Prosthetic finger for fingertip tactile sensing via flexible chromatic optical waveguides

Building prosthetics indistinguishable from human limbs to accurately receive and transmit sensory information to users not only promises to radically improve the lives of amputees, but also shows potential in a range of robotic applications. Currently, a mainstream approach is to embed electrical o...

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Published in:Materials horizons 2023-10, Vol.10 (11), p.4940-4951
Main Authors: Zhou, Jian, Fu, Chunqiao, Fang, Jiahao, Shang, Kedong, Pu, Xiaobo, Zhang, Yong, Jiang, Zhongbao, Lu, Xulei, He, Changliu, Jia, Lingxu, Yao, Yuming, Qian, Linmao, Yang, Tingting
Format: Article
Language:English
Subjects:
Braille
Fingers
Force distribution
Hardness
Optical measuring instruments
Optical waveguides
Perception
Prostheses
Robotics
Sensors
Tactile sensors (robotics)
Three dimensional printing
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cited_by cdi_FETCH-LOGICAL-c292t-e58612833f8a0476005769b0d02005f33864af44bf7f60673bd606d022324f9f3
cites cdi_FETCH-LOGICAL-c292t-e58612833f8a0476005769b0d02005f33864af44bf7f60673bd606d022324f9f3
container_end_page 4951
container_issue 11
container_start_page 4940
container_title Materials horizons
container_volume 10
creator Zhou, Jian
Fu, Chunqiao
Fang, Jiahao
Shang, Kedong
Pu, Xiaobo
Zhang, Yong
Jiang, Zhongbao
Lu, Xulei
He, Changliu
Jia, Lingxu
Yao, Yuming
Qian, Linmao
Yang, Tingting
description Building prosthetics indistinguishable from human limbs to accurately receive and transmit sensory information to users not only promises to radically improve the lives of amputees, but also shows potential in a range of robotic applications. Currently, a mainstream approach is to embed electrical or optical sensors with force/thermal sensing functions on the surface or inside of prosthetic fingers. Compared with electrical sensing technologies, tactile sensors based on stretchable optical waveguides have the advantages of easy fabrication, chemical safety, environmental stability, and compatibility with prosthetic structural materials. However, so far, research has mainly focused on the perception of finger joint motion or external press, and there is still a lack of study on optical sensors with fingertip tactile capabilities (such as texture, hardness, slip detection, etc.). Here we report a 3D printing prosthetic finger with flexible chromatic optical waveguides implanted at the fingertip. The finger achieves distributed displacement/force sensing detection, and exhibits high sensitivity, fast response and good stability. The finger can be used to conduct active sensory experiments, and the detection parameters include object contour, hardness, slip direction and speed, temperature, etc. Finally, exploratory research on identifying and manipulating objects is carried out with this finger. The developed prosthetic finger can artificially recreate touch perception and realize complex functions such as note-writing analysis and braille recognition.
doi_str_mv 10.1039/d3mh00921a
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source Royal Society of Chemistry:Jisc Collections:Royal Society of Chemistry Read and Publish 2022-2024 (reading list)
subjects Braille
Fingers
Force distribution
Hardness
Optical measuring instruments
Optical waveguides
Perception
Prostheses
Robotics
Sensors
Tactile sensors (robotics)
Three dimensional printing
title Prosthetic finger for fingertip tactile sensing via flexible chromatic optical waveguides
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