedings of the Institute of Navigation ION GPS-95, Palm Springs, CA.Google Scholar
Müller, T. (1998). Performance Degradation in GPS-Receivers Caused by Group Delay Variations of SAW-Filters. IEEE MTT-S Digest, 495498.Google Scholar
Osborne, H.C. (1980). Stability Analysis of an Nth Power Digital Phase-Locked Loop – Part II: Second- and Third-Order DPLL's, IEEE Trans. On Communications, vol. Com-28, no. 8.Google Scholar
Skone, S., Lachapelle, G., Yao, D., Yu, W. and Watson, R.. (2005). Investigating the Impact of Ionospheric Scintillation Using a GPS Software Receiver. Proceedings of the Institute of Navigation ION GNSS 2005, Long Beach, CA.Google Scholar
Stephens, D. (2002). Phase-Locked Loops for Wireless Communications: Digital, Analog, and Optical Implementations, 2nd Edition, Kluwer Academic Publishers.Google Scholar
Stephens, S.A. and Thomas, J.B. (1995). Controlled-Root Formulation for Digital Phase-Locked Loops, IEEE Trans. On Aerospace and Electronic Systems, vol. 31, no. 1, 7895.Google Scholar
Tateishi, K. (1998). Cycle Slip Detector and Phase Locked Loop Circuit and Digital Signal Reproducing Apparatus Using the Same. US Patent 5790613.Google Scholar
Thuringer, D. and McGraw, G. (2001). Cycle Slip Detection in Carrier Tracking Loops. Proceedings of the Institute of Navigation ION GPS 2001, Salt Lake City, UT.Google Scholar
Van Dierendonck, A.J. (1996). GPS Receivers, Global Positioning System: Theory and Applications, AIAA.Google Scholar
Walter, T., Datta-Baruna, S., Blanch, J., and Enge, P.. (2004). The Effects of Large Ionospheric Gradients on Single Frequency Airborne Smoothing Filters for WAAS and LAAS, Proceedings of the National Technical Meeting of the Satellite Division of the Institute of Navigation, ION NTM 2004, San Diego, CA.Google Scholar
Ward, P., Betz, J. and Hegarty, C.. (2006). Satellite Signal Acquisition, Tracking, and Data Demodulation, Understanding GPS: Principles and Applications, 2nd Edition, Artech House.Google Scholar