Coupling Estimation and Maximum Efficiency Tracking in Multi-Transmitters WPT for Fast Moving Receiver

Coupling Estimation and Maximum Efficiency Tracking in Multi-Transmitters WPT for Fast Moving Receiver

Maximum efficiency tracking (MET) with multiple concurrently-activated transmitters (TXs) has not yet been investigated thoroughly. This paper proposes a fast real-time estimation of coupling coefficients and load resistance for multiple concurrently-activated TXs and a moving RX. This is the first...

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Bibliographic Details
Published in:IEEE access Vol. 12; pp. 9952 - 9962
Main Authors: Khan, Shahid Ali, Ahn, Dukju
Format: Journal Article
Language:English
Published: Piscataway The Institute of Electrical and Electronics Engineers, Inc. (IEEE) 2024
IEEE
Subjects:
Circuits
Controllers
Coupling coefficients
Dynamic wireless power transfer
Efficiency
Electric potential
Iterative methods
Load resistance
maximum efficiency point tracking
multiple transmitters
Parameter estimation
Power flow
resonant converter
Tracking
Transmitters
Voltage
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Summary:Maximum efficiency tracking (MET) with multiple concurrently-activated transmitters (TXs) has not yet been investigated thoroughly. This paper proposes a fast real-time estimation of coupling coefficients and load resistance for multiple concurrently-activated TXs and a moving RX. This is the first paper that demonstrates iteration-less, fast, communication-less MET with power regulation when the RX is moving across multiple activated TX array. The controller senses only the voltage magnitude of TX coil-capacitor resonator, and the input DC voltage and DC current of inverter. Once the parameters are estimated, the controller sets the converters to maximum efficiency point immediately. The benefits of proposed method are that it does not require a communication channel, extra circuit components for MET, time-consuming iterations and computations, and periodic interruption of power flow due to load disconnection or initialization, all of which were limitations in typical methods. Experimental results show that the proposed method provides a fast response (3.8ms) for an RX moving at 6.84 km/h across multiple TXs.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2024.3352636