用于 10 DOF 下肢外骨骼的基于无模型的自适应后退-超级扭转-RBF 神经网络控制(含 α 变量

Farid Kenas, Nadia Saadia, Amina Ababou, Noureddine Ababou
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引用次数: 0

摘要

下肢外骨骼在增强人类活动能力和提高行动不便者的生活质量方面发挥着举足轻重的作用。鉴于这些迫切需求,本文介绍了一种改进的 10 自由度下肢外骨骼控制策略,尤其侧重于增强稳定性、精确性和鲁棒性。为了简化复杂的外骨骼动态模型,我们的方法采用了更易于管理的二阶超局部模型。我们采用两个径向基函数(RBF)神经网络来精确估计与该超局部模型相关的整块干扰和非物理参数。此外,我们的控制策略集成了反向步进技术和超扭曲算法,以最大限度地减少跟踪误差。利用 Lyapunov 理论严格确定了所设计控制器的稳定性。在实施阶段,我们使用 SolidWorks 精心设计了外骨骼的虚拟原型,然后导出到 Matlab/Simscape Multibody 进行协同仿真。此外,我们还从表面肌电图(sEMG)测量数据中推导出所需轨迹,使我们的控制策略与用户的实际需求相一致。全面的实验和分析得出了令人信服的数值结果,凸显了我们提出的方法的优越性。在所有 10 个自由度上,我们的控制器都比其他控制器具有显著优势。平均而言,它比基于自适应反步态 -RBF 控制器提高了约 45%,比基于无模型反步态滑模控制器提高了 74%,比基于超局部模型和径向基函数神经网络的自适应有限时间控制提高了 74%。此外,与 PID 控制器相比,我们的方法也有超过 80% 的显著改进。这些重要发现证明了我们提出的控制策略在提高下肢外骨骼性能方面的有效性,为可穿戴机器人领域的进步铺平了道路。
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Model-free based adaptive BackStepping-Super Twisting-RBF neural network control with α-variable for 10 DOF lower limb exoskeleton

Lower limb exoskeletons play a pivotal role in augmenting human mobility and improving the quality of life for individuals with mobility impairments. In light of these pressing needs, this paper presents an improved control strategy for a 10-degree-of-freedom lower limb exoskeleton, with a particular focus on enhancing stability, precision, and robustness. To simplify the intricate dynamic model of the exoskeleton, our approach leverages a more manageable 2nd order ultra-local model. We employ two radial basis function (RBF) neural networks to accurately estimate both lumped disturbances and non-physical parameters associated with this ultra-local model. In addition, our control strategy integrates the backstepping technique and the super twisting algorithm to minimize tracking errors. The stability of the designed controller is rigorously established using Lyapunov theory. In the implementation phase, a virtual prototype of the exoskeleton is meticulously designed using SolidWorks and then exported to Matlab/Simscape Multibody for co-simulation. Furthermore, the desired trajectories are derived from surface electromyography (sEMG) measured data, aligning our control strategy with the practical needs of the user. Comprehensive experimentation and analysis have yielded compelling numerical findings that underscore the superiority of our proposed method. Across all 10 degrees of freedom, our controller demonstrates a significant advantage over alternative controllers. On average, it exhibits an approximately 45% improvement compared to the Adaptive Backstepping-Based -RBF Controller, a 74% improvement compared to the Model-Free Based Back-Stepping Sliding Mode Controller, and an outstanding 74% improvement compared to the Adaptive Finite Time Control Based on Ultra-local Model and Radial Basis Function Neural Network. Furthermore, when compared to the PID controller, our approach showcases an exceptional improvement of over 80%. These significant findings underscore the effectiveness of our proposed control strategy in enhancing lower limb exoskeleton performance, paving the way for advancements in the field of wearable robotics.

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来源期刊
CiteScore
3.80
自引率
5.90%
发文量
50
期刊介绍: The International Journal of Intelligent Robotics and Applications (IJIRA) fosters the dissemination of new discoveries and novel technologies that advance developments in robotics and their broad applications. This journal provides a publication and communication platform for all robotics topics, from the theoretical fundamentals and technological advances to various applications including manufacturing, space vehicles, biomedical systems and automobiles, data-storage devices, healthcare systems, home appliances, and intelligent highways. IJIRA welcomes contributions from researchers, professionals and industrial practitioners. It publishes original, high-quality and previously unpublished research papers, brief reports, and critical reviews. Specific areas of interest include, but are not limited to:Advanced actuators and sensorsCollective and social robots Computing, communication and controlDesign, modeling and prototypingHuman and robot interactionMachine learning and intelligenceMobile robots and intelligent autonomous systemsMulti-sensor fusion and perceptionPlanning, navigation and localizationRobot intelligence, learning and linguisticsRobotic vision, recognition and reconstructionBio-mechatronics and roboticsCloud and Swarm roboticsCognitive and neuro roboticsExploration and security roboticsHealthcare, medical and assistive roboticsRobotics for intelligent manufacturingService, social and entertainment roboticsSpace and underwater robotsNovel and emerging applications
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