Patient-driven control of FES-supported standing up and sitting down: experimental results.

IEEE transactions on rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society Pub Date : 2000-12-01 DOI:10.1109/86.895956

R. Riener, M. Ferrarin, E. Pavan, C. Frigo

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引用次数: 88

Abstract

A patient-driven control strategy for standing-up and sitting-down was experimentally tested on two paraplegic patients by applying functional electrical stimulation (FES) to the quadriceps muscle. The strategy--also known as "patient-driven motion reinforcement" (PDMR)--was developed by computer simulations reported in a former study. It is based on an inverse dynamic model (IDM) that predicts the stimulation pattern required to maintain the movement as it is initiated by the patient's voluntary effort. For reasons of safety and weight relief, the movement was supported by a seesaw construction. After some practice the patients were able to influence the stimulator output and to control the movement by their voluntary effort. Consequently, no pre-programmed reference trajectory was required. As a positive side effect, upper body effort could be minimized compared to trials without FES. To achieve a satisfactory performance of the PDMR controller a careful parameter identification of the inverse dynamic model was fundamental.

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fes支持站立和坐下的患者驱动控制:实验结果。

通过对两名截瘫患者的四头肌进行功能性电刺激(FES)，对患者驱动的站立和坐下控制策略进行了实验测试。这种策略——也被称为“病人驱动的运动强化”(PDMR)——是在以前的一项研究中通过计算机模拟开发出来的。它是基于一个反向动态模型(IDM)，预测维持运动所需的刺激模式，因为它是由病人的自愿努力发起的。出于安全和减轻重量的考虑，机芯由跷跷板结构支撑。经过一些练习，患者能够影响刺激器的输出，并通过他们的自愿努力控制运动。因此，不需要预先编程的参考轨迹。作为积极的副作用，与没有FES的试验相比，上身的努力可以最小化。为了使PDMR控制器获得满意的性能，精确的逆动力学模型参数辨识是至关重要的。

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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IEEE transactions on rehabilitation engineering : a publication of the IEEE Engineering in Medicine and Biology Society

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