Comparison of different machine learning models to enhance sacral acceleration-based estimations of running stride temporal variables and peak vertical ground reaction force.

IF 2 3区医学 Q3 ENGINEERING, BIOMEDICAL

Sports Biomechanics Pub Date : 2025-04-01 Epub Date: 2023-01-06 DOI:10.1080/14763141.2022.2159870

Aurélien Patoz, Thibault Lussiana, Bastiaan Breine, Cyrille Gindre, Davide Malatesta

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引用次数: 0

Abstract

Machine learning (ML) was used to predict contact ( $t_{c}$ ) and flight ( $t_{f}$ ) time, duty factor (DF) and peak vertical force ( $F_{v, \max}$ ) from IMU-based estimations. One hundred runners ran on an instrumented treadmill (9-13 km/h) while wearing a sacral-mounted IMU. Linear regression (LR), support vector regression and two-layer neural-network were trained (80 participants) using IMU-based estimations, running speed, stride frequency and body mass. Predictions (remaining 20 participants) were compared to gold standard (kinetic data collected using the force plate) by calculating the mean absolute percentage error (MAPE). MAPEs of $F_{v, \max}$ did not significantly differ among its estimation and predictions (P = 0.37), while prediction MAPEs for $t_{c}$ , $t_{f}$ and DF were significantly smaller than corresponding estimation MAPEs (P ≤ 0.003). There were no significant differences among prediction MAPEs obtained from the three ML models (P ≥ 0.80). Errors of the ML models were equal to or smaller than (≤32%) the smallest real difference for the four variables, while errors of the estimations were not (15-45%), indicating that ML models were sufficiently accurate to detect a clinically important difference. The simplest ML model (LR) should be used to improve the accuracy of the IMU-based estimations. These improvements may be beneficial when monitoring running-related injury risk factors in real-world settings.

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不同机器学习模型的比较，以增强基于骶骨加速度的跑步跨步时间变量和峰值垂直地面反作用力的估计。

使用机器学习（ML）从基于imu的估计中预测接触（tc）和飞行（tf）时间、占空因子（DF）和峰值垂直力（Fv,max）。100名跑步者戴着安装在骶骨上的IMU，在仪器化的跑步机上（9-13公里/小时）跑步。使用基于imu的估计、跑步速度、步频和体重对80名参与者进行线性回归、支持向量回归和双层神经网络训练。通过计算平均绝对百分比误差（MAPE），将预测结果（剩余20名参与者）与金标准（使用力板收集的动力学数据）进行比较。Fv、max的估计值与预测值的mape差异不显著（P = 0.37）， tc、tf、DF的预测mape显著小于相应的估计值（P≤0.003）。三种ML模型的预测mape之间无显著差异（P≥0.80）。ML模型的误差等于或小于（≤32%）四个变量的最小实际差值，而估计误差不为（15-45%），表明ML模型足够准确，可以检测到临床上重要的差异。应该使用最简单的ML模型（LR）来提高基于imu的估计的准确性。在现实环境中监测与跑步相关的伤害风险因素时，这些改进可能是有益的。

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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来源期刊

Sports Biomechanics 医学-工程：生物医学

CiteScore

5.70

自引率

9.10%

发文量

135

审稿时长

>12 weeks

期刊介绍： Sports Biomechanics is the Thomson Reuters listed scientific journal of the International Society of Biomechanics in Sports (ISBS). The journal sets out to generate knowledge to improve human performance and reduce the incidence of injury, and to communicate this knowledge to scientists, coaches, clinicians, teachers, and participants. The target performance realms include not only the conventional areas of sports and exercise, but also fundamental motor skills and other highly specialized human movements such as dance (both sport and artistic). Sports Biomechanics is unique in its emphasis on a broad biomechanical spectrum of human performance including, but not limited to, technique, skill acquisition, training, strength and conditioning, exercise, coaching, teaching, equipment, modeling and simulation, measurement, and injury prevention and rehabilitation. As well as maintaining scientific rigour, there is a strong editorial emphasis on ''reader friendliness''. By emphasising the practical implications and applications of research, the journal seeks to benefit practitioners directly. Sports Biomechanics publishes papers in four sections: Original Research, Reviews, Teaching, and Methods and Theoretical Perspectives.