Optical Micro/Nanofiber Enabled Multiaxial Force Sensor for Tactile Visualization and Human–Machine Interface

Yu Xie; Jing Pan; Longteng Yu; Hubiao Fang; Shaoliang Yu; Ning Zhou; Limin Tong; Lei Zhang

doi:10.1002/advs.202404343

Optical Micro/Nanofiber Enabled Multiaxial Force Sensor for Tactile Visualization and Human–Machine Interface

Yu Xie
, Jing Pan^*
, Longteng Yu
, Hubiao Fang
, Shaoliang Yu
, Ning Zhou
, Limin Tong
, Lei Zhang^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Tactile sensors with capability of multiaxial force perception play a vital role in robotics and human–machine interfaces. Flexible optical waveguide sensors have been an emerging paradigm in tactile sensing due to their high sensitivity, fast response, and antielectromagnetic interference. Herein, a flexible multiaxial force sensor enabled by U-shaped optical micro/nanofibers (MNFs) is reported. The MNF is embedded within an elastomer film topped with a dome-shaped protrusion. When the protrusion is subjected to vector forces, the embedded MNF undergoes anisotropic deformations, yielding time-resolved variations in light transmission. Detection of both normal and shear forces is achieved with sensitivities reaching 50.7 dB N⁻¹ (14% kPa⁻¹) and 82.2 dB N⁻¹ (21% kPa⁻¹), respectively. Notably, the structural asymmetry of the MNF induces asymmetrical optical modes, granting the sensor directional responses to four-directional shear forces. As proof-of-concept applications, tactile visualizations for texture and relief pattern recognition are realized with a spatial resolution of 160 µm. Moreover, a dual U-shaped MNF configuration is demonstrated as a human–machine interface for cursor manipulation. This work represents a step towards advanced multiaxial tactile sensing.

Original language	English
Article number	2404343
Journal	Advanced Science
Volume	11
Issue number	45
DOIs	https://doi.org/10.1002/advs.202404343
State	Published - 4 Dec 2024
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

directional response
human–machine interface
micro/nanofiber (MNF)
multiaxial force
optical sensor
tactile visualization

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10.1002/advs.202404343

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title = "Optical Micro/Nanofiber Enabled Multiaxial Force Sensor for Tactile Visualization and Human–Machine Interface",

abstract = "Tactile sensors with capability of multiaxial force perception play a vital role in robotics and human–machine interfaces. Flexible optical waveguide sensors have been an emerging paradigm in tactile sensing due to their high sensitivity, fast response, and antielectromagnetic interference. Herein, a flexible multiaxial force sensor enabled by U-shaped optical micro/nanofibers (MNFs) is reported. The MNF is embedded within an elastomer film topped with a dome-shaped protrusion. When the protrusion is subjected to vector forces, the embedded MNF undergoes anisotropic deformations, yielding time-resolved variations in light transmission. Detection of both normal and shear forces is achieved with sensitivities reaching 50.7 dB N−1 (14\% kPa−1) and 82.2 dB N−1 (21\% kPa−1), respectively. Notably, the structural asymmetry of the MNF induces asymmetrical optical modes, granting the sensor directional responses to four-directional shear forces. As proof-of-concept applications, tactile visualizations for texture and relief pattern recognition are realized with a spatial resolution of 160 µm. Moreover, a dual U-shaped MNF configuration is demonstrated as a human–machine interface for cursor manipulation. This work represents a step towards advanced multiaxial tactile sensing.",

keywords = "directional response, human–machine interface, micro/nanofiber (MNF), multiaxial force, optical sensor, tactile visualization",

author = "Yu Xie and Jing Pan and Longteng Yu and Hubiao Fang and Shaoliang Yu and Ning Zhou and Limin Tong and Lei Zhang",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s). Advanced Science published by Wiley-VCH GmbH.",

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T1 - Optical Micro/Nanofiber Enabled Multiaxial Force Sensor for Tactile Visualization and Human–Machine Interface

AU - Xie, Yu

AU - Pan, Jing

AU - Yu, Longteng

AU - Fang, Hubiao

AU - Yu, Shaoliang

AU - Zhou, Ning

AU - Tong, Limin

AU - Zhang, Lei

PY - 2024/12/4

Y1 - 2024/12/4

N2 - Tactile sensors with capability of multiaxial force perception play a vital role in robotics and human–machine interfaces. Flexible optical waveguide sensors have been an emerging paradigm in tactile sensing due to their high sensitivity, fast response, and antielectromagnetic interference. Herein, a flexible multiaxial force sensor enabled by U-shaped optical micro/nanofibers (MNFs) is reported. The MNF is embedded within an elastomer film topped with a dome-shaped protrusion. When the protrusion is subjected to vector forces, the embedded MNF undergoes anisotropic deformations, yielding time-resolved variations in light transmission. Detection of both normal and shear forces is achieved with sensitivities reaching 50.7 dB N−1 (14% kPa−1) and 82.2 dB N−1 (21% kPa−1), respectively. Notably, the structural asymmetry of the MNF induces asymmetrical optical modes, granting the sensor directional responses to four-directional shear forces. As proof-of-concept applications, tactile visualizations for texture and relief pattern recognition are realized with a spatial resolution of 160 µm. Moreover, a dual U-shaped MNF configuration is demonstrated as a human–machine interface for cursor manipulation. This work represents a step towards advanced multiaxial tactile sensing.

AB - Tactile sensors with capability of multiaxial force perception play a vital role in robotics and human–machine interfaces. Flexible optical waveguide sensors have been an emerging paradigm in tactile sensing due to their high sensitivity, fast response, and antielectromagnetic interference. Herein, a flexible multiaxial force sensor enabled by U-shaped optical micro/nanofibers (MNFs) is reported. The MNF is embedded within an elastomer film topped with a dome-shaped protrusion. When the protrusion is subjected to vector forces, the embedded MNF undergoes anisotropic deformations, yielding time-resolved variations in light transmission. Detection of both normal and shear forces is achieved with sensitivities reaching 50.7 dB N−1 (14% kPa−1) and 82.2 dB N−1 (21% kPa−1), respectively. Notably, the structural asymmetry of the MNF induces asymmetrical optical modes, granting the sensor directional responses to four-directional shear forces. As proof-of-concept applications, tactile visualizations for texture and relief pattern recognition are realized with a spatial resolution of 160 µm. Moreover, a dual U-shaped MNF configuration is demonstrated as a human–machine interface for cursor manipulation. This work represents a step towards advanced multiaxial tactile sensing.

KW - directional response

KW - human–machine interface

KW - micro/nanofiber (MNF)

KW - multiaxial force

KW - optical sensor

KW - tactile visualization

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ER -

Optical Micro/Nanofiber Enabled Multiaxial Force Sensor for Tactile Visualization and Human–Machine Interface

Abstract

UN SDGs

Keywords

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