Automatic Tuning of Virtual Constraint-Based Control Algorithms for Powered Knee-Ankle Prostheses.

Control Technology and Applications. Control Technology and Applications Pub Date : 2017-08-01 DOI:10.1109/CCTA.2017.8062560

Saurav Kumar, Alireza Mohammadi, Nicholas Gans, Robert D Gregg

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引用次数: 16

Abstract

State-of-art powered prosthetic legs are often controlled using a collection of joint impedance controllers designed for different phases of a walking cycle. Consequently, finite state machines are used to control transitions between different phases. This approach requires a large number of impedance parameters and switching rules to be tuned. Since one set of control parameters cannot be used across different amputees, clinicians spend enormous time tuning these gains for each patient. This paper proposes a virtual constraint-based control scheme with a smaller set of control parameters, which are automatically tuned in real-time using an extremum seeking controller (ESC). ESC, being a model-free control method, assumes no prior knowledge of either the prosthesis or human. Using a singular perturbation analysis, we prove that the virtual constraint tracking errors are small and the PD gains remain bounded. Simulations demonstrate that our ESC-based method is capable of adapting the virtual-constraint based control parameters for amputees with different masses.

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基于虚拟约束的动力膝关节假肢控制算法的自动调谐。

最先进的动力假肢通常使用针对步行周期的不同阶段设计的关节阻抗控制器集合来控制。因此，有限状态机用于控制不同阶段之间的转换。这种方法需要调整大量的阻抗参数和开关规则。由于一组控制参数不能用于不同的截肢者，临床医生花费大量时间为每个患者调整这些增益。本文提出了一种基于虚拟约束的控制方案，该方案具有较小的控制参数集，并使用极值搜索控制器(ESC)实时自动调整控制参数。ESC是一种无模型控制方法，不需要预先了解假体或人。利用奇异摄动分析，我们证明了虚拟约束跟踪误差很小，PD增益保持有界。仿真结果表明，基于esc的方法能够适应不同质量截肢者的虚拟约束控制参数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Control Technology and Applications. Control Technology and Applications

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