Fractional multi-loop active disturbance rejection control for a lower knee exoskeleton system

IF 0.6 Q3 ENGINEERING, MULTIDISCIPLINARY

Acta Polytechnica Pub Date : 2023-07-04 DOI:10.14311/ap.2023.63.0158

N. A. Al-awad, A. Humaidi, A. Al-Araji

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引用次数: 0

Abstract

Rehabilitation Exoskeleton is becoming more and more important in physiotherapists’ routine work. To improve the treatment performance, such as reducing the recovery period and/or monitoring and reacting to unpredictable situations, the rehabilitation manipulators need to help the patients in various physical trainings. A special case of the active disturbance rejection control (ADRC) is applied to govern a proper realisation of basic limb rehabilitation trainings. The experimental study is performed on a model of a flexible joint manipulator, whose behaviour resembles a real exoskeleton rehabilitation device (a one-degree-of-freedom, rigid-link, flexible-joint manipulator). The fractional (FADRC) is an unconventional model-independent approach, acknowledged as an effective controller in the existence of total plant uncertainties, and these uncertainties are inclusive of the total disturbances and unknown dynamics of the plant. In this work, three FADRC schemes are used, the first one using a fractional state observer (FSO), or FADRC1, second one using a fractional proportional-derivative controller (FPD), or FADRC2, and the third one a Multi-loop fractional in PD-loop controller and the observer-loop (Feedforward and Feedback), or FADRC3. The simulated Exoskeleton system is subjected to a noise disturbance and the FADRC3 shows the effectiveness to compensate all these effects and satisfies the desired position when compared with FADRC1 and FADRC2. The design and simulation were carried out in MATLAB/Simulink.

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膝关节外骨骼系统的分数阶多回路自抗扰控制

外骨骼康复在物理治疗师的日常工作中越来越重要。为了提高治疗效果，例如缩短恢复期和/或监测和应对不可预测的情况，康复操纵者需要在各种体能训练中帮助患者。应用主动抗扰控制（ADRC）的一个特殊情况来管理基本肢体康复训练的正确实现。实验研究是在柔性关节机械手的模型上进行的，其行为类似于真实的外骨骼康复设备（一个自由度、刚性连杆、柔性关节机械臂）。分数阶（FADRC）是一种非常规的模型无关方法，被公认为存在总对象不确定性的有效控制器，这些不确定性包括总扰动和对象的未知动力学。在这项工作中，使用了三种FADRC方案，第一种方案使用分数状态观测器（FSO）或FADRC1，第二种方案使用小数比例微分控制器（FPD）或FADR C2，第三种方案使用多环路分数PD环路控制器和观测器环路（前馈和反馈）或FADRC3。模拟的外骨骼系统受到噪声干扰，与FADRC1和FADRC2相比，FADRC3显示出补偿所有这些影响的有效性，并满足所需位置。在MATLAB/Simulink中进行了设计和仿真。

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

Acta Polytechnica ENGINEERING, MULTIDISCIPLINARY-

CiteScore

1.90

自引率

12.50%

发文量

审稿时长

24 weeks

期刊介绍： Acta Polytechnica is a scientific journal published by CTU in Prague. The main title, Acta Polytechnica, is accompanied by the subtitle Journal of Advanced Engineering, which defines the scope of the journal more precisely - Acta Polytechnica covers a wide spectrum of engineering topics, physics and mathematics. Our aim is to be a high-quality multi-disciplinary journal publishing the results of basic research and also applied research. We place emphasis on the quality of all published papers. The journal should also serve as a bridge between basic research in natural sciences and applied research in all technical disciplines. The innovative research results published by young researchers or by postdoctoral fellows, and also the high-quality papers by researchers from the international scientific community, reflect the good position of CTU in the World University Rankings. We hope that you will ﬁnd our journal interesting, and that it will serve as a valuable source of scientiﬁc information.