Modeling Contact Stiffness of Soft Fingertips for Grasping Applications

Ma, Xiaolong; Chen, Lingfeng; Gao, Yanfeng; Liu, Daliang; Wang, Binrui

doi:10.3390/biomimetics8050398

Biomimetics

2023

DOI: 10.3390/biomimetics8050398

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Modeling Contact Stiffness of Soft Fingertips for Grasping Applications

Xiaolong Ma,

Lingfeng Chen,

Yanfeng Gao

et al.

Abstract: Soft fingertips have distinct intrinsic features that allow robotic hands to offer adjustable and manageable stiffness for grasping. The stability of the grasp is determined by the contact stiffness between the soft fingertip and the object. Within this work, we proposed a line vector representation method based on the Winkler Model and investigated the contact stiffness between soft fingertips and objects to achieve control over the gripping force and fingertip displacement of the gripper without the need for… Show more

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2024

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Cited by 2 publications

References 37 publications

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Force and pose control of a hemispherical ultrasonic probe in contact with viscoelastic gelatine

Facundo-Flores,

Baltazar,

Treesatayapun

2024

Meccanica

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Ultrasound probes are widely employed for internal sonification, to detect anomalies and assess mechanical properties. Achieving precise contact and orientation control is crucial for optimizing the transmission of acoustic energy into the test material. This study investigates the contact control of a hemispherical probe against a viscoelastic gelatin (tissue-like) test object. For small applied loads, the signals from the force sensor are often contaminated with noise. To enhance contact measurements, an ultrasound hemispherical probe was designed for Hertzian contact with gelatin. The transmitted/reflected acoustic energy is known to be a function of the contact area, which can be related to the applied force. The transmitted and reflected acoustic energy, which depends on the contact area, is related to the applied force. The goal is to develop an adaptive, model-free algorithm to control the contact force and orientation of the probe to maximize energy transfer. This algorithm integrates reflected acoustic energy at the contact interface with force data as feedback. A multi-input fuzzy controller scheme that is robust to noise and operates in real time is proposed. Numerical and experimental results demonstrate the controller’s stability and its ability to rapidly converge to the desired force and orientation conditions.

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Force and pose control of a hemispherical ultrasonic probe in contact with viscoelastic gelatine

Facundo-Flores,

Baltazar,

Treesatayapun

2024

Meccanica

View full text Add to dashboard Cite

show abstract

Robustifying a reinforcement learning agent-based bionic reflex controller through an adaptive sliding mode control

Basumatary,

Adhar,

Hazarika

2024

Robotica

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Maintaining object grasp stability represents a pivotal challenge within the domain of robotic manipulation and upper-limb prosthetics. Perturbations originating from external sources frequently disrupt the stability of grasps, resulting in slippage occurrences. Also, if the grasping forces are not optimal while controlling the slip, it may result in the deformation of the objects. This study investigates the robustification of a reinforcement learning (RL) policy for implementing intelligent bionic reflex control, i.e., slip and deformation prevention of the grasped objects. RL-derived policies are vulnerable to failures in environments characterized by dynamic variability. To mitigate this vulnerability, we propose a methodology involving the incorporation of an adaptive sliding mode controller into a pre-trained RL policy. By exploiting the inherent invariance property of the sliding mode algorithm in the presence of uncertainties, our approach strengthens the robustness of the RL policies against diverse and dynamic variations. Numerical simulations substantiate the efficacy of our approach in robustifying RL policies trained within simulated environments.

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Modeling Contact Stiffness of Soft Fingertips for Grasping Applications

Cited by 2 publications

References 37 publications

Force and pose control of a hemispherical ultrasonic probe in contact with viscoelastic gelatine

Force and pose control of a hemispherical ultrasonic probe in contact with viscoelastic gelatine

Robustifying a reinforcement learning agent-based bionic reflex controller through an adaptive sliding mode control

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