下肢康复机器人个性化三维步态模式生成器。

Pablo Romero-Sorozabal, Gabriel Delgado-Oleas, Alvaro Gutierrez, Eduardo Rocon
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引用次数: 0

摘要

在机器人步态康复领域,经常需要控制机器人设备遵循特定的类人轨迹。近年来,已经提出了各种步态生成器模型,提供可调节到一系列高度和步态速度的定制步态模式。然而,这些模型的开发重点是步态康复设备,该设备旨在控制受试者关节的角度轨迹,例如外骨骼。类似的设备,例如末端执行器机器人,控制受试者关节的方向和3D位置,并且不能容易地实现这些模型。在本研究中,提出了一种新的用于步态康复机器人的个性化三维步态模式生成器。生成器采用多变量回归模型来预测骨盆、髋关节和踝关节沿步态周期的角度轨迹。然后,通过在人体模型上应用预测的角轨迹来重建3D关节位置,该模型的灵感来自于使用逆运动学的倒立摆模拟。根据42名以8种不同速度行走的参与者的真实步态模式,对发电机的性能进行了统计评估。预测的轨迹与测量的轨迹相匹配,所有笛卡尔轴上所有关节的平均均方根误差为25.73 mm,在3.3-5.4 km/h之间有更好的结果。为应用于末端执行器步态机器人康复装置提供了一个很好的解决方案。
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Individualized Three-Dimensional Gait Pattern Generator for Lower Limbs Rehabilitation Robots.

In the field of robotic gait rehabilitation, controlling robotic devices to follow specific human-like trajectories is often required. In recent years, various gait generator models have been proposed, providing customized gait patterns adjustable to a range of heights and gait speeds. However, these models were developed with a focus on gait rehabilitation devices designed to control the angular trajectories of the subject's joints, e.g. exoskeletons. Similar devices, e.g. end-effector robots, control the orientation and also the 3D position of the subject's joints and cannot easily implement these models. In this study, it is proposed a new individualized three-dimensional gait pattern generator for gait rehabilitation robots. The generator employs multi-variable regression models to predict the joint angular trajectories of the pelvis, hip, and ankle along the gait cycle. The 3D joints positions are then reconstructed by applying the predicted angular trajectories over a human model inspired on the inverted pendulum analogy using inverse kinematics. The generator's performance was statistically evaluated against real gait patterns from 42 participants walking at 8 different velocities. The predicted trajectories matched the measured ones with an average Root Mean Squared Error of 25.73 mm for all joints at all Cartesian axes, with better results between 3.3 - 5.4 km/h. Suggesting to be a good solution to be applied in end-effector gait robotic rehabilitation devices.

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Individualized Three-Dimensional Gait Pattern Generator for Lower Limbs Rehabilitation Robots. Individualized Training of Back Muscles Using Iterative Learning Control of a Compliant Balance Board. Influence of Robotic Therapy on Severe Stroke Patients. INSPIIRE - A Modular and Passive Exoskeleton to Investigate Human Walking and Balance. Instrumented Upper Limb Functional Assessment Using a Robotic Exoskeleton: Normative References Intervals.
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