Ultra-high resolution, multi-scenario, super-elastic inductive strain sensors based on liquid metal for the wireless monitoring of human movement
Flexible strain sensors are an essential component of electronic skin as they are capable of sensing various physiological signals from the human body. They can be used to monitor human health and performance during exercise. However, most currently available strain sensors cannot simultaneously det...
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sg-ntu-dr.10356-1817192024-12-20T15:49:18Z Ultra-high resolution, multi-scenario, super-elastic inductive strain sensors based on liquid metal for the wireless monitoring of human movement Mao, Jian He, Zidong Wu, Yuanzhao Cao, Jinwei Zhao, Shijing Chen, Bin Shang, Jie Liu, Yiwei Li, Run-Wei School of Materials Science and Engineering Innovative Center for Flexible Devices Max Planck-NTU Joint Lab for Artificial Senses Engineering Electronic skin Human movements Flexible strain sensors are an essential component of electronic skin as they are capable of sensing various physiological signals from the human body. They can be used to monitor human health and performance during exercise. However, most currently available strain sensors cannot simultaneously detect both small and large strains on the human skin during movement. In this study, we propose a planar, inductive strain sensor based on liquid metal putty with exceptional elasticity. This sensor can detect both large and small strains: it can measure strains of up to 300% and detect those as low as 0.05% while exhibiting excellent stability (more than 5000 stretch-release cycles) and consistency in terms of variations in inductance (a maximum change of only 1.2%). It also performs well under bending and folding conditions. We also investigated methods to enhance the sensitivity of the sensor under stretching conditions, and used the results to develop a system to monitor signals of human movement based on techniques of wireless transmission and signal processing. This system can capture changes in the magnitude of strain on the skin during human movement, and can be used to monitor various human activities, including respiratory signals, swallowing, and the movements of the joints. Due to these features, the proposed system offers significant potential for use in applications of health and motion monitoring. Published version This research was partially supported by National Key R & D Program China (2023YFC3603500), National Natural Science Foundation of China (52127803, 51931011, 62174165, U22A2075, 52301256, U20A6001, M-0152, U22A20248, 52201236, 62204246, 52105286), Chinese Academy of Sciences Youth Innovation Promotion Association (2018334), Pioneer and Leading Goose R & D Program of Zhejiang (2022C01032), ‘‘High-level Talent Special Support Plan’’ Technology Innovation Leading Talent Project of Zhejiang Province (2022R52004), Natural Science Foundation of Zhejiang Province (LD22E010002), Ningbo Natural Science Foundations (20221JCGY010312, 2022J288 ), Ningbo Key Research and Development Program (2023Z097). 2024-12-16T02:24:07Z 2024-12-16T02:24:07Z 2024 Journal Article Mao, J., He, Z., Wu, Y., Cao, J., Zhao, S., Chen, B., Shang, J., Liu, Y. & Li, R. (2024). Ultra-high resolution, multi-scenario, super-elastic inductive strain sensors based on liquid metal for the wireless monitoring of human movement. Materials Advances, 5(14), 5813-5822. https://dx.doi.org/10.1039/d4ma00140k 2633-5409 https://hdl.handle.net/10356/181719 10.1039/d4ma00140k 2-s2.0-85198901513 14 5 5813 5822 en Materials Advances © 2024 The Authors. Published by the Royal Society of Chemistry. This article is licensed under a Creative Commons Attribution-NonCommercial 3.0 Unported Licence. application/pdf |
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Engineering Electronic skin Human movements |
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Engineering Electronic skin Human movements Mao, Jian He, Zidong Wu, Yuanzhao Cao, Jinwei Zhao, Shijing Chen, Bin Shang, Jie Liu, Yiwei Li, Run-Wei Ultra-high resolution, multi-scenario, super-elastic inductive strain sensors based on liquid metal for the wireless monitoring of human movement |
| description |
Flexible strain sensors are an essential component of electronic skin as they are capable of sensing various physiological signals from the human body. They can be used to monitor human health and performance during exercise. However, most currently available strain sensors cannot simultaneously detect both small and large strains on the human skin during movement. In this study, we propose a planar, inductive strain sensor based on liquid metal putty with exceptional elasticity. This sensor can detect both large and small strains: it can measure strains of up to 300% and detect those as low as 0.05% while exhibiting excellent stability (more than 5000 stretch-release cycles) and consistency in terms of variations in inductance (a maximum change of only 1.2%). It also performs well under bending and folding conditions. We also investigated methods to enhance the sensitivity of the sensor under stretching conditions, and used the results to develop a system to monitor signals of human movement based on techniques of wireless transmission and signal processing. This system can capture changes in the magnitude of strain on the skin during human movement, and can be used to monitor various human activities, including respiratory signals, swallowing, and the movements of the joints. Due to these features, the proposed system offers significant potential for use in applications of health and motion monitoring. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Mao, Jian He, Zidong Wu, Yuanzhao Cao, Jinwei Zhao, Shijing Chen, Bin Shang, Jie Liu, Yiwei Li, Run-Wei |
| format |
Article |
| author |
Mao, Jian He, Zidong Wu, Yuanzhao Cao, Jinwei Zhao, Shijing Chen, Bin Shang, Jie Liu, Yiwei Li, Run-Wei |
| author_sort |
Mao, Jian |
| title |
Ultra-high resolution, multi-scenario, super-elastic inductive strain sensors based on liquid metal for the wireless monitoring of human movement |
| title_short |
Ultra-high resolution, multi-scenario, super-elastic inductive strain sensors based on liquid metal for the wireless monitoring of human movement |
| title_full |
Ultra-high resolution, multi-scenario, super-elastic inductive strain sensors based on liquid metal for the wireless monitoring of human movement |
| title_fullStr |
Ultra-high resolution, multi-scenario, super-elastic inductive strain sensors based on liquid metal for the wireless monitoring of human movement |
| title_full_unstemmed |
Ultra-high resolution, multi-scenario, super-elastic inductive strain sensors based on liquid metal for the wireless monitoring of human movement |
| title_sort |
ultra-high resolution, multi-scenario, super-elastic inductive strain sensors based on liquid metal for the wireless monitoring of human movement |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/181719 |
| _version_ |
1820027753599074304 |