Broadband EC Models of Coil Antennas for Inductively Coupled Systems

Broadband EC Models of Coil Antennas for Inductively Coupled Systems

Wireless energy and data transfer systems in the near field are mostly based on inductively coupled coil antennas. These systems require accurate coil antenna equivalent circuit (EC) models for an efficient system design. In this work, we present broadband EC models of coil antennas to conduct circu...

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Bibliographic Details
Published in:2022 Wireless Power Week (WPW) pp. 465 - 469
Main Authors: Fischbacher, Richard, Pommerenke, David, Prestros, Ralph, Lopera, Jose Romero, Bosch, Wolfgang, Grosinger, Jasmin
Format: Conference Proceeding
Language:English
Published: IEEE 05-07-2022
Subjects:
Analytical models
Antenna measurements
Coil antennas
Couplings
Data models
Data transfer
equivalent circuits
near-field communication
Prototypes
radio-frequency identification
Wireless communication
wireless power transfer
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Summary:Wireless energy and data transfer systems in the near field are mostly based on inductively coupled coil antennas. These systems require accurate coil antenna equivalent circuit (EC) models for an efficient system design. In this work, we present broadband EC models of coil antennas to conduct circuit-level analyses of such wireless energy and data transfer systems versus a broad frequency range, e.g., wireless power transfer (WPT) or near-field communication (NFC) systems. The novelty of the EC models lies in their broadband nature compared to previous work. We provide an approach to model single coil antennas far above their self-resonant frequency with a simple broadband EC model, for analyzing the system's interoperability or coexistence with other systems. Additionally, we provide a broadband EC model of strongly coupled coil antennas with a particular focus on the modeling of parasitic capacitive coupling, which can severely impair communication system performance. The proposed EC models were developed and verified from 10 kHz up to 100 MHz by measurements and finite element simulations.
DOI:10.1109/WPW54272.2022.9854040