Two-stage design method for enhanced inductive energy transmission with Q-constrained planar square loops

Q-factor constraints are usually imposed on conductor loops employed as proximity range High Frequency Radio Frequency Identification (HF-RFID) reader antennas to ensure adequate data bandwidth. However, pairing such low Q-factor loops in inductive energy transmission links restricts the link transm...

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主要な著者: Eteng, Akaa Agbaeze, Abdul Rahim, Sharul Kamal, Leow, Chee Yen, Chew, Beng Wah, Vandenbosch, Guy A. E.
フォーマット: 論文
出版事項: Public Library of Science 2016
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オンライン・アクセス:http://eprints.utm.my/id/eprint/73919/
https://www.scopus.com/inward/record.uri?eid=2-s2.0-84960861863&doi=10.1371%2fjournal.pone.0148808&partnerID=40&md5=d7947cc0832475b7b9feed32826154b8
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要約:Q-factor constraints are usually imposed on conductor loops employed as proximity range High Frequency Radio Frequency Identification (HF-RFID) reader antennas to ensure adequate data bandwidth. However, pairing such low Q-factor loops in inductive energy transmission links restricts the link transmission performance. The contribution of this paper is to assess the improvement that is reached with a two-stage designmethod, concerning the transmission performance of a planar square loop relative to an initial design, without compromise to a Q-factor constraint. The first stage of the synthesis flow is analytical in approach, and determines the number and spacing of turns by which coupling between similar paired square loops can be enhanced with low deviation fromtheQ-factor limit presented by an initial design. The second stage applies full-wave electromagnetic simulations to determine more appropriate turn spacing and widths tomatch the Q-factor constraint, and achieve improved coupling relative to the initial design. Evaluating the design method in a test scenario yielded a more than 5%increase in link transmission efficiency, as well as an improvement in the link fractional bandwidth by more than 3%, without violating the loop Q-factor limit. These transmission performance enhancements are indicative of a potential for modifying proximity HFRFID reader antennas for efficient inductive energy transfer and data telemetry links.