材料科学
非线性系统
聚二甲基硅氧烷
共形映射
压电
声学
电介质
极化(电化学)
横截面
工作(物理)
计算机科学
适应度函数
联轴节(管道)
机械工程
人体运动
格子(音乐)
结构健康监测
测距
微观结构
超材料
触觉传感器
纳米技术
3d打印
光电子学
接口(物质)
智能材料
电子工程
仿生学
压电传感器
外骨骼
作者
Yifan Kong,Hongyun Zhao,Zhuangzhuang He,Danjie Zhu,Wen Yao,Weiqiu Chen,Chunli Zhang
标识
DOI:10.1002/adfm.202529747
摘要
ABSTRACT Flexoelectricity, a universal electromechanical coupling effect in all dielectric materials, offers a broader range of material selection for fabricating smart and functional devices. Inspired by the serpentine structures found in muscle fibers, this work proposes a metamaterial‐inspired flexoelectric sports monitoring (MFSM) sensor based on polydimethylsiloxane (PDMS), by integrating the concept of microstructural design from metamaterials into sensor engineering. The flexoelectric polarization response can be modulated by both the structural characters of the initial serpentine microstructure and the application of hierarchical lattice design strategies. Experiments demonstrate that, under specific geometric and loading conditions, the proposed MFSM sensor achieves a 44.5‐fold enhancement in the effective transverse piezoelectric coefficient at the macroscopic device level compared to AlN. Furthermore, the structural design can be tailored to match the nonlinear J‐shaped stress‐strain curves of different skin regions, enabling a conformal fit. Finally, by integrating a Wi‐Fi module for real‐time signal monitoring and utilizing deep learning for motion posture identification, the proposed MFSM sensor achieves 100% classification accuracy across seven human motion categories in a single‐subject proof‐of‐concept study. Subject to further validation across broader demographics, this work is anticipated to offer novel solutions for postoperative rehabilitation and athletic posture correction.
科研通智能强力驱动
Strongly Powered by AbleSci AI