Analysis of the worst-case scenarios in an elite football team: Towards a better understanding and application.
Andrew R NovakFranco M ImpellizzeriArjav TrivediAaron J CouttsAlan McCallPublished in: Journal of sports sciences (2021)
This study investigated the variability in the worst-case scenario (WCS) and suggested a framework to improve the definition and guide further investigation. Optical tracking data from 26 male players across 38 matches were analysed to determine the WCS for total distance, high-speed running (>5.5 m.s-1) and sprinting (>7.0 m.s-1) using a 3-minute rolling window. Position, total output, previous epoch, match half, time of occurrence, classification of starter vs substitute, and minutes played were modelled as selected contextual factors hypothesized to have associations with the WCS. Linear mixed effects models were used to account for cross-sectional observations and repeated measures. Unexplained variance remained high (total distance R2 = 0.53, high-speed running R2 = 0.53 and sprinting R2 = 0.40). Intra-individual variability was also high (total distance CV = 4.6-8.2%; high-speed CV = 15.6-37.8% and Sprinting CV = 21.1-76.4%). The WCS defined as the maximal physical load in a given time-window, produces unstable metrics lacking context, with high variability. Furthermore, training drills targetting this metric concurrently across players may not have representative designs and may underprepare athletes for complete match demands and multifaceted WCS scenarios. Using WCS as benchmarks (reproducing similar physical activity for training purposes) is conceptually questionable.
Keyphrases
- high speed
- atomic force microscopy
- physical activity
- cross sectional
- high resolution
- climate change
- risk assessment
- machine learning
- high intensity
- palliative care
- high school
- heart rate
- body composition
- quality improvement
- deep learning
- artificial intelligence
- big data
- virtual reality
- resistance training
- mass spectrometry
- blood pressure