在步行速度和坡度上实现对动力假肢连续可变阻抗控制的统一方法

Albert J Lee, Curt A Laubscher, T Kevin Best, Robert D Gregg
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引用次数: 0

摘要

基于阻抗的控制算法具有仿生能力和直观结构,因此动力假肢控制领域的研究一直在探索使用这种算法。现代阻抗控制器的特点是其参数可根据数据驱动模型在步态阶段和任务中平滑变化。然而,这些最新成果只在站立时使用连续阻抗控制,而在摆动时则利用离散转换逻辑切换到运动控制,这就需要为步幅的不同部分建立两个独立的模型。相比之下,本文提出的控制器在整个步态过程中使用平滑的阻抗参数轨迹,将步态和摆动期统一在一个单一的连续模型下。此外,本文还提出了一个基础模型来表示阻抗参数中的任务间关系--与传统的线性插值方法相比,这种策略已被证明能提高模型精度。在所提出的控制器中,傅立叶级数的加权和被用来将每个关节的阻抗参数建模为步态周期进展和任务的连续函数。通过凸优化确定傅立叶级数系数,使控制器能最好地再现参考健全数据集中的关节扭矩和运动学。用动力膝关节假肢进行的实验表明,与更复杂的混合阻抗运动学模型相比,这种更简单的统一模型在不同的步行速度和坡度下能产生有竞争力的结果。
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Towards a Unified Approach for Continuously-Variable Impedance Control of Powered Prosthetic Legs over Walking Speeds and Inclines.

Research in powered prosthesis control has explored the use of impedance-based control algorithms due to their biomimetic capabilities and intuitive structure. Modern impedance controllers feature parameters that smoothly vary over gait phase and task according to a data-driven model. However, these recent efforts only use continuous impedance control during stance and instead utilize discrete transition logic to switch to kinematic control during swing, necessitating two separate models for the different parts of the stride. In contrast, this paper presents a controller that uses smooth impedance parameter trajectories throughout the gait, unifying the stance and swing periods under a single, continuous model. Furthermore, this paper proposes a basis model to represent intertask relationships in the impedance parameters-a strategy that has previously been shown to improve model accuracy over classic linear interpolation methods. In the proposed controller, a weighted sum of Fourier series is used to model the impedance parameters of each joint as continuous functions of gait cycle progression and task. Fourier series coefficients are determined via convex optimization such that the controller best reproduces the joint torques and kinematics in a reference able-bodied dataset. Experiments with a powered knee-ankle prosthesis show that this simpler, unified model produces competitive results when compared to a more complex hybrid impedance-kinematic model over varying walking speeds and inclines.

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