纳米网
材料科学
可穿戴计算机
计算机科学
手势识别
联轴节(管道)
人工智能
纳米技术
传输(电信)
卷积神经网络
工作(物理)
极限抗拉强度
门
手势
声学
人体运动
导电体
可穿戴技术
无线传感器网络
微电子机械系统
执行机构
软机器人
压力(语言学)
人工神经网络
肌电图
隐马尔可夫模型
人机系统
光电子学
机器人
纳米器件
水准点(测量)
作者
Haitao Deng,Ziquan Cao,Jianmin Yang,Maosong Yin,Chuanghui Yu,Dianyu Wang,Jinghua Yu,Guoliang Liu,Weihua Gao,Xianhe Yu,Jiantao Yao,Ye Tian
摘要
ABSTRACT Engineering soft conductors that simultaneously offer high strength, extreme stretchability, and environmental stability remains a central challenge for next‐generation wearable electronics. Here, we incorporate an electrospun polyurethane (PU) nanomesh rich in hydrogen bonding sites into a eutectogel matrix. Benefiting from designable interfacial interactions, the thin hybrid gel (≈45 µm) exhibits high tensile strength (12.6 MPa), remarkable stretchability (1376%) and fatigue resistance. Based on its good sensitivity, the hybrid gel can serve as a strain sensor for wide range human motion monitoring, as well as a multifunctional sensor for humidity and temperature detection. Moreover, its high water vapor transmission rate (1176 g·m −2 ·d −1 ) and robust anti‐freezing and anti‐drying properties enable reliable recording of physiological signals such as electromyography (EMG) and electrocardiography (ECG). By coupling the EMG output with a convolutional neural network (CNN), the system attains a high gesture recognition accuracy of 98.7%. This work demonstrates great potential for next‐generation wearable healthcare and human‐machine interfaces.
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