步态
运动学
弹道
控制理论(社会学)
扭矩
控制器(灌溉)
计算机科学
外骨骼
最佳步行速度
单调的工作
自适应控制
矫形学
理论(学习稳定性)
趋同(经济学)
适应(眼睛)
生物力学
模拟
机器人
节奏
机器人运动学
动力外骨骼
机器人学
工程类
六足动物
步态分析
功能性电刺激
人工智能
自适应系统
控制工程
作者
Mohammad Shushtari,Livia Murray,Atusa Ghorbani Siavashani,Arash Arami
标识
DOI:10.1109/tro.2026.3663979
摘要
This study presents and experimentally validates an adaptive control method for human-exoskeleton interaction through online adaptation of desired joint trajectories. Leveraging gait phase and human-exoskeleton interaction torque estimators, our approach enables seamless assistance adaptation to varying walking patterns and speeds. Specifically, a pre-trained neural network approximates the exoskeleton's dynamics, enabling real-time interaction torque estimation from kinematic measurements and commanded motor torques alone. These estimates drive a gradient-descent update of the joint reference trajectories, minimizing a cost function that penalizes both interaction torques and trajectory modification, ensuring bounded convergence and stability without user-specific parameter tuning. We compared our adaptive controller with a fixed-trajectory gait-phase-based controller during overground and treadmill walking at three self-selected speeds ranging from 0.4 to 0.8 m/s. In 16 participants, the adaptive controller significantly reduced the hip and knee interaction torques by 51.2%$\pm$11.1 and 63.9%$\pm$29.7, respectively, during overground walking. Muscular effort significantly decreased in Bicep Femoris (21.0%$\pm$34.5) and Rectus Femoris (28.1%$\pm$34.6), while remaining unchanged in other muscles. Cadence and gait speed increased by 7.6%$\pm$5.2 and 10.7%$\pm$8.3, respectively, indicating that participants could walk faster with less effort due to trajectory adaptation. Post-adaptation trajectories more closely resembled those of walking without the exoskeleton, and exoskeleton-torques aligned more closely with human biological torques. Our proposed adaptive controller, which requires only exoskeleton kinematics, also maintained performance during treadmill walking across speeds, demonstrating speed-invariant behaviour compared to the non-adaptive controller.
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