Freestanding and Scalable Force-Softness Bimodal Sensor Arrays for Haptic Body-Feature Identification

Zequn Cui; Wensong Wang; Huarong Xia; Changxian Wang; Jiaqi Tu; Shaobo Ji; Joel Ming Rui Tan; Zhihua Liu; Feilong Zhang; Wenlong Li; Zhisheng Lv; Zheng Li; Wei Guo; Nien Yue Koh; Kian Bee Ng; Xue Feng; Yuanjin Zheng; Xiaodong Chen

doi:10.1002/adma.202207016

Freestanding and Scalable Force-Softness Bimodal Sensor Arrays for Haptic Body-Feature Identification

Zequn Cui, Wensong Wang, Huarong Xia, Changxian Wang, Jiaqi Tu, Shaobo Ji, Joel Ming Rui Tan, Zhihua Liu, Feilong Zhang, Wenlong Li, Zhisheng Lv, Zheng Li, Wei Guo, Nien Yue Koh, Kian Bee Ng, Xue Feng, Yuanjin Zheng^*, Xiaodong Chen^*

^*Corresponding author for this work

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

37 Citations (Scopus)

Abstract

Tactile technologies that can identify human body features are valuable in clinical diagnosis and human–machine interactions. Previously, cutting-edge tactile platforms have been able to identify structured non-living objects; however, identification of human body features remains challenging mainly because of the irregular contour and heterogeneous spatial distribution of softness. Here, freestanding and scalable tactile platforms of force-softness bimodal sensor arrays are developed, enabling tactile gloves to identify body features using machine-learning methods. The bimodal sensors are engineered by adding a protrusion on a piezoresistive pressure sensor, endowing the resistance signals with combined information of pressure and the softness of samples. The simple design enables 112 bimodal sensors to be integrated into a thin, conformal, and stretchable tactile glove, allowing the tactile information to be digitalized while hand skills are performed on the human body. The tactile glove shows high accuracy (98%) in identifying four body features of a real person, and four organ models (healthy and pathological) inside an abdominal simulator, demonstrating identification of body features of the bimodal tactile platforms and showing their potential use in future healthcare and robotics.

Original language	English
Article number	2207016
Journal	Advanced Materials
Volume	34
Issue number	47
DOIs	https://doi.org/10.1002/adma.202207016
Publication status	Published - Nov 24 2022
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2022 Wiley-VCH GmbH.

ASJC Scopus Subject Areas

General Materials Science
Mechanics of Materials
Mechanical Engineering

Keywords

identification of body features
palpation
pressure sensors
softness sensing
tactile gloves

UN SDGs

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

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10.1002/adma.202207016

Cite this

Cui, Z., Wang, W., Xia, H., Wang, C., Tu, J., Ji, S., Tan, J. M. R., Liu, Z., Zhang, F., Li, W., Lv, Z., Li, Z., Guo, W., Koh, N. Y., Ng, K. B., Feng, X., Zheng, Y., & Chen, X. (2022). Freestanding and Scalable Force-Softness Bimodal Sensor Arrays for Haptic Body-Feature Identification. Advanced Materials, 34(47), Article 2207016. https://doi.org/10.1002/adma.202207016

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abstract = "Tactile technologies that can identify human body features are valuable in clinical diagnosis and human–machine interactions. Previously, cutting-edge tactile platforms have been able to identify structured non-living objects; however, identification of human body features remains challenging mainly because of the irregular contour and heterogeneous spatial distribution of softness. Here, freestanding and scalable tactile platforms of force-softness bimodal sensor arrays are developed, enabling tactile gloves to identify body features using machine-learning methods. The bimodal sensors are engineered by adding a protrusion on a piezoresistive pressure sensor, endowing the resistance signals with combined information of pressure and the softness of samples. The simple design enables 112 bimodal sensors to be integrated into a thin, conformal, and stretchable tactile glove, allowing the tactile information to be digitalized while hand skills are performed on the human body. The tactile glove shows high accuracy (98%) in identifying four body features of a real person, and four organ models (healthy and pathological) inside an abdominal simulator, demonstrating identification of body features of the bimodal tactile platforms and showing their potential use in future healthcare and robotics.",

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author = "Zequn Cui and Wensong Wang and Huarong Xia and Changxian Wang and Jiaqi Tu and Shaobo Ji and Tan, {Joel Ming Rui} and Zhihua Liu and Feilong Zhang and Wenlong Li and Zhisheng Lv and Zheng Li and Wei Guo and Koh, {Nien Yue} and Ng, {Kian Bee} and Xue Feng and Yuanjin Zheng and Xiaodong Chen",

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doi = "10.1002/adma.202207016",

language = "English",

volume = "34",

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AU - Tu, Jiaqi

AU - Ji, Shaobo

AU - Tan, Joel Ming Rui

AU - Liu, Zhihua

AU - Zhang, Feilong

AU - Li, Wenlong

AU - Lv, Zhisheng

AU - Li, Zheng

AU - Guo, Wei

AU - Koh, Nien Yue

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AU - Feng, Xue

AU - Zheng, Yuanjin

AU - Chen, Xiaodong

PY - 2022/11/24

Y1 - 2022/11/24

N2 - Tactile technologies that can identify human body features are valuable in clinical diagnosis and human–machine interactions. Previously, cutting-edge tactile platforms have been able to identify structured non-living objects; however, identification of human body features remains challenging mainly because of the irregular contour and heterogeneous spatial distribution of softness. Here, freestanding and scalable tactile platforms of force-softness bimodal sensor arrays are developed, enabling tactile gloves to identify body features using machine-learning methods. The bimodal sensors are engineered by adding a protrusion on a piezoresistive pressure sensor, endowing the resistance signals with combined information of pressure and the softness of samples. The simple design enables 112 bimodal sensors to be integrated into a thin, conformal, and stretchable tactile glove, allowing the tactile information to be digitalized while hand skills are performed on the human body. The tactile glove shows high accuracy (98%) in identifying four body features of a real person, and four organ models (healthy and pathological) inside an abdominal simulator, demonstrating identification of body features of the bimodal tactile platforms and showing their potential use in future healthcare and robotics.

AB - Tactile technologies that can identify human body features are valuable in clinical diagnosis and human–machine interactions. Previously, cutting-edge tactile platforms have been able to identify structured non-living objects; however, identification of human body features remains challenging mainly because of the irregular contour and heterogeneous spatial distribution of softness. Here, freestanding and scalable tactile platforms of force-softness bimodal sensor arrays are developed, enabling tactile gloves to identify body features using machine-learning methods. The bimodal sensors are engineered by adding a protrusion on a piezoresistive pressure sensor, endowing the resistance signals with combined information of pressure and the softness of samples. The simple design enables 112 bimodal sensors to be integrated into a thin, conformal, and stretchable tactile glove, allowing the tactile information to be digitalized while hand skills are performed on the human body. The tactile glove shows high accuracy (98%) in identifying four body features of a real person, and four organ models (healthy and pathological) inside an abdominal simulator, demonstrating identification of body features of the bimodal tactile platforms and showing their potential use in future healthcare and robotics.

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KW - pressure sensors

KW - softness sensing

KW - tactile gloves

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Freestanding and Scalable Force-Softness Bimodal Sensor Arrays for Haptic Body-Feature Identification

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

UN SDGs

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