Recent Developments and Applications of Tactile Sensors with Biomimetic Microstructures.

IF 3.4 3区医学 Q1 ENGINEERING, MULTIDISCIPLINARY

Biomimetics Pub Date : 2025-02-27 DOI:10.3390/biomimetics10030147

Fengchang Huang, Xidi Sun, Qiaosheng Xu, Wen Cheng, Yi Shi, Lijia Pan

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Abstract

Humans possess an innate ability to perceive a wide range of objects through touch, which allows them to interact effectively with their surroundings. Similarly, tactile perception in artificial sensory systems enables the acquisition of object properties, human physiological signals, and environmental information. Biomimetic tactile sensors, as an emerging sensing technology, draw inspiration from biological systems and exhibit high sensitivity, rapid response, multimodal perception, and stability. By mimicking biological mechanisms and microstructures, these sensors achieve precise detection of mechanical signals, thereby paving the way for advancements in tactile sensing applications. This review provides an overview of key sensing mechanisms, microstructure designs, and advanced fabrication techniques of biomimetic tactile sensors. The system architecture design of biomimetic tactile sensing systems is also explored. Furthermore, the review highlights significant applications of these sensors in recent years, including texture recognition, human health detection, and human-machine interaction. Finally, the key challenges and future development prospects related to biomimetic tactile sensors are discussed.

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人类与生俱来就能通过触觉感知各种物体，从而与周围环境进行有效互动。同样，人工感觉系统中的触觉感知也能获取物体属性、人体生理信号和环境信息。仿生触觉传感器作为一种新兴的传感技术，从生物系统中汲取灵感，具有高灵敏度、快速反应、多模态感知和稳定性等特点。通过模仿生物机制和微结构，这些传感器实现了对机械信号的精确检测，从而为触觉传感应用的发展铺平了道路。本综述概述了生物仿生触觉传感器的关键传感机制、微结构设计和先进制造技术。此外，还探讨了仿生物触觉传感系统的系统架构设计。此外，综述还重点介绍了近年来这些传感器的重要应用，包括纹理识别、人体健康检测和人机交互。最后，讨论了与仿生物触觉传感器相关的主要挑战和未来发展前景。

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