Design and Validation of an Underactuated Modular Exoskeleton With Multijoint Coupling Assistance for Enhancing Human Locomotion With Reduced Hip Impact
Xinyu Wu;Aibin Zhu;Chunli Zheng;Lei Shi;Peng Xu;Bingsheng Bao;Jing Zhang;Xiao Li
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引用次数: 0
Abstract
Knee and ankle single-joint exoskeletons enhance human locomotion but can impact the hip joint. This article introduces a multijoint coupling assistance mechanism and a modular exoskeleton prototype that avoids negative effects on the hip joint. During the stance phase, it sequentially assists the knee and ankle with one quasi-direct drive motor without affecting other joints, and reduces hip joint load in the swing phase. A controller trained on inertial measurement unit data from both legs determines the gait phase and generates corresponding biological torque. Experiments showed a 9.08% decrease in peak fascia lata muscle activity and an 18.32% reduction in peak hip joint torque when using the exoskeleton. This study reports that reducing the impact on the hip joint when assisting a single joint such as the knee or ankle can enhance the overall assistance performance of the exoskeleton.
期刊介绍:
IEEE/ASME Transactions on Mechatronics publishes high quality technical papers on technological advances in mechatronics. A primary purpose of the IEEE/ASME Transactions on Mechatronics is to have an archival publication which encompasses both theory and practice. Papers published in the IEEE/ASME Transactions on Mechatronics disclose significant new knowledge needed to implement intelligent mechatronics systems, from analysis and design through simulation and hardware and software implementation. The Transactions also contains a letters section dedicated to rapid publication of short correspondence items concerning new research results.
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