反推
外骨骼
控制理论(社会学)
执行机构
机器人
控制器(灌溉)
控制工程
计算机科学
李雅普诺夫函数
自适应控制
理论(学习稳定性)
非线性系统
康复机器人
自由度(物理和化学)
控制(管理)
工程类
动力学(音乐)
机器人学
非线性控制
机器人控制
Lyapunov稳定性
可穿戴计算机
控制系统
系统动力学
移动机器人
鲁棒控制
有界函数
作者
Brahim Brahmi,Maarouf Saad
标识
DOI:10.1109/tsmc.2025.3616513
摘要
Exoskeleton robots hold immense promise in rehabilitation, serving as crucial aids for patient mobility and exercise. However, harnessing their capabilities requires overcoming significant control challenges arising from complex nonlinear dynamics and uncertainties in both models and actuators. This article introduces a novel adaptive backstepping controller designed specifically for exoskeleton robots navigating uncertain dynamics and actuator parameters. Unlike conventional approaches that rely on basis functions, the proposed controller (PL) integrates a modified function approximation technique (MFAT) to approximate dynamic parameters without the need for such functions. The MFAT effectively manages mismatched perturbations, while the backstepping control compensates for uncertainties associated with state variables, enhancing resilience to disturbances, especially in scenarios where the exoskeleton’s dynamics model is unknown. The Lyapunov stability analysis ensures uniformly ultimately bounded (UUB) signals within the closed-loop system. A comparative study conducted on the industrial robot IRB 120 validates the effectiveness of the PL and highlights its superior performance. Real-time implementation on a seven degrees of freedom (DOFs) wearable robot named ETS-MARSE confirms the efficiency of the control algorithm. The results from simulations and experiments underscore the efficacy of the proposed approach. The insights gained from this article pave the way to unlocking the full potential of exoskeleton robots in rehabilitation settings, promising improved patient outcomes and advancing human-technology interaction to new heights.
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