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An Intuitive Formulation of the Human Arm Active Endpoint Stiffness

In this work, we propose an intuitive and real-time model of the human arm active endpoint stiffness. In our model, the symmetric and positive-definite stiffness matrix is constructed through the eigendecomposition Kc=VDVT, where V is an orthonormal matrix whose columns are the normalized eigenvecto...

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Published in:	Sensors (Basel, Switzerland) Switzerland), 2020-09, Vol.20 (18), p.5357
Main Authors:	Wu, Yuqiang, Zhao, Fei, Kim, Wansoo, Ajoudani, Arash
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Language:	English
Subjects:	Arm human factors Humans Models, Theoretical Movement physical human–robot collaboration Range of Motion, Articular robot adaptation and learning Skeleton
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description	In this work, we propose an intuitive and real-time model of the human arm active endpoint stiffness. In our model, the symmetric and positive-definite stiffness matrix is constructed through the eigendecomposition Kc=VDVT, where V is an orthonormal matrix whose columns are the normalized eigenvectors of Kc, and D is a diagonal matrix whose entries are the eigenvalues of Kc. In this formulation, we propose to construct V and D directly by exploiting the geometric information from a reduced human arm skeleton structure in 3D and from the assumption that human arm muscles work synergistically when co-contracted. Through the perturbation experiments across multiple subjects under different arm configurations and muscle activation states, we identified the model parameters and examined the modeling accuracy. In comparison to our previous models for predicting human active arm endpoint stiffness, the new model offers significant advantages such as fast identification and personalization due to its principled simplicity. The proposed model is suitable for applications such as teleoperation, human-robot interaction and collaboration, and human ergonomic assessments, where a personalizable and real-time human kinodynamic model is a crucial requirement.
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subjects	Arm human factors Humans Models, Theoretical Movement physical human–robot collaboration Range of Motion, Articular robot adaptation and learning Skeleton
title	An Intuitive Formulation of the Human Arm Active Endpoint Stiffness
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