Welsh Rugby Union, United Kingdom; School of Exercise Science, Australian Catholic University, Australia.
Gabbett Performance Solutions, Australia; University of Southern Queensland, Institute for Resilient Regions, Australia.
J Sci Med Sport. 2019 Jul;22(7):827-832. doi: 10.1016/j.jsams.2019.01.001. Epub 2019 Jan 6.
To automate the detection of ruck and tackle events in rugby union using a specifically-designed algorithm based on microsensor data.
Cross-sectional study.
Elite rugby union players wore microtechnology devices (Catapult, S5) during match-play. Ruck (n=125) and tackle (n=125) event data was synchronised with video footage compiled from international rugby union match-play ruck and tackle events. A specifically-designed algorithm to detect ruck and tackle events was developed using a random forest classification model. This algorithm was then validated using 8 additional international match-play datasets and video footage, with each ruck and tackle manually coded and verified if the event was correctly identified by the algorithm.
The classification algorithm's results indicated that all rucks and tackles were correctly identified during match-play when 79.4±9.2% and 81.0±9.3% of the random forest decision trees agreed with the video-based determination of these events. Sub-group analyses of backs and forwards yielded similar optimal confidence percentages of 79.7% and 79.1% respectively for rucks. Sub-analysis revealed backs (85.3±7.2%) produced a higher algorithm cut-off for tackles than forwards (77.7±12.2%).
The specifically-designed algorithm was able to detect rucks and tackles for all positions involved. For optimal results, it is recommended that practitioners use the recommended cut-off (80%) to limit false positives for match-play and training. Although this algorithm provides an improved insight into the number and type of collisions in which rugby players engage, this algorithm does not provide impact forces of these events.
使用专门设计的基于微传感器数据的算法,自动检测橄榄球中的争球和擒抱事件。
横断面研究。
精英橄榄球运动员在比赛中佩戴微技术设备(Catapult,S5)。争球(n=125)和擒抱(n=125)事件数据与来自国际橄榄球比赛争球和擒抱事件的视频片段同步。使用随机森林分类模型开发了专门设计的算法来检测争球和擒抱事件。然后,使用 8 个额外的国际比赛数据集和视频片段验证该算法,对每个争球和擒抱进行手动编码,并验证算法是否正确识别了事件。
分类算法的结果表明,在比赛中,当 79.4±9.2%和 81.0±9.3%的随机森林决策树与基于视频的这些事件确定一致时,所有争球和擒抱都被正确识别。对后锋和前锋的亚组分析分别得出了 79.7%和 79.1%的最佳置信百分比。亚分析显示,后锋(85.3±7.2%)的算法截点高于前锋(77.7±12.2%)的截点。
专门设计的算法能够检测所有参与位置的争球和擒抱。为了获得最佳结果,建议从业者使用推荐的截点(80%)来限制比赛和训练中的假阳性。尽管该算法提供了对橄榄球运动员参与的碰撞次数和类型的更深入了解,但该算法不提供这些事件的冲击力量。
