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Energy harvesting for wearable senso...

Manoli, Yiannos.

Energy harvesting for wearable sensor systemsinductive architectures for the swing excitation of the leg /

紀錄類型:	書目-電子資源 : Monograph/item
正題名/作者:	Energy harvesting for wearable sensor systemsby Klevis Ylli, Yiannos Manoli.
其他題名:	inductive architectures for the swing excitation of the leg /
作者:	Ylli, Klevis.
其他作者:	Manoli, Yiannos.
出版者:	Singapore :Springer Singapore :2021.
面頁冊數:	xxix, 143 p. :ill., digital ;24 cm.
Contained By:	Springer Nature eBook
標題:	Energy harvesting.
電子資源:	https://doi.org/10.1007/978-981-33-4448-8
ISBN:	9789813344488$q(electronic bk.)

Energy harvesting for wearable sensor systemsinductive architectures for the swing excitation of the leg /
Ylli, Klevis.

Energy harvesting for wearable sensor systemsinductive architectures for the swing excitation of the leg /[electronic resource] :by Klevis Ylli, Yiannos Manoli. - Singapore :Springer Singapore :2021. - xxix, 143 p. :ill., digital ;24 cm. - Springer series in advanced microelectronics,v.621437-0387 ;. - Springer series in advanced microelectronics ;3..

Abstract -- 1. Introduction -- 2. Theory and Modeling -- 3. Geometrical Parameter Optimization -- 4. Experimental Evaluation of Fabricated Architectures -- 5. Second Optimization Run -- 6. Second Generation HAC Experimental Results -- 7. Applications -- 8. Conclusion and Outlook -- A. Appendix -- B. List of Publications -- Bibliography -- Nomenclature.

This book investigates several non-resonant inductive harvester architectures in order to find the magnet coil arrangement that generates the largest power output. The book is useful as a step-by-step guide for readers unfamiliar with this form of energy harvesting, but who want to build their own system models to calculate the magnet motion and, from that, the power generation available for body-worn sensor systems. The detailed description of system model development will greatly facilitate experimental work with the aim of fabricating the design with the highest predicted power output. Based on the simulated optimal geometry, fabricated devices achieve an average power output of up to 43 mW during walking, an amount of power that can supply modern low-power, body-worn systems. Experiments were also carried out in industrial applications with power outputs up to 15 mW. In sum, researchers and engineers will find a step-by-step introduction to inductive harvesting and its modeling aspects for achieving optimal harvester designs in an efficient manner.

ISBN: 9789813344488$q(electronic bk.)

Standard No.: 10.1007/978-981-33-4448-8doiSubjects--Topical Terms:

491439
Energy harvesting.

LC Class. No.: TK2897 / .Y555 2021

Dewey Class. No.: 621.042

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520 $a This book investigates several non-resonant inductive harvester architectures in order to find the magnet coil arrangement that generates the largest power output. The book is useful as a step-by-step guide for readers unfamiliar with this form of energy harvesting, but who want to build their own system models to calculate the magnet motion and, from that, the power generation available for body-worn sensor systems. The detailed description of system model development will greatly facilitate experimental work with the aim of fabricating the design with the highest predicted power output. Based on the simulated optimal geometry, fabricated devices achieve an average power output of up to 43 mW during walking, an amount of power that can supply modern low-power, body-worn systems. Experiments were also carried out in industrial applications with power outputs up to 15 mW. In sum, researchers and engineers will find a step-by-step introduction to inductive harvesting and its modeling aspects for achieving optimal harvester designs in an efficient manner.
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