材料科学
灵活性(工程)
灵敏度(控制系统)
噪音(视频)
声学
机器人
声传感器
光电子学
纳米技术
人工智能
电子工程
计算机科学
工程类
物理
图像(数学)
统计
数学
作者
Liuyang Han,Wenjie Zhang,Chenlei Fan,Ziyao Qi,Yuhan Liu,Yu Wang,Yanfei Zhao,Biao Zhang,Xiao Chen,Ying Dong,Xiaohao Wang
标识
DOI:10.1002/adfm.202512101
摘要
Abstract Acoustic detection and recognition are crucial for information exchange in diverse fields, yet traditional acoustic sensors face limitations in bulk, sensitivity, and flexibility. The existing flexible acoustic sensors still struggle with performance degradation under bending. Therefore, this study introduces a piezoelectret thin‐film acoustic sensor (PETAS) that includes a vibrating membrane, a spacer layer, and an electret layer made of fluorinated ethylene propylene (FEP). The air gaps within the electret layer are fully charged after corona poling, and charge redistribution occurs when the device undergoes deformation. By decoupling the diaphragm and the electret layer, the diaphragm can specifically respond to acoustic pressure variations and affect charge distribution so that bandwidth and sensitivity are significantly enhanced while flexibility is maintained. The fabricated sensor demonstrates a stable output across 0∼830 Hz frequency range, high sensitivity (2.744 pC/Pa at 500 Hz), and excellent durability (>10 5 continuous operational and 1,000 bending cycles without performance loss). The exceptional performance ensures an over 96% accuracy in the command recognition and strong ability of environmental noise rejection in the human‐robot interaction. As demonstrated in experiments, neck‐mounted PETAS significantly outperformed commercial microphones. These demonstrations illustrate that PETAS offers a versatile solution for next‐generation wearable electronics and HRI systems.
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