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Estimation of gait events and kinetic waveforms with wearable sensors and machine learning when running in an unconstrained environment.在非约束环境下跑步时,使用可穿戴传感器和机器学习估计步态事件和动力学波形。
Sci Rep. 2023 Feb 9;13(1):2339. doi: 10.1038/s41598-023-29314-4.
2
Comparison of different machine learning models to enhance sacral acceleration-based estimations of running stride temporal variables and peak vertical ground reaction force.比较不同机器学习模型以增强基于骶骨加速度的跑步步幅时间变量和垂直地面反作用力峰值估计。
Sports Biomech. 2023 Jan 6:1-17. doi: 10.1080/14763141.2022.2159870.
3
Impact of Gender and Feature Set on Machine-Learning-Based Prediction of Lower-Limb Overuse Injuries Using a Single Trunk-Mounted Accelerometer.基于单躯干安装加速度计的机器学习预测下肢过度使用损伤中性别和特征集的影响。
Sensors (Basel). 2022 Apr 8;22(8):2860. doi: 10.3390/s22082860.
4
A Single Sacral-Mounted Inertial Measurement Unit to Estimate Peak Vertical Ground Reaction Force, Contact Time, and Flight Time in Running.一种单骶骨安装的惯性测量单元,用于估计跑步时的峰值垂直地面反作用力、接触时间和腾空时间。
Sensors (Basel). 2022 Jan 20;22(3):784. doi: 10.3390/s22030784.
5
Lower step rate is associated with a higher risk of bone stress injury: a prospective study of collegiate cross country runners.较低的步频与更高的骨骼应力损伤风险相关:一项大学生越野跑运动员的前瞻性研究。
Br J Sports Med. 2021 Aug;55(15):851-856. doi: 10.1136/bjsports-2020-103833. Epub 2021 May 14.
6
Sacral acceleration can predict whole-body kinetics and stride kinematics across running speeds.骶骨加速度可以预测不同跑步速度下的全身动力学和步幅运动学。
PeerJ. 2021 Apr 12;9:e11199. doi: 10.7717/peerj.11199. eCollection 2021.
7
Accelerometer Based Data Can Provide a Better Estimate of Cumulative Load During Running Compared to GPS Based Parameters.与基于全球定位系统(GPS)的参数相比,基于加速度计的数据能更好地估算跑步过程中的累积负荷。
Front Sports Act Living. 2020 Oct 30;2:575596. doi: 10.3389/fspor.2020.575596. eCollection 2020.
8
A Scoping Review of the Relationship between Running and Mental Health.跑步与心理健康关系的范围综述。
Int J Environ Res Public Health. 2020 Nov 1;17(21):8059. doi: 10.3390/ijerph17218059.
9
Impact-Related Ground Reaction Forces Are More Strongly Associated With Some Running Injuries Than Others.与某些跑步损伤相比,与冲击相关的地面反作用力与其他损伤的关系更为密切。
Am J Sports Med. 2020 Oct;48(12):3072-3080. doi: 10.1177/0363546520950731. Epub 2020 Sep 11.
10
Predicting vertical ground reaction force during running using novel piezoresponsive sensors and accelerometry.利用新型压阻式传感器和加速度计预测跑步时的垂直地面反作用力。
J Sports Sci. 2020 Aug;38(16):1844-1858. doi: 10.1080/02640414.2020.1757361. Epub 2020 May 25.

利用机器学习预测跑步过程中的垂直地面反作用力特征。

Predicting vertical ground reaction force characteristics during running with machine learning.

作者信息

Bogaert Sieglinde, Davis Jesse, Vanwanseele Benedicte

机构信息

Human Movements Biomechanics Research Group, Department of Movement Sciences, KU Leuven, Leuven, Belgium.

Department of Computer Science, Leuven.AI, KU Leuven, Leuven, Belgium.

出版信息

Front Bioeng Biotechnol. 2024 Oct 8;12:1440033. doi: 10.3389/fbioe.2024.1440033. eCollection 2024.

DOI:10.3389/fbioe.2024.1440033
PMID:39439554
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11493597/
Abstract

Running poses a high risk of developing running-related injuries (RRIs). The majority of RRIs are the result of an imbalance between cumulative musculoskeletal load and load capacity. A general estimate of whole-body biomechanical load can be inferred from ground reaction forces (GRFs). Unfortunately, GRFs typically can only be measured in a controlled environment, which hinders its wider applicability. The advent of portable sensors has enabled training machine-learned models that are able to monitor GRF characteristics associated with RRIs in a broader range of contexts. Our study presents and evaluates a machine-learning method to predict the contact time, active peak, impact peak, and impulse of the vertical GRF during running from three-dimensional sacral acceleration. The developed models for predicting active peak, impact peak, impulse, and contact time demonstrated a root-mean-squared error of 0.080 body weight (BW), 0.198 BW, 0.0073 BW seconds, and 0.0101 seconds, respectively. Our proposed method outperformed a mean-prediction baseline and two established methods from the literature. The results indicate the potential utility of this approach as a valuable tool for monitoring selected factors related to running-related injuries.

摘要

跑步存在引发与跑步相关损伤(RRIs)的高风险。大多数RRIs是累积肌肉骨骼负荷与负荷能力之间失衡的结果。全身生物力学负荷的一般估计可以从地面反作用力(GRFs)推断得出。不幸的是,GRFs通常只能在受控环境中测量,这限制了其更广泛的应用。便携式传感器的出现使得能够训练机器学习模型,这些模型能够在更广泛的情境中监测与RRIs相关的GRF特征。我们的研究提出并评估了一种机器学习方法,用于从三维骶骨加速度预测跑步过程中垂直GRF的接触时间、主动峰值、冲击峰值和冲量。用于预测主动峰值、冲击峰值、冲量和接触时间的开发模型的均方根误差分别为0.080体重(BW)、0.198 BW、0.0073 BW秒和0.0101秒。我们提出的方法优于平均预测基线和文献中的两种既定方法。结果表明,这种方法作为监测与跑步相关损伤的选定因素的有价值工具具有潜在效用。