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Active RFID Trilateration and Location Fingerprinting Based on RSSI for Pedestrian Navigation

Published online by Cambridge University Press:  12 March 2009

Qing Fu
Affiliation:
(Institute of Geodesy and Geophysics, Vienna University of Technology, Austria)
Guenther Retscher*
Affiliation:
(Institute of Geodesy and Geophysics, Vienna University of Technology, Austria)
*

Abstract

In the work package ‘Integrated Positioning’ of the Ubiquitous Cartography for Pedestrian Navigation project (UCPNAVI) alternative location methods using active Radio Frequency Identification (RFID) are investigated for positioning of pedestrians in areas where no GNSS position determination is possible due to obstruction of the satellite signals. In most common RFID applications, positioning is performed using cell-based positioning. RFID tags can be installed at active landmarks (i.e., known locations) in the surroundings and a user equipped with an RFID reader can be positioned using Cell of Origin (CoO). The positioning accuracy, however, depends on the size of the cell defined by the maximum range of the signal. Using long range RFID for positioning the cell size can be quite large, i.e., around 20 m. Therefore, the paper proposes two new methods for positioning, i.e., trilateration and location fingerprinting based on received signal strength indication (RSSI) if more than one RFID tag is visible. The trilateration approach is based on the deduction of ranges to the RFID tags from RSSI. An iterative approach to model the signal propagation will be introduced, i.e., the International Telecommunication Union (ITU) indoor location model that can be simplified to a logarithmic model, and a simple polynomial model is employed for the signal strength to range conversion. In a second attempt, location fingerprinting based on RSSI is investigated. In this case, RSSI is measured in a training phase at known locations inside the building and stored in a database. In the positioning phase these measurements are used together with the current measurements to obtain the current location of the user. For the estimation of the current location different approaches are employed and tested, i.e., a direction-based approach, a tag-based approach, a direction-tag-based approach and a heading-based approach. Using trilateration or fingerprinting positioning accuracies on the one to a few metres level can usually be achieved. The concept and the iterative approach of the different methods and test results are discussed in this paper.

Type
Research Article
Copyright
Copyright © The Royal Institute of Navigation 2009

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References

REFERENCES

Finkenzeller, K., 2002. RFID Handbook: Fundamentals and Application in Contactless Smart Cards and Identification, Carl Hanser Verlag, Munich, Germany, see http://www.rfid-handbook.de/ (Last date accessed: March 2008).Google Scholar
Fu, Q., 2008. Active RFID for Positioning Using Trilateration and Location Fingerprinting Based on RSSI, in: Papers presented at the ION GNSS 2008 Conference, September 16–19, 2008, Savannah, Georgia, USA, CD-Rom Proceedings.Google Scholar
Kaemarungsi, K., 2005. Design of Indoor Positioning Systems Based on Location Fingerprinting Technique, Dissertation, University of Pittsburgh, see http://etd.library.pitt.edu/ETD/available/etd-02232005-235903/unrestricted/dissertation28Feb05.pdf (Last date accessed: July 2008).Google Scholar
Ranvier, S., 2004. Path Loss Models, S-72.333 Physical Layer Methods in Wireless Communication Systems, Postgraduate Course on Radiocommuications, Helsinki University of Technology, SMRAD Centre of Excellence, http://www.comlab.hut.fi/opetus/333/2004_2005_slides/Path_loss_models.pdf (Last date accessed: July 2008).Google Scholar
Retscher, G., Moser, E., Vredeveld, D., Heberling, D., Pamp, J., 2007. Performance and Accuracy Test of a WiFi Indoor Positioning System, Journal of Applied Geodesy, 1, 2, 103110.CrossRefGoogle Scholar
Retscher, G., Fu, Q., 2007a. Integration of RFID, GNSS and DR for Ubiquitous Positioning in Pedestrian Navigation, in: Papers presented at the ION GNSS 2007 Conference, Fort Worth, Texas U.S.A., September 25–28, 2007, CD-Rom Proceedings, 10 pgs.Google Scholar
Retscher, G., Fu, Q., 2007b. Using Active RFID for Positioning in Navigation Systems, In: Papers presented at the 4th International Symposium on Location Based Services and Telecartography, Hong Kong, PR China; November 08–10, 2007, CD-Rom Proceedings, 11 pgs.Google Scholar
Wikipedia, 2008. ITU Model for Indoor Attenuation, see http://en.wikipedia.org/wiki/ITU_Model_for_Indoor_Attenuation (Last date accessed: March 2008).Google Scholar