Characterization of high-Q inductors up to its self-resonance frequency for wireless power transfer applications

Arturo Fajardo Jaimes; Fabian L. Cabrera; Fernando Rangel De Sousa

doi:10.1109/LMWC.2018.2876770

Characterization of high-Q inductors up to its self-resonance frequency for wireless power transfer applications

Arturo Fajardo Jaimes
, Fabian L. Cabrera
, Fernando Rangel De Sousa

Universidade Federal de Santa Catarina

Producción: Contribución a una revista › Artículo › revisión exhaustiva

5 Citas (Scopus)

Resumen

The primary coil of an efficient asymmetric inductive link (IL) has a high quality factor and operates near its self-resonance frequency (SRF). Therefore, its characterization is challenging, especially because the measurement instruments must be able to measure a large reactance and a very small resistance at a frequency where the inductor radiates. In this letter, we present a method suitable for characterizing high-$Q$ inductors up to its SRF. The proposed method uses an inductive sensor to characterize the inductor under test without galvanic contact. The method was validated by applying it to the primary coil of an asymmetric IL. The empirical results are consistent with the theoretical model and the full-wave simulations.

Idioma original	Inglés
Número de artículo	8535021
Páginas (desde-hasta)	1071-1073
Número de páginas	3
Publicación	IEEE Microwave and Wireless Components Letters
Volumen	28
N.º	12
DOI	https://doi.org/10.1109/LMWC.2018.2876770 https://doi.org/10.1109/lmwc.2018.2876770
Estado	Publicada - dic. 2018
Publicado de forma externa	Sí

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title = "Characterization of high-Q inductors up to its self-resonance frequency for wireless power transfer applications",

abstract = "The primary coil of an efficient asymmetric inductive link (IL) has a high quality factor and operates near its self-resonance frequency (SRF). Therefore, its characterization is challenging, especially because the measurement instruments must be able to measure a large reactance and a very small resistance at a frequency where the inductor radiates. In this letter, we present a method suitable for characterizing high-\$Q\$ inductors up to its SRF. The proposed method uses an inductive sensor to characterize the inductor under test without galvanic contact. The method was validated by applying it to the primary coil of an asymmetric IL. The empirical results are consistent with the theoretical model and the full-wave simulations.",

keywords = "Inductor, quality factor, self-resonance frequency (SRF), wireless power transfer (WPT)",

author = "Jaimes, \{Arturo Fajardo\} and Cabrera, \{Fabian L.\} and \{De Sousa\}, \{Fernando Rangel\}",

note = "Publisher Copyright: {\textcopyright} 2018 IEEE.",

year = "2018",

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doi = "10.1109/LMWC.2018.2876770",

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AU - Jaimes, Arturo Fajardo

AU - Cabrera, Fabian L.

AU - De Sousa, Fernando Rangel

PY - 2018/12

Y1 - 2018/12

N2 - The primary coil of an efficient asymmetric inductive link (IL) has a high quality factor and operates near its self-resonance frequency (SRF). Therefore, its characterization is challenging, especially because the measurement instruments must be able to measure a large reactance and a very small resistance at a frequency where the inductor radiates. In this letter, we present a method suitable for characterizing high-$Q$ inductors up to its SRF. The proposed method uses an inductive sensor to characterize the inductor under test without galvanic contact. The method was validated by applying it to the primary coil of an asymmetric IL. The empirical results are consistent with the theoretical model and the full-wave simulations.

AB - The primary coil of an efficient asymmetric inductive link (IL) has a high quality factor and operates near its self-resonance frequency (SRF). Therefore, its characterization is challenging, especially because the measurement instruments must be able to measure a large reactance and a very small resistance at a frequency where the inductor radiates. In this letter, we present a method suitable for characterizing high-$Q$ inductors up to its SRF. The proposed method uses an inductive sensor to characterize the inductor under test without galvanic contact. The method was validated by applying it to the primary coil of an asymmetric IL. The empirical results are consistent with the theoretical model and the full-wave simulations.

KW - Inductor

KW - quality factor

KW - self-resonance frequency (SRF)

KW - wireless power transfer (WPT)

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JF - IEEE Microwave and Wireless Components Letters

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ER -

Characterization of high-Q inductors up to its self-resonance frequency for wireless power transfer applications

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