Optimal Waveforms for Efficient Wireless Power Transmission

This work shows how using specifically selected or designed waveforms in wireless power transfer (WPT) systems can lead to improved RF to dc conversion efficiency in rectifier circuits in the receiving end of these systems. Signals with different time domain waveforms are considered such as OFDM, wh...

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Published in	IEEE microwave and wireless components letters Vol. 24; no. 5; pp. 354 - 356
Main Authors	Collado, A., Georgiadis, A.
Format	Journal Article
Language	English
Published	New York, NY IEEE 01.05.2014 Institute of Electrical and Electronics Engineers
Subjects	Antennas Applied sciences Circuits Constants Conversion Energy harvesting Exact sciences and technology Microwaves Peak to average power ratio Power transmission Radiocommunications Receiving rectenna rectifier Rectifiers Telecommunications Telecommunications and information theory Time-domain analysis Waveforms White noise Wireless communication Wireless power transmission Chaos Performance evaluation Rectifier Conversion rate Rectifying circuits Peak to average power ratio Energy recovery Wireless electricity Single carrier Energy harvesting wireless power transmission Rectennas Time domain method White noise Orthogonal frequency division multiplexing rectenna Comparative study
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Abstract	This work shows how using specifically selected or designed waveforms in wireless power transfer (WPT) systems can lead to improved RF to dc conversion efficiency in rectifier circuits in the receiving end of these systems. Signals with different time domain waveforms are considered such as OFDM, white noise and chaotic waveforms, and the performance of a rectifier circuit operating at 433 MHz is evaluated when using these signals in comparison to a single carrier constant envelope signal. The performed experiments show that selecting high peak to average power ratio (PAPR) signals lead to improved RF-DC conversion efficiency in rectifier circuits.
AbstractList	This work shows how using specifically selected or designed waveforms in wireless power transfer (WPT) systems can lead to improved RF to dc conversion efficiency in rectifier circuits in the receiving end of these systems. Signals with different time domain waveforms are considered such as OFDM, white noise and chaotic waveforms, and the performance of a rectifier circuit operating at 433 MHz is evaluated when using these signals in comparison to a single carrier constant envelope signal. The performed experiments show that selecting high peak to average power ratio (PAPR) signals lead to improved RF-DC conversion efficiency in rectifier circuits.
Author	Georgiadis, A. Collado, A.
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SubjectTerms	Antennas Applied sciences Circuits Constants Conversion Energy harvesting Exact sciences and technology Microwaves Peak to average power ratio Power transmission Radiocommunications Receiving rectenna rectifier Rectifiers Telecommunications Telecommunications and information theory Time-domain analysis Waveforms White noise Wireless communication Wireless power transmission
Title	Optimal Waveforms for Efficient Wireless Power Transmission
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