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Numerical and experimental characterization of through-the-body UHF-RFID links for passive tags implanted into human limbs

TitleNumerical and experimental characterization of through-the-body UHF-RFID links for passive tags implanted into human limbs
Publication TypeArticolo su Rivista peer-reviewed
Year of Publication2014
AuthorsLodato, R., Lopresto Vanni, Pinto Rosanna, and Marrocco G.
JournalIEEE Transactions on Antennas and Propagation
Volume62
Pagination5298-5306
ISSN0018926X
KeywordsExperimental characterization, Human limbs, Implantable antennas, loop, Passive tags, Radio frequency identification (RFID)
Abstract

Radio frequency identification (RFID) in the UHF band has been recently proposed as enabling technology to develop implanted radio-sensors to be integrated into orthopedic prosthesis because of the power autonomy and standardized communication protocols. This paper investigates the feasibility of direct and forward links for UHF-RFID (860-960 MHz) tags implanted into human limbs, that are interrogated by a noncontacting reader's antenna, with the purpose to label and, in a near future, to collect data about the health status of an implanted orthopedic prosthesis. Performance gain indicators of the through-the-body RFID channel are estimated by electromagnetic simulations over an anthropomorphic phantom as well as by means of experimentation with a real RFID communication link involving a simplified in vitro setup. The achieved results suggest that, by exploiting the current potentialities of RFID technology, and for the specific tag (loop antenna) and reader antenna (SPIFA) herein considered, a stable communication link with tags implanted inside limbs might be already feasible up to 10-35 cm from the body in full compliance with the constrains over electromagnetic exposure. In the particular case of implanted tag into an elbow, the estimated power margin in the direct and inverse links could be even suitable to set up sensing-oriented systems based onto turn-on and backscattered power modulation. © 2014 IEEE.

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URLhttps://www.scopus.com/inward/record.uri?eid=2-s2.0-84908013097&doi=10.1109%2fTAP.2014.2345586&partnerID=40&md5=7ad03d09d1400bb967a37b3ac97ce8ec
DOI10.1109/TAP.2014.2345586
Citation KeyLodato20145298