Self‐Adaptive Perception of Object's Deformability with Multiple Deformation Attributes Utilizing Biomimetic Mechanoreceptors

The perception of object's deformability in unstructured interactions relies on both kinesthetic and cutaneous cues to adapt the uncertainties of an object. However, the existing tactile sensors cannot provide adequate cutaneous cues to self‐adaptively estimate the material softness, especially...

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Bibliographic Details
Published in:Advanced materials (Weinheim) 2024-03, Vol.36 (9), p.e2305032-n/a
Main Authors: Lin, Waner, Wang, Ziya, Xu, Yingtian, Hu, Zhixian, Zhao, Wenyu, Zhu, Zhihao, Sun, Zhenglong, Wang, Guoxing, Peng, Zhengchun
Format: Article
Language:English
Subjects:
Biomimetic materials
biomimetic mechanoreceptors
compliance
Contact pressure
Deformation
Formability
material softness
Mechanoreceptors
Modulus of elasticity
multiple deformation attributes
Perception
self‐adaptive
Sensors
Softness
Tactile sensors (robotics)
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Summary:The perception of object's deformability in unstructured interactions relies on both kinesthetic and cutaneous cues to adapt the uncertainties of an object. However, the existing tactile sensors cannot provide adequate cutaneous cues to self‐adaptively estimate the material softness, especially in non‐standard contact scenarios where the interacting object deviates from the assumption of an elastic half‐infinite body. This paper proposes an innovative design of a tactile sensor that integrates the capabilities of two slow‐adapting mechanoreceptors within a soft medium, allowing self‐decoupled sensing of local pressure and strain at specific locations within the contact interface. By leveraging these localized cutaneous cues, the sensor can accurately and self‐adaptively measure the material softness of an object, accommodating variations in thicknesses and applied forces. Furthermore, when combined with a kinesthetic cue from the robot, the sensor can enhance tactile expression by the synergy of two relevant deformation attributes, including material softness and compliance. It is demonstrated that the biomimetic fusion of tactile information can fully comprehend the deformability of an object, hence facilitating robotic decision‐making and dexterous manipulation. A novel tactile sensor, which integrates biomimetic slow‐adapting mechanoreceptors in a soft medium, enables self‐decoupled sensing of local pressure and strain at the contact surface. In robotic manipulation, the sensor can achieve the self‐adaptive perception of material softness and enhance tactile perception by establishing two relevant deformation attributes (material softness and compliance) for an object.
ISSN:0935-9648
1521-4095
DOI:10.1002/adma.202305032