Series-elastic actuator with two degree-of-freedom PID control improves torque control in a powered knee exoskeleton

IF 3.4 Q2 ENGINEERING, BIOMEDICAL Wearable technologies Pub Date : 2023-01-01 DOI:10.1017/wtc.2023.20
Sergei V. Sarkisian, Lukas Gabert, Tommaso Lenzi
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Abstract

Abstract Powered exoskeletons need actuators that are lightweight, compact, and efficient while allowing for accurate torque control. To satisfy these requirements, researchers have proposed using series elastic actuators (SEAs). SEAs use a spring in series with rotary or linear actuators. The spring compliance, in conjunction with an appropriate control scheme, improves torque control, efficiency, output impedance, and disturbance rejection. However, springs add weight to the actuator and complexity to the control, which may have negative effects on the performance of the powered exoskeleton. Therefore, there is an unmet need for new SEA designs that are lighter and more efficient than available systems, as well as for control strategies that push the performance of SEA-based exoskeletons without requiring complex modeling and tuning. This article presents the design, development, and testing of a novel SEA with high force density for powered exoskeletons, as well as the use of a two degree-of-freedom (2DOF) PID system to improve output impedance and disturbance rejection. Benchtop testing results show reduced output impedance and damping values when using a 2DOF PID controller as compared to a 1DOF PID controller. Human experiments with three able-bodied subjects ( N = 3) show improved torque tracking with reduced root-mean-square error by 45.2% and reduced peak error by 49.8% when using a 2DOF PID controller. Furthermore, EMG data shows a reduction in peak EMG value when using the exoskeleton in assistive mode compared to the exoskeleton operating in transparent mode.
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采用双自由度PID控制的系列弹性致动器改善了动力膝关节外骨骼的扭矩控制
动力外骨骼需要轻巧、紧凑、高效的致动器,同时允许精确的扭矩控制。为了满足这些要求,研究人员提出使用串联弹性执行器(SEAs)。SEAs使用弹簧串联旋转或线性执行器。弹簧顺应性,结合适当的控制方案,提高扭矩控制,效率,输出阻抗和抗干扰性。然而,弹簧增加了致动器的重量和控制的复杂性,这可能对动力外骨骼的性能产生负面影响。因此,对于比现有系统更轻、更高效的新型SEA设计,以及在不需要复杂建模和调优的情况下推动基于SEA的外骨骼性能的控制策略,都存在未满足的需求。本文介绍了一种用于动力外骨骼的具有高力密度的新型SEA的设计,开发和测试,以及使用两自由度(2DOF) PID系统来改善输出阻抗和抗干扰性。台式测试结果表明,与使用1DOF PID控制器相比,使用2DOF PID控制器可以降低输出阻抗和阻尼值。对3名健全受试者(N = 3)进行的人体实验表明,使用2自由度PID控制器可以改善转矩跟踪,使均方根误差降低45.2%,峰值误差降低49.8%。此外,肌电数据显示,与在透明模式下运行的外骨骼相比,在辅助模式下使用外骨骼时,肌电峰值值有所降低。
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来源期刊
CiteScore
5.80
自引率
0.00%
发文量
0
审稿时长
11 weeks
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