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

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

Open Access

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

Author(s) -

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

Publication year - 2021

Publication title -

science advances

Language(s) - Uncategorized

Resource type - Journals

SCImago Journal Rank - 5.928

H-Index - 146

ISSN - 2375-2548

DOI - 10.1126/sciadv.abi6751

Subject(s) - wireless , wearable computer , computer science , transmission (telecommunications) , electronics , wearable technology , interface (matter) , wireless transmission , wireless network , robotics , wi fi array , internet of things , electrical engineering , telecommunications , embedded system , robot , artificial intelligence , engineering , bubble , maximum bubble pressure method , parallel computing

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