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Wireless Personal Communications

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01.10.2013

Position Estimation in Single-Frequency GPS Receivers Using Kalman Filter with Pseudo-Range and Carrier Phase Measurements

Erschienen in: Wireless Personal Communications | Ausgabe 4/2013

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Abstract

Today Global Positioning System (GPS) is the most important system of positioning in the world and is used in different industries. Basic positioning methods in GPS receivers are based on pseudo-range and carrier phase measurements types whilst each of which has its own advantages and disadvantages. Pseudo-range method is not very much accurate. Carrier phase has a substantial accuracy, but its main problem is that it is an indirect measurement which only computes the displacement. Carrier phase measurement can include some whole cycles plus a fraction of carrier phase. The number of whole cycles may change through time however this change is unknown for us. Code measurements (based on pseudo-range) and carrier phase are corrupted with the same error sources, but with main differences. Basically, code tracking with low accuracy makes unambiguous pseudo-ranges. Carrier phase measurements are highly accurate, but get limited with integer ambiguity. Integer is fixed until the time that carrier tracking loop is saved. Every kind of gap in tracking, no matter how short it is, changes the amount of integer which is the biggest problem in carrier phase utilization. In this paper, the corporation of pseudo-range capability and carrier phase in single-frequency GPS receivers will be discussed which makes a substitute for the pure pseudo-range observations and provides a high level of positioning accuracy. To achieve this aim, Kalman filter will be used.

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Mosavi, M. R. (2006). Comparing DGPS corrections prediction using neural network, fuzzy neural network, and Kalman filter. Journal of GPS Solutions, 10(2), 97–107.CrossRef

Mosavi, M. R. (2011). Wavelet neural network for corrections prediction in single-frequency GPS users. Neural Processing Letters, 33(2), 137–150.CrossRef

Wen, Z., Henkel, P., & Gunther, C. (2011). Reliable estimation of phase biases of GPS satellites with a local reference network. In IEEE conference on ELMAR (pp. 321–324).

Cui, Y. J., & Ge, S. S. (2001). Autonomous vehicle positioning with GPS in urban canyon environments. IEEE Conference on Robotics & Automation, 2, 1105–1110.

Evers, H., & Kasties, G. (1994). Differential GPS in a real time land vehicle environment-satellite based van carrier location system. IEEE Magazine on Aerospace and Electronic Systems, 9(8), 26–32.CrossRef

Pikander, M., & Eskelinen, P. (2004). Differential GPS dynamic location experiments at sea. IEEE Magazine on Aerospace and Electronic Systems, 19(4), 36–39.CrossRef

Rezaei, S., & Sengupta, R. (2007). Kalman filter-based integration of DGPS and vehicle sensors for localization. IEEE Transactions on Control Systems Technology, 15(6), 1080–1088.CrossRef

Yang, Q., & Sun, J. (2007). A location method for autonomous vehicle based on integrated GPS/INS. In IEEE conference on vehicular electronics and safety (pp. 1–4).

Yu, J., & Chen, X. (2010). Application of extended Kalman filter in ultra-tight GPS/INS integration based on GPS software receiver. In IEEE conference on vehicular green circuits and systems (pp. 82–86).

10.

Defraigne, P., Harmegnies, A., & Petit, G. (2011). Time and frequency transfer combining GLONASS and GPS data. In IEEE joint conference on frequency control and the European frequency and time forum (pp. 1–5).

11.

Zhao, X., Qian, Y., Zhang, M., Niu, J., & Kou, Y. (2011). An improved adaptive Kalman filtering algorithm for advanced robot navigation system based on GPS/INS. In IEEE conference on mechatronics and automation (pp. 1039–1044).

12.

Grewal, M. S., & Andrews, A. P. (2010). Applications of Kalman filtering in aerospace 1960 to the present. IEEE Magazine on Control Systems, 30(3), 69–78.MathSciNetCrossRef

13.

Kim, D. M., & Suk, J. (2011). Optimal tracking filter considering both correlated/white measurement noise. In IEEE conference on control, automation and systems (pp. 1424–1428).

14.

Hayashi, M., Tanaka, T., & Yonekawa, M. (2008). High accuracy positioning of two-wheeled vehicle at high speed traveling using GPS. In 2008 SICE annual conference (pp. 3500–3503).

15.

Gelb, A. (1979). Applied optimal estimation. Cambridge, MA: Massachusetts Institute of Technology Press.

16.

Brown, R. G., & Hwang, P. Y. C. (1992). Introduction to random signals and applied Kalman filtering (2nd ed.). New York, NY: Wiley.MATH

17.

Brown, R. G., & Hwang, P. Y. C. (1997). Introduction to random signals and applied Kalman filtering (3rd ed.). New York, NY: Wiley.MATH

18.

Grewal, M. S., Weill, L. R., & Andrews, A. P. (2001). Global positioning systems, inertial navigation and integration. New York, NY: Wiley.

19.

Ford, T. J., & Hamilton, J. (2003). A new positioning filter: Phase smoothing in the position domain. Journal of the Institute of Navigation, 50(2), 65–78.

20.

Sato, G., Asai, T., Sakamoto, T., & Hase, T. (2000). Improvement of the positioning accuracy of a software-based GPS receiver using a 32-bit embedded microprocessor. IEEE Transactions on Consumer Electronics, 46(3), 521–530.CrossRef

21.

Kikiras, P., & Drakoulis, D. (2004). An integrated approach for the estimation of mobile subscriber geolocation. Journal of Wireless Personal Communications, 30, 217–231.CrossRef

22.

Vizireanu, D. N. (2011). A simple and precise real-time four point single sinusoid signals instantaneous frequency estimation method for portable DSP based instrumentation measurement. Journal of Measurement, 44(2), 500–502.CrossRef

23.

Sanguino, J. E., Tocha, F., & Rodrigues, A. (2011). WAW location-based service positioning. Journal of Wireless Personal Communications, 58, 599–612.CrossRef

24.

Azami, H., Mosavi, M. R., & Sanei, S. (2012). Classification of GPS satellites using improved back propagation training algorithms. Journal of Wireless Personal Communications. doi:10.1007/s11277-012-0844-7.

25.

Reis, J., Sanguino, J., & Rodrigues, A. (2012). Baseline influence on single-frequency GPS precise heading estimation. Journal of Wireless Personal Communications, 64, 185–196.CrossRef

Titel: Position Estimation in Single-Frequency GPS Receivers Using Kalman Filter with Pseudo-Range and Carrier Phase Measurements
Publikationsdatum: 01.10.2013
Erschienen in: Wireless Personal Communications / Ausgabe 4/2013
Print ISSN: 0929-6212
Elektronische ISSN: 1572-834X
DOI: https://doi.org/10.1007/s11277-013-1166-0

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