Authors: P. Chambe, B. Canova, A. Balabanian, M. Pele, N. Coeur

Abstract:

To avoid battery assisted tags with limited lifetime batteries, it is proposed here to replace them by energy harvesting systems, able to feed from local environment. This would allow total independence to RFID systems, very interesting for applications where tag removal from its location is not possible. Example is here described for luggage safety in airports, and is easily  extendable to similar situation in terms of operation constraints. The idea is to fix RFID tag with energy harvesting system not only to identify luggage but also to supply an embedded microcontroller with a sensor delivering luggage weight making it impossible to add or to remove anything from the luggage during transit phases. The aim is to optimize the harvested energy for such RFID applications, and to study in which limits these applications are theoretically possible. Proposed energy harvester is based on two energy sources: piezoelectricity and electromagnetic waves, so that when the luggage is moving on ground transportation to airline counters, the piezo module supplies the tag and its microcontroller, while the RF module operates during luggage transit thanks to readers located along the way. Tag location on the luggage is analyzed to get best vibrations, as well as harvester better choice for optimizing the energy supply depending on applications and the amount of energy harvested during a period of time. Effects of system parameters (RFID UHF frequencies, limit distance between the tag and the antenna necessary to harvest energy, produced voltage and voltage threshold) are discussed and working conditions for such system are delimited.

Keywords: EM waves, Energy Harvesting, Piezoelectric, RFID Tag.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1093662

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References:

[1] N. Elvin, A. Erturk: Introduction and Methods of Energy Harvesting, Advances in Energy Harvesting Methods, N. Elvin, A. Erturk, eds, pp.3- 14, Springer, 2013
[2] D. Paret : RFID en Ultra et Super Hautes Fréquences UHF-SHF - Théorie et Mise en Oeuvre, Technique et Ingénierie, Dunod / L'Usine Nouvelle, 2008.H. Poor, An Introduction to Signal Detection and Estimation. New York: Springer-Verlag, 1985, ch. 4.
[3] S. Priya, D.J. Inman: Energy Harvesting Technologies, Springer, New York, 2009; S. Beeby, N. White: Energy Harvesting for Autonomous Systems, Artech House Publ., Boston, 2010
[4] M. Gorlatova, P. Kinget, I. Kymissis, D. Rubenstein, X. Wang, G. Zussman: Energy Harvesting Active Networked Tags (EnHANTs) for Ubiquitous Object Networking, IEEE Wireless Communications, Special Issue on the Internet of Things: The Next Big Thing in Communications, Vol.17(6), pp. 18–25, 2010, and : Challenge: Ultra- Low-Power Energy-Harvesting Active Networked Tags (EnHANTs),” in Proc. ACM MOBICOM’09, 2009
[5] R. Dayal, S. Dwari, L. Parsa : A New Design for Vibration Based Electromagnetic Energy Harvesting Systems Using Coil Inductance of Microgenerator, IEEE Trans. on Industry Applications. Vol.47 (2), March/April 2011C. J. Kaufman, Rocky Mountain Research Lab., Boulder, CO, private communication, May 1995.
[6] E. Dallago, M. Marchesi, G. Venchi : Analytical Model of a Vibrating Electromagnetic Harvester Considering Nonlinear Effects, IEEE Trans. on Power Electronics, Vol.25(8), pp.1989-1997, 2010; R. Dayal, S. Dwari, L. Parsa : A New Design for Vibration Based Electromagnetic Energy Harvesting Systems Using Coil Inductance of Microgenerator, IEEE Trans. on Industry Applications. Vol.47 (2), March/April 2011; H. El Anzeery, M. El Bagouri, and R. Guindi: Novel Radio Frequency Energy Harvesting Model, IEEE Intern. Power Engineering and Optimization Conf. (PEOCO2012), Melaka, Malaysia, 6-7 June 2012; N.G. Elvin, A.A. Elvin: An Experimentally Validated EM Energy Harvester, J. Sound Vib. Vol.330, pp.2314-2324, 2011M. Young, The Techincal Writers Handbook. Mill Valley, CA: University Science, 1989.
[7] S.R. Anton, H.A. Sodano: A Review of Power Harvesting Using Piezoelectricity Materials, Smart Mater Struct. Vol.16, R1-R21, 2007; A. Erturk, D.J. Inman: Piezoelectric Energy Harvesting, Wiley, Chichester, 2011
[8] S. Roundy, P.K. Wright, J.M. Rabaey: Energy Scavenging for Wireless Sensor Networks with Speciel Focus on Vibrations, Kluwer Acad., Boston, 2004; M. Gorlatova, J. Sarik, G. Grebla, M. Cong, I. Kymissis, G. Zussman : Movers and Shakers: Kinetic Energy Harvesting for the Internet of Things,” in Proc. ACM SIGMETRICS’14 (to appear), 2014; E. Minazara, D. Vasic, F. Costa : Piezoelectric Generator Harvesting Bike Vibrations Energy to Supply Portable Devices, Intern. Conf. on Renewable Energies and Power Quality, 2008; S. Meninger, J.O. Mur- Miranda, R. Amirtharajah, A. Chandrakasan, J.H. Lang: Vibration-to- Electric Energy Conversion, IEEE Trans. VLSI Syst., Vol.9, pp.61-76, 2001; M. Soliman, E. Abddel-Rahman, E. El-Saadany, R. Mansour: A Wideband Vibration-based Energy Harvester, J. Micromech. Microeng., Vol.18, 115021, 2008
[9] Datasheet of LTC3330: Nanopower Buck-Boost DC/DC with Energy Harvesting Battery Life Extender, http://cds.linear.com/docs/en/ datasheet/3330fa.pdf; Datasheet of LTC3388: 20V High Efficiency Nanopower Step-Down Regulator, http://cds.linear.com/docs/en/ datasheet/338813f.pdf.
[10] M. Gorlatova, A. Wallwater, G. Zussman: Networking Low-Power Energy Harvesting Devices: Measurements and Algorithms, IEEE Transactions on Mobile Computing, Vol.12 (9), pp.1853–1865, 2013, and Proc. IEEE NFOCOM’11, 2011.