Improving the Accuracy of Wearable Sensors for Human Locomotion Tracking Using Phase-Locked Regression Models

Ton T. H. Duong, Huanghe Zhang, T. Lynch, D. Zanotto
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引用次数: 7

Abstract

The trend toward soft wearable robotic systems creates a compelling need for new and reliable sensor systems that do not require a rigid mounting frame. Despite the growing use of inertial measurement units (IMUs) in motion tracking applications, sensor drift and IMU-to-segment misalignment still represent major problems in applications requiring high accuracy. This paper proposes a novel 2-step calibration method which takes advantage of the periodic nature of human locomotion to improve the accuracy of wearable inertial sensors in measuring lower-limb joint angles. Specifically, the method was applied to the determination of the hip joint angles during walking tasks. The accuracy and precision of the calibration method were accessed in a group of N =8 subjects who walked with a custom-designed inertial motion capture system at 85% and 115% of their comfortable pace, using an optical motion capture system as reference. In light of its low computational complexity and good accuracy, the proposed approach shows promise for embedded applications, including closed-loop control of soft wearable robotic systems.
利用锁相回归模型提高可穿戴式人体运动跟踪传感器的精度
软可穿戴机器人系统的发展趋势创造了对不需要刚性安装框架的新型可靠传感器系统的迫切需求。尽管惯性测量单元(imu)在运动跟踪应用中的应用越来越多,但在需要高精度的应用中,传感器漂移和IMU-to-segment不对准仍然是主要问题。利用人体运动的周期性,提出了一种新的两步标定方法,提高了可穿戴惯性传感器测量下肢关节角度的精度。具体来说,该方法被应用于步行任务中髋关节角度的确定。以N =8名受试者为研究对象,采用定制的惯性运动捕捉系统,分别以舒适步速的85%和115%行走,并以光学运动捕捉系统为参照,对校准方法的准确性和精密度进行评估。该方法计算复杂度低,精度高,可用于嵌入式应用,包括软可穿戴机器人系统的闭环控制。
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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