外骨骼运动学设计稳健性:一种考虑人类可变性的评估方法

IF 3.4 Q2 ENGINEERING, BIOMEDICAL Wearable technologies Pub Date : 2020-11-04 eCollection Date: 2020-01-01 DOI:10.1017/wtc.2020.7
Matteo Sposito, Christian Di Natali, Stefano Toxiri, Darwin G Caldwell, Elena De Momi, Jesús Ortiz
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引用次数: 0

摘要

摘要外骨骼是一种可穿戴设备,旨在为一个或多个人体关节执行某些活动提供物理帮助。从力学的角度来看,它们是与生物关节平行排列的运动学结构。为了允许用户在辅助的情况下移动,避免外骨骼运动学带来的移动限制至关重要。被动自由度和其他自对准机制是避免任何限制的常见选择。然而,文献缺乏一种系统的方法来解释在设计和评估运动链时受试者之间和受试者内部的巨大可变性。为此,我们引入了一种基于模型的方法来评估外骨骼的运动学,方法是将移动性的限制表示为锚点处的扰动和不期望的力。该方法利用机器人运动学工具,并生成有用的见解来支持设计过程。尽管说明了用于提升任务的背部支撑外骨骼的应用,但该方法可以描述任何类型的刚性外骨骼。进行了一项定性的试点试验,以评估运动学模型,该模型被证明可以预测与锚点处记录的不期望的力上升相关的运动学配置,这些力会导致使用者的行动受限和不适。
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Exoskeleton kinematic design robustness: An assessment method to account for human variability.

Exoskeletons are wearable devices intended to physically assist one or multiple human joints in executing certain activities. From a mechanical point of view, they are kinematic structures arranged in parallel to the biological joints. In order to allow the users to move while assisted, it is crucial to avoid mobility restrictions introduced by the exoskeleton's kinematics. Passive degrees of freedom and other self-alignment mechanisms are a common option to avoid any restrictions. However, the literature lacks a systematic method to account for large inter- and intra-subject variability in designing and assessing kinematic chains. To this end, we introduce a model-based method to assess the kinematics of exoskeletons by representing restrictions in mobility as disturbances and undesired forces at the anchor points. The method makes use of robotic kinematic tools and generates useful insights to support the design process. Though an application on a back-support exoskeleton designed for lifting tasks is illustrated, the method can describe any type of rigid exoskeleton. A qualitative pilot trial is conducted to assess the kinematic model that proved to predict kinematic configurations associated to rising undesired forces recorded at the anchor points, that give rise to mobility restrictions and discomfort on the users.

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来源期刊
CiteScore
5.80
自引率
0.00%
发文量
0
审稿时长
11 weeks
期刊最新文献
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