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使用鞋载惯性传感器估计跑步速度:直接积分、线性和个性化模型

Running Speed Estimation Using Shoe-Worn Inertial Sensors: Direct Integration, Linear, and Personalized Model.

作者信息

Falbriard Mathieu, Soltani Abolfazl, Aminian Kamiar

机构信息

Laboratory of Movement Analysis and Measurement, École Polytechnique Fédérale de Lausanne, Lausanne, Switzerland.

出版信息

Front Sports Act Living. 2021 Mar 18;3:585809. doi: 10.3389/fspor.2021.585809. eCollection 2021.

DOI:10.3389/fspor.2021.585809
PMID:33817632
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8014039/
Abstract

The overground speed is a key component of running analysis. Today, most speed estimation wearable systems are based on GNSS technology. However, these devices can suffer from sparse communication with the satellites and have a high-power consumption. In this study, we propose three different approaches to estimate the overground speed in running based on foot-worn inertial sensors and compare the results against a reference GNSS system. First, a method is proposed by direct strapdown integration of the foot acceleration. Second, a feature-based linear model and finally a personalized online-model based on the recursive least squares' method were devised. We also evaluated the performance differences between two sets of features; one automatically selected set (i.e., optimized) and a set of features based on the existing literature. The data set of this study was recorded in a real-world setting, with 33 healthy individuals running at low, preferred, and high speed. The direct estimation of the running speed achieved an inter-subject mean ± STD accuracy of 0.08 ± 0.1 m/s and a precision of 0.16 ± 0.04 m/s. In comparison, the best feature-based linear model achieved 0.00 ± 0.11 m/s accuracy and 0.11 ± 0.05 m/s precision, while the personalized model obtained a 0.00 ± 0.01 m/s accuracy and 0.09 ± 0.06 m/s precision. The results of this study suggest that (1) the direct estimation of the velocity of the foot are biased, and the error is affected by the overground velocity and the slope; (2) the main limitation of a general linear model is the relatively high inter-subject variance of the bias, which reflects the intrinsic differences in gait patterns among individuals; (3) this inter-subject variance can be nulled using a personalized model.

摘要

地面速度是跑步分析的关键组成部分。如今,大多数速度估计可穿戴系统都基于全球导航卫星系统(GNSS)技术。然而,这些设备可能会出现与卫星通信稀疏以及功耗高的问题。在本研究中,我们提出了三种基于足部惯性传感器估计跑步地面速度的不同方法,并将结果与参考GNSS系统进行比较。首先,提出了一种通过直接对足部加速度进行捷联积分的方法。其次,设计了一种基于特征的线性模型,最后设计了一种基于递归最小二乘法的个性化在线模型。我们还评估了两组特征之间的性能差异;一组是自动选择的(即优化的)特征集,另一组是基于现有文献的特征集。本研究的数据集是在现实环境中记录的,33名健康个体以低速、偏好速度和高速跑步。跑步速度的直接估计在受试者间的平均±标准差精度为0.08±0.1米/秒,精度为0.16±0.04米/秒。相比之下,最佳的基于特征的线性模型的精度为0.00±0.11米/秒,精度为0.11±0.05米/秒,而个性化模型的精度为0.00±0.01米/秒,精度为0.09±0.06米/秒。本研究结果表明:(1)足部速度的直接估计存在偏差,误差受地面速度和坡度影响;(2)一般线性模型的主要局限性是偏差的受试者间方差相对较高,这反映了个体间步态模式的内在差异;(3)使用个性化模型可以消除这种受试者间方差。

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