A paradigm shift fully self-powered long-distance wireless sensing solution enabled by discharge-induced displacement current

Haoyu Wang; Jiaqi Wang; Kuanming Yao; Jingjing Fu; Xin Xia; Ruirui Zhang; Jiyu Li; Guoqiang Xu; Lingyun Wang; Jingchao Yang; Jie Lai; Yuan Dai; Zhengyou Zhang; Anyin Li; Yuyan Zhu; Xinge Yu; Zhong Lin Wang; Yunlong Zi

doi:10.1126/sciadv.abi6751

A paradigm shift fully self-powered long-distance wireless sensing solution enabled by discharge-induced displacement current

Haoyu Wang (Co-first Author), Jiaqi Wang (Co-first Author), Kuanming Yao, Jingjing Fu, Xin Xia, Ruirui Zhang, Jiyu Li, Guoqiang Xu, Lingyun Wang, Jingchao Yang, Jie Lai, Yuan Dai^*, Zhengyou Zhang, Anyin Li, Yuyan Zhu, Xinge Yu, Zhong Lin Wang^*, Yunlong Zi^*

^*Corresponding author for this work

Department of Biomedical Engineering

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

94 Citations (Scopus)

99 Downloads (CityUHK Scholars)

Abstract

The rapid development of the Internet of Things depends on wireless devices and their network. Traditional wireless sensing and transmission technology still requires multiple modules for sensing, signal modulation, transmission, and power, making the whole system bulky, rigid, and costly. Here, we proposed a paradigm shift wireless sensing solution based on the breakdown discharge–induced displacement current. Through that, we can combine the abovementioned functional modules in a single unit of self-powered wireless sensing e-sticker (SWISE), which features a small size (down to 9 mm by 9 mm) and long effective transmission distance (>30 m) when compared to existing wireless sensing technologies. Furthermore, SWISEs have functions of multipoint motion sensing and gas detection in fully self-powered manner. This work proposes a solution for flexible self-powered wireless sensing platforms, which shows great potential for implantable and wearable electronics, robotics, health care, infrastructure monitoring, human-machine interface, virtual reality, etc.

Original language	English
Article number	eabi6751
Journal	Science Advances
Volume	7
Issue number	39
Online published	22 Sept 2021
DOIs	https://doi.org/10.1126/sciadv.abi6751
Publication status	Published - 24 Sept 2021

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This full text is made available under CC-BY 4.0. https://creativecommons.org/licenses/by/4.0/

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Wang, H., Wang, J., Yao, K., Fu, J., Xia, X., Zhang, R., Li, J., Xu, G., Wang, L., Yang, J., Lai, J., Dai, Y., Zhang, Z., Li, A., Zhu, Y., Yu, X., Wang, Z. L., & Zi, Y. (2021). A paradigm shift fully self-powered long-distance wireless sensing solution enabled by discharge-induced displacement current. Science Advances, 7(39), Article eabi6751. https://doi.org/10.1126/sciadv.abi6751

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abstract = "The rapid development of the Internet of Things depends on wireless devices and their network. Traditional wireless sensing and transmission technology still requires multiple modules for sensing, signal modulation, transmission, and power, making the whole system bulky, rigid, and costly. Here, we proposed a paradigm shift wireless sensing solution based on the breakdown discharge–induced displacement current. Through that, we can combine the abovementioned functional modules in a single unit of self-powered wireless sensing e-sticker (SWISE), which features a small size (down to 9 mm by 9 mm) and long effective transmission distance (>30 m) when compared to existing wireless sensing technologies. Furthermore, SWISEs have functions of multipoint motion sensing and gas detection in fully self-powered manner. This work proposes a solution for flexible self-powered wireless sensing platforms, which shows great potential for implantable and wearable electronics, robotics, health care, infrastructure monitoring, human-machine interface, virtual reality, etc.",

author = "Haoyu Wang and Jiaqi Wang and Kuanming Yao and Jingjing Fu and Xin Xia and Ruirui Zhang and Jiyu Li and Guoqiang Xu and Lingyun Wang and Jingchao Yang and Jie Lai and Yuan Dai and Zhengyou Zhang and Anyin Li and Yuyan Zhu and Xinge Yu and Wang, {Zhong Lin} and Yunlong Zi",

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language = "English",

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A paradigm shift fully self-powered long-distance wireless sensing solution enabled by discharge-induced displacement current. / Wang, Haoyu (Co-first Author); Wang, Jiaqi (Co-first Author); Yao, Kuanming et al.
In: Science Advances, Vol. 7, No. 39, eabi6751, 24.09.2021.

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

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AU - Wang, Haoyu

AU - Wang, Jiaqi

AU - Yao, Kuanming

AU - Fu, Jingjing

AU - Xia, Xin

AU - Zhang, Ruirui

AU - Li, Jiyu

AU - Xu, Guoqiang

AU - Wang, Lingyun

AU - Yang, Jingchao

AU - Lai, Jie

AU - Dai, Yuan

AU - Zhang, Zhengyou

AU - Li, Anyin

AU - Zhu, Yuyan

AU - Yu, Xinge

AU - Wang, Zhong Lin

AU - Zi, Yunlong

PY - 2021/9/24

Y1 - 2021/9/24

N2 - The rapid development of the Internet of Things depends on wireless devices and their network. Traditional wireless sensing and transmission technology still requires multiple modules for sensing, signal modulation, transmission, and power, making the whole system bulky, rigid, and costly. Here, we proposed a paradigm shift wireless sensing solution based on the breakdown discharge–induced displacement current. Through that, we can combine the abovementioned functional modules in a single unit of self-powered wireless sensing e-sticker (SWISE), which features a small size (down to 9 mm by 9 mm) and long effective transmission distance (>30 m) when compared to existing wireless sensing technologies. Furthermore, SWISEs have functions of multipoint motion sensing and gas detection in fully self-powered manner. This work proposes a solution for flexible self-powered wireless sensing platforms, which shows great potential for implantable and wearable electronics, robotics, health care, infrastructure monitoring, human-machine interface, virtual reality, etc.

AB - The rapid development of the Internet of Things depends on wireless devices and their network. Traditional wireless sensing and transmission technology still requires multiple modules for sensing, signal modulation, transmission, and power, making the whole system bulky, rigid, and costly. Here, we proposed a paradigm shift wireless sensing solution based on the breakdown discharge–induced displacement current. Through that, we can combine the abovementioned functional modules in a single unit of self-powered wireless sensing e-sticker (SWISE), which features a small size (down to 9 mm by 9 mm) and long effective transmission distance (>30 m) when compared to existing wireless sensing technologies. Furthermore, SWISEs have functions of multipoint motion sensing and gas detection in fully self-powered manner. This work proposes a solution for flexible self-powered wireless sensing platforms, which shows great potential for implantable and wearable electronics, robotics, health care, infrastructure monitoring, human-machine interface, virtual reality, etc.

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A paradigm shift fully self-powered long-distance wireless sensing solution enabled by discharge-induced displacement current

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ECS: Skin-Integrated Sensing and Haptic Feedback Electronics for Health Monitoring and Sudden Illnesses Early Warning

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A paradigm shift fully self-powered long-distance wireless sensing solution enabled by discharge-induced displacement current

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Publisher's Copyright Statement

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ECS: Skin-Integrated Sensing and Haptic Feedback Electronics for Health Monitoring and Sudden Illnesses Early Warning

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