<

This Article Statistics
Viewed : 97 Downloaded : 58 Cited : 0


 

Demands in Wireless Power Transfer of both Artificial Intelligence and Industry 4.0 for Greater Autonomy

Sedat Tarakçı *, H.Gökay Biliç, Aptülgalip Karabulut, Serhan Özdemir

Abstract

There are many autonomous applications in daily life and they are limited only by our engineering. It is critical barrier for Industry 4.0 to make efficient communication between all physical objects to transfer of information and power in today’s technology. This paper presents the efficient wireless energy transfer methods for different applications which is already used and will be widely used for Artificial Intelligence technology. After the review of historical background, mostly used inductive coupling and capacitive coupling methods in Artificial Intelligence and their importance related with Industry 4.0 applications are demonstrated. Energy transfer demands for radio frequency identification (RFID) application are discussed with the definition of backscatter coupling. Finally, using wireless communication and power transfer methods for greater autonomy is investigated.

Keywords

Capacitive Coupling, Energy, Inductive Coupling, Industry 4.0, Power Transfer, RFID, Wireless

Volume 3, No 3, Supplement, pp 23-34, 2018



Download full text   |   How to Cite   |   Download XML Files

References
  • Adair, N. (2005). RFID Power Budgets for Packaging Applications. Institute of Packaging Professionals.
  • Ali, M. & H. Nugroho. (2016). Effective power amplifier of wireless power transfer system for consumer electronics. in Power System Technology (POWERCON), 2016 IEEE International Conference.
  • Casanova, J.J., Z.N. Low, & J. Lin. (2009). Design and optimization of a class-E amplifier for a loosely coupled planar wireless power system. IEEE Transactions on Circuits and Systems II: Express Briefs. 56(11): p. 830-834.
  • Chawla, V. & Sam Ha, D. (2007). An Overview of Passive RFID. IEEE Applications & Practice. Volume 0163-6804/07. Pages 11-17.
  • Dai, J., & Ludois, D. C. (2015). Single active switch power electronics for kilowatt scale capacitive power transfer. IEEE Journal of Emerging and Selected Topics in Power Electronics, 3(1), 315-323.
  • Dai, J., & Ludois, D. C. (2015, March). Wireless electric vehicle charging via capacitive power transfer through a conformal bumper. In Applied Power Electronics Conference and Exposition (APEC), 2015 IEEE (pp. 3307-3313). IEEE.
  • Fan, Z., Gao, X. R., & Kazmer O. D. (2010). Design of a Self Energized Wireless Sensors for Simultaneous Pressure and Temperature Measurement. IEEE Xplore. DOI:10.1109/AIM.2010.5695931.
  • Finkenzeller, K. (2010). RFID Handbook Fundamentals and Applications in Contactless Smart Cards, Radio Frequency Identification and Near Field Communication. West Sussex, United Kingdom: John Wiley & Sons Ltd.
  • Hassan, M.A. & A. Elzawawi. (2015). Wireless Power Transfer through Inductive Coupling. in Proc. of 19th International Conference on Circuits (part of CSCC'15).
  • Islam, A.B.(2011). Design of wireless power transfer and data telemetry system for biomedical applications.
  • Jiang, H., et al. (2012). Safety considerations of wireless charger for electric vehicles—A review paper. in Product Compliance Engineering (ISPCE), 2012 IEEE Symposium.
  • Katrin, N. (editor). (2015). Siemens Global, Industry & Automation. World Wide Web Electronic Publication. https://www.siemens.com/innovation, version (05/2015).
  • Kinergizer BV. Delft, the Netherlands. World Wide Web Electronic Publication. www.kinergizer.com, version (10/2018).
  • Landt, J (2005). The History of RFID. IEEE Potentials. Volume 0278-6648/05. Pages 8-11.
  • Mostafa, T. M., Muharam, A., & Hattori, R. (2017, May). Wireless battery charging system for drones via capacitive power transfer. In Emerging Technologies: Wireless Power Transfer (WoW), 2017 IEEE PELS Workshop on (pp. 1-6). IEEE.
  • Nilsson, W. J., Riedel, N. (2011). Natural and step responses of RLC circuit, Sinusoidal steady-state Analysis. In: Electric Circuits (Gilfillan, A. and Kerman, F.), Pearson Education, pp.286-368, New Jersey.
  • Oh Eunjeon (editor). (2018). Robotic arm, Canada. World Wide Web Electronic Publication. https://grabcad.com/library/robotic-arm-137, version (10/2018).
  • Pinuela, M., et al.(2013). Maximizing DC-to-load efficiency for inductive power transfer. IEEE transactions on power electronics. 28(5): p. 2437-2447.
  • Poon, A.S., O'Driscoll, S., & Meng, T.H.(2010). Optimal frequency for wireless power transmission into dispersive tissue. IEEE Transactions on Antennas and Propagation. 58(5): p. 1739-1750.
  • Priya, S. & Inman, D. J. (2009). Energy Harvesting Technologies. New York, NY: Springer Science+Business Media.
  • Qiu, C., et al. (2013). Overview of wireless power transfer for electric vehicle charging. in Electric Vehicle Symposium and Exhibition (EVS27), IEEE.
  • Rozario, D. (2016). Design of contactless capacitive power transfer systems for battery charging applications (PhD. dissertation).
  • Sayre, C. W. (2008). Complete Wireless Design. New York, NY: The McGraw-Hill Companies Inc.
  • Sepahvand, A., Kumar, A., Afridi, K., & Maksimović, D. (2015, July). High power transfer density and high efficiency 100 MHz capacitive wireless power transfer system. In Control and Modeling for Power Electronics (COMPEL), 2015 IEEE 16th Workshop on (pp. 1-4). IEEE.
  • Shen, W. (2010). Wireless Power in Passive RFID System. Mikkeli University of Applied Sciences, Bachelor’s Thesis Information Technology. Mikkeli, Finland
  • Sokal, N.O.(2001). Class-E RF power amplifiers. QEX, 2001. 204(1): p. 9-20.
  • Sorrells, P. (1998). Passive RFID Basics. Microchip Technology Inc. USA. DS00680B. Pages 1-5.
  • Xia, C., et al. (2012). Comparison of Power Transfer Characteristics between CPT and IPT System and Mutual Inductance Optimization for IPT System. JCP. 7(11): p. 2734-2741.
  • Yi, K. H. (2015). 6.78 MHz capacitive coupling wireless power transfer system. Journal of Power Electronics, 15(4), 987-993.