Analysis of Different Matching Technique for realization of Effective RF Energy Harvesting Circuit

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IJCA Proceedings on International Conference on Quality Up-gradation in Engineering Science and Technology
© 2017 by IJCA Journal
ICQUEST 2016 - Number 2
Year of Publication: 2017
Authors:
Poonam A. Awathare
Sanjay Tembhurne

Poonam A Awathare and Sanjay Tembhurne. Article: Analysis of Different Matching Technique for realization of Effective RF Energy Harvesting Circuit. IJCA Proceedings on International Conference on Quality Up-gradation in Engineering Science and Technology ICQUEST 2016(2):1-4, August 2017. Full text available. BibTeX

@article{key:article,
	author = {Poonam A. Awathare and Sanjay Tembhurne},
	title = {Article: Analysis of Different Matching Technique for realization of Effective RF Energy Harvesting Circuit},
	journal = {IJCA Proceedings on International Conference on Quality Up-gradation in Engineering Science and Technology},
	year = {2017},
	volume = {ICQUEST 2016},
	number = {2},
	pages = {1-4},
	month = {August},
	note = {Full text available}
}

Abstract

In this paper the analysis of the different types of input impedance matching network for realization of efficient RF energy harvesting circuit. In mobile application like wireless sensors there is issue of long term power backup and charging of batteries. In this paper, there is design to matching circuit compatible for RF energy harvesting by using L-section to proposed for obtaining the signal bandwidth 900MHz with a noise figure of 4. 8 dB. L network is working as resonating frequency( 900MHz) as well as matching network at resonant frequency.

References

  • T. Umeda, H Yoshida, S. Sekine, Y. Fujita, T. Suzuki, and S. Otaka, "A 950 MHz rectifier circuit for sensor network tags with 10 m distance", IEEE J. Solid-State Circuits, vol. 41, no. 1, Jan. 2006.
  • P. Nintanavongsa, U. Muncuk, D. R. Lewis, and K. R. Chowdhury,"Design Optimization and Implementation for RF Energy Harvesting Circuits", IEEE Journal on Emerging and Selected Topics in Circuits and Systems, vol. 2, no. 1, pp. 24-33, Mar. 2012.
  • H. Nakamoto, D. Yamazaki, T. Yamamoto, H. Kurata, S. Yamada, K. Mukaida, T. Ninomiya, T. Ohkawa, S. Masui, and K. Gotoh, "A passive UHF RFID Tang LSI with 36. 6% efficiency CMOS-Only rectifier and current-mode demodulator in 0. 35 um FeRam technology", in Proc. IEEE ISSC Conf. 2006, Feb. 6-9, 2006, pp. 1201-1210.
  • Gaurav Singh Rahul Ponnaganti T. V. Prabhakar K. J. Vinoy''A tuned rectifier for RF energy harvesting from ambidient radiations'',AEUInternational Journal of Electronics and Communication,Volume 67,Issue 7,July 2013,Pages 564-569,ISSN 1434-8411.
  • J. P. Curty N. Joehl, F. krummenacher C. Dehollain, and M. J. Declerc,''A model for u-power rectifier analysis and design'',IEEE Trans. Circuit Syst, vol. 52, no. 12,pp. 2771-2779,Dec. 2005.
  • Singh G, Ponnaganti R. Ambient RF energy harvesting and monitoring. M. Tech. Dissertation. Centre For Electronics Design and Technology, Faculty of Engineering, Indian Institute of Science, Bangalore; June 2011.
  • Oi-Ying Wong, Hei Wong, Wing-shan Tam, chi-Wah kok, Topology,analysis and CMOS implementation of switched capacitor DC-Dc Converters. Electronics and Energitics Vol. 27,No. 1,March 2014,pp. 41-46.
  • T. Van Breussegem and M. Steyarert,,Converter Topologyand Fundamentals,CMOS Integrated capacitive DC-DC Converters,Analog Circuits and Signal Processing DOI:10. 1007/978-1-4614-4280-6_2.
  • Miles M. turner, Greg Branch and Paul W. Switch, Method of theoretical Analysis and Computer Modeling of the Shaping of Electrical Pulses by the Non-Linear Transmission lines and lumpedElements Delay lines. IEEE TRANSACTION ON ELECTRON DEVICES,VOL. 38. NO. 4 APRIL 1991.
  • Hema Ramachandran,Bindhu G. R. ,Optimum Wireless Power Transfer using Lumped L-Section Networks. ,2015 International on Circuit Power and Computing Technologies [ICCPCT].
  • Ngee Siang kuck. Ah Choy Liew, Edl. Schamiloglu and Jose Osvaldo Rossi. , Circuit Modelling of Non-Linear Lines Including Hybrid lines. IEEE TRANSACTION on PLASMA SCIENCE VOL. 40 No. 10,OCTOBER 2012.
  • Praharshin M. Senadeera, James Greggs, Zhijian Xie, and Numan S. Dogan, Meng Li,and Nader Behad,and Hriseyin S. Savci. X-Band Energy Harvester with minaiaturized on chip Slot Antenna Implemented in 0. 18um RF CMOS. 978-1-4577-2032-1/12,2012IEEE.
  • Zhicheng Lin ,Pui-in Mak,and Rui. P,Martins. A SubGHZ Multi-ISM-Band Zigbee Receiver Using Function-Reuse and Gain-Boosted N-Path Techniques for IoT Applications. IEEE JOURNAL OF SOLID STATE CIRCCUITS, VOL,49. No. 12, DECEMBER 2014.
  • G. Tant , A. GIry, P. Ferris, G. pares, J. D. Armould, J-M. Fournier, C. Raynaud, P. vincent,. A SOI CMOS reconfigurable Output Matching Network for multimode, Multiband Power Amplifiers. 978-1-4799-8275-2/15/2005 IEEE.
  • Shintaro Wantanabe,Yoichiro Takayama, Ryo Tshikawa and Kazichiko Honjo. , A Broadband Doherty Power Amplifier Without a Quarter-Wave impedence Inverting Network. Proceeding of APMC 2012, Kaohsiung, Taiwan, Dec. 4-7,2012.
  • Zhicheng Lin, Pui. In Mak and Rui P. Martins. , Analysis and Modeling of Gain-Boosted N-Path Swiched Capacitor Bandpass Filter. IEEE TRANSACTION On Circuits and System-I:Regular Papers,VOL. 61, No. 9 September 2014.
  • S. Scorcioni, L. Larcher ,A. Bertacchini. Optimised CMOS RF-DC Converter for Remote Wireless Powering of RFID Applications. 2012 IEEE International Conference on RFID 298-1-4676-0328-6/12.
  • Geffrey K. Ottamn, Health F. Hofmann, Archin C,Bhatt and George A. Lesiutre, Adaptive Piezoelectric Energy Harvesting Circuit for Wireless Remote Power. IEEE TRANSACTION On Power Electronics, VOL. 17, No. 5;September 2002.
  • A. Sample and J. R. Smith, "Experimental result with two wirelessvpower transfer system," in IEEE Radio Wireless Symp, Jan. 2009, pp. 16-18.