Abstract
In our previous research, we addressed the problem of automating the design of passive radio-frequency (PRF) services. An optimal PRF surface is one that offers a maximum probability of localization at a minimum instrumentation cost, i.e., a minimum number of surface-embedded passive RFID transponders. Our previous results were based on the assumption that the signal distribution model of an individual RFID transponder can be approximated as a circle. The problem of automated PRF surface design was then formulated as the problem of packing a surface with circles of a given radius. However, in practice, this approach leads to some loss of optimality: some areas of the surface may not be covered or too many transponders may be required. More exact methods are need for verifying and constructing signal distribution models of surface-embedded RFID transponders that can be used by surface packing algorithms to optimize the design. In this paper, we present the design and implementation of a Cartesian robot for verifying and constructing signal distribution models of surface-embedded RFID transponders. A model is characterized by four high-level parameters: an RFID transponder, an RFID antenna, an RFID reader, and a surface type. The robot moves an RFID reader-antenna unit over a PRF surface, e.g. a carpet, and systematically collects readings for various antenna positions over the surface. The collected readings are subsequently processed to verify or construct signal distribution models. We describe experiments with the robot to verify the localization probability of automatically designed PRF surfaces. We also present experiments with the robot to verify and construct the signal distribution models of a specific RFID transponder.
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References
Zita Haigh, K., Kiff, L.M., Myers, J., Guralnik, V., Gieb, C., Phelps, J., Wagner, T.: The Independent Life Style Assistant: AI Lessons Learned. In: Proceedings of the 2004 IAAI Conference (2004)
Pollack, M.: Intelligent Technology for the Aging Population. AI Magazine (2005)
Kautz, H., Arnstein, L., Borriello, G., Etzioni, O., Fox, D.: An Overview of the Assisted Cognition Project. In: Proceedings of the 2002 AAAI Workshop on Automation as Caregiver: The Role of Intelligent Technology in Elder Care (2002)
Marston, J., Golledge, R.: Towards an Accessible City: Removing Functional Barriers for the Blind and Visually Impaired: A Case for Auditory Signs Technical Report, Department of Geography, University of California at Santa Barbara (2000)
AMS Project Autonomous Movement Support Project, http://www.ubin.jp/press/pdf/TEP040915-milt01e.pdf
Patterson, D., Fishkin, K., Fox, D., Kautzh, H., Perkowitz, M., Philipose, H.: Contextual Support for Human Activity. In: Proceedings of the 2004 AAAI Spring Symposium on Interaction between Humans and Autonomous Systems OverExtended Operation (2004)
Willis, S., Helal, S.: A Passive RFID Information Grid for Location and Proximity Sensing for the Blind User University of Florida Technical Report number TR04-009 (2004)
Kantor, G., Singh, S.: Preliminary Results in Range-Only Localization and Mapping. In: IEEE Conference on Robotics and Automation (2002)
Hahnel, D., Burgard, W., Fox, D., Fishkin, K., Philipose, M.: Mapping and Localization with RFID Technology Technical Report, IRS-TR-03-014, Intel Research Institute (2003)
Tsukiyama, T.: Navigation System for Mobile Robots using RFID tags. In: IEEE Conference on Advanced Robotics (2003)
Kulyukin, V., Kutiyanawala, A., Jiang, M.: Surface-embedded Passive RF Exteroception: Kepler, Greed, and Buffon’s Needle. In: Indulska, J., Ma, J., Yang, L.T., Ungerer, T., Cao, J. (eds.) UIC 2007. LNCS, vol. 4611. Springer, Heidelberg (2007)
Minghui, J., Kulyukin, V.: Connect-the-Dots in a Graph and Buffon’s Needle on a Chessboard: Two Problems in Assisted Navigation. In: Proceedings of the 10th Joint Conference on Information Sciences and the 10th International Conference on Computer Science and Informatics (JCIS-CSI-07), Salt Lake City, UT (July 2007)
Kulyukin, V., LoPresti, E., Kutiyanawala, A., Simpson, R., Matthews, J.: A Rollator-Mounted Wayfinding System for the Elderly: Proof-of-Concept Design and Preliminary Technical Evaluation. In: Proceedings of the 30-th Annual Conference of the Rehabilitation Engineering and Assistive Technology Society of North America (RESNA 2007) (2007)
Texas Instruments Antenna Reference Guide (1999), http://focus.ti.com/lit/ug/scbu025/scbu025.pdf
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Kutiyanawala, A., Kulyukin, V. (2008). A Cartesian Robot for RFID Signal Distribution Model Verification. In: Sandnes, F.E., Zhang, Y., Rong, C., Yang, L.T., Ma, J. (eds) Ubiquitous Intelligence and Computing. UIC 2008. Lecture Notes in Computer Science, vol 5061. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-540-69293-5_20
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DOI: https://doi.org/10.1007/978-3-540-69293-5_20
Publisher Name: Springer, Berlin, Heidelberg
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