Quantifying the Impact of Slow Wave Factor on Closed-Loop Defect-Based WPT Systems

Kassen Dautov; Mohammad S. Hashmi; N. Nasimuddin; Muhammad Akmal Chaudhary; Galymzhan Nauryzbayev

doi:10.1109/TIM.2022.3181938

Quantifying the Impact of Slow Wave Factor on Closed-Loop Defect-Based WPT Systems

Kassen Dautov
, Mohammad S. Hashmi
, N. Nasimuddin
, Muhammad Akmal Chaudhary
, Galymzhan Nauryzbayev

College of Engineering and Information Technology

Nazarbayev University
Agency for Science, Technology and Research, Singapore

Research output: Contribution to journal › Article › peer-review

27 Scopus citations

Abstract

This article reports the impact of the slow wave effect (SWE) on the design, analysis, and performance of defected ground structure (DGS)-based resonators and the associated wireless power transfer (WPT) systems. As a case study, a systematic analysis of closed-loop polygonal DGS-based resonators is developed which enables a unique methodology to trade off the defect shape and, in turn, SWE and the magnetic field to improve the resonator's effectiveness. It is conceptualized and then experimentally demonstrated that the performance of DGS-based resonators is shape-independent for closed-loop defects. Subsequently, these resonators were aptly utilized to develop a WPT system prototype. An excellent agreement between the theoretical and measurement results demonstrates the effectiveness of the presented DGS-type WPT concept in this article.

Original language	English
Article number	8004310
Journal	IEEE Transactions on Instrumentation and Measurement
Volume	71
DOIs	https://doi.org/10.1109/TIM.2022.3181938
State	Published - 2022

Keywords

Defected ground structure (DGS)
H-field
near-field wireless power transfer (WPT)
resonator characterization
slow wave factor (SWF)

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10.1109/TIM.2022.3181938

Cite this

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title = "Quantifying the Impact of Slow Wave Factor on Closed-Loop Defect-Based WPT Systems",

abstract = "This article reports the impact of the slow wave effect (SWE) on the design, analysis, and performance of defected ground structure (DGS)-based resonators and the associated wireless power transfer (WPT) systems. As a case study, a systematic analysis of closed-loop polygonal DGS-based resonators is developed which enables a unique methodology to trade off the defect shape and, in turn, SWE and the magnetic field to improve the resonator's effectiveness. It is conceptualized and then experimentally demonstrated that the performance of DGS-based resonators is shape-independent for closed-loop defects. Subsequently, these resonators were aptly utilized to develop a WPT system prototype. An excellent agreement between the theoretical and measurement results demonstrates the effectiveness of the presented DGS-type WPT concept in this article.",

keywords = "Defected ground structure (DGS), H-field, near-field wireless power transfer (WPT), resonator characterization, slow wave factor (SWF)",

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doi = "10.1109/TIM.2022.3181938",

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AU - Dautov, Kassen

AU - Hashmi, Mohammad S.

AU - Nasimuddin, N.

AU - Chaudhary, Muhammad Akmal

AU - Nauryzbayev, Galymzhan

PY - 2022

Y1 - 2022

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AB - This article reports the impact of the slow wave effect (SWE) on the design, analysis, and performance of defected ground structure (DGS)-based resonators and the associated wireless power transfer (WPT) systems. As a case study, a systematic analysis of closed-loop polygonal DGS-based resonators is developed which enables a unique methodology to trade off the defect shape and, in turn, SWE and the magnetic field to improve the resonator's effectiveness. It is conceptualized and then experimentally demonstrated that the performance of DGS-based resonators is shape-independent for closed-loop defects. Subsequently, these resonators were aptly utilized to develop a WPT system prototype. An excellent agreement between the theoretical and measurement results demonstrates the effectiveness of the presented DGS-type WPT concept in this article.

KW - Defected ground structure (DGS)

KW - H-field

KW - near-field wireless power transfer (WPT)

KW - resonator characterization

KW - slow wave factor (SWF)

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DO - 10.1109/TIM.2022.3181938

M3 - Article

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JO - IEEE Transactions on Instrumentation and Measurement

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ER -

Quantifying the Impact of Slow Wave Factor on Closed-Loop Defect-Based WPT Systems

Abstract

Keywords

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