Multi-objective Design Optimization and Control Strategy for Digital Hydraulically Driven Knee Exoskeleton

IF 0.7 Q4 ENGINEERING, MECHANICAL

International Journal of Fluid Power Pub Date : 2023-05-03 DOI:10.13052/ijfp1439-9776.2425

Rituraj, R. Scheidl

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Abstract

This article presents a multi-objective design optimization strategy to determine an optimal design of digital hydraulically driven knee exoskeleton. To satisfy the overall goal of compact and lightweight design, four key design objectives are defined. Via genetic algorithm based multi-objective optimization technique, the pareto-optimal set of designs is determined and the trade-offs between the design objectives are analysed. Via decisions based on component availability and user-comfort, the dimensionality of the pareto-front is reduced to two and an exoskeleton design is selected that offers a good compromise between the design objectives. For the actuation of the exoskeleton, an energy efficient control strategy is proposed which consists of using passive control during the stance phase and simplified model predictive control during the swing phase. The operation of the chosen knee exoskeleton design and the control strategy is investigated via numerical simulations. The results indicate that the exoskeleton successfully tracks the desired knee motion and delivers the required knee torque.

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数字液压驱动膝关节外骨骼的多目标设计优化与控制策略

本文提出了一种多目标设计优化策略，以确定数字液压驱动膝关节外骨骼的优化设计。为了满足紧凑和轻量化设计的总体目标，定义了四个关键的设计目标。通过基于遗传算法的多目标优化技术，确定了帕累托最优设计集，并分析了设计目标之间的权衡。通过基于组件可用性和用户舒适度的决策，将帕累托前沿的维度减少到两个，并选择在设计目标之间提供良好折衷的外骨骼设计。对于外骨骼的驱动，提出了一种节能控制策略，该策略包括在站立阶段使用被动控制和在摆动阶段使用简化模型预测控制。通过数值模拟研究了所选择的膝关节外骨骼设计的操作和控制策略。结果表明，外骨骼成功地跟踪了所需的膝盖运动，并提供了所需膝盖扭矩。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Fluid Power ENGINEERING, MECHANICAL-

CiteScore

1.60

自引率

0.00%

发文量