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Understanding the track and field sprint start through a functional analysis of the external force features which contribute to higher levels of block phase performance
Neil Bezodis 
,
Sean Walton ,
Ryu Nagahara
,
Sean Walton ,
Ryu Nagahara
Journal of Sports Sciences, Volume: 37, Issue: 5, Pages: 560 - 567
Swansea University Authors:
Neil Bezodis , Sean Walton
-
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DOI (Published version): 10.1080/02640414.2018.1521713
Abstract
This study aimed to identify the continuous ground reaction force (GRF) features which contribute to higher levels of block phase performance. Twenty-three sprint-trained athletes completed starts from their preferred settings during which GRFs were recorded separately under each block. Continuous f...
| Published in: | Journal of Sports Sciences |
|---|---|
| ISSN: | 0264-0414 1466-447X |
| Published: |
2019
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| URI: | https://cronfa.swan.ac.uk/Record/cronfa43730 |
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2020-07-08T14:26:06.5486382 v2 43730 2018-09-07 Understanding the track and field sprint start through a functional analysis of the external force features which contribute to higher levels of block phase performance 534588568c1936e94e1ed8527b8c991b 0000-0003-2229-3310 Neil Bezodis Neil Bezodis true false 0ec10d5e3ed3720a2d578417a894cf49 0000-0002-6451-265X Sean Walton Sean Walton true false 2018-09-07 STSC This study aimed to identify the continuous ground reaction force (GRF) features which contribute to higher levels of block phase performance. Twenty-three sprint-trained athletes completed starts from their preferred settings during which GRFs were recorded separately under each block. Continuous features of the magnitude and direction of the resultant GRF signals which explained 90% of the variation between the sprinters were identified. Each sprinter’s coefficient score for these continuous features was then input to a linear regression model to predict block phase performance (normalised external power). Four significant (p < 0.05) predictor features associated with GRF magnitude were identified; there were none associated with GRF direction. A feature associated with greater rear block GRF magnitudes from the onset of the push was the most important predictor (β = 1.185), followed by greater front block GRF magnitudes for the final three-quarters of the push (β = 0.791). Features which included a later rear block exit (β = 0.254) and greater front leg GRF magnitudes during the mid-push phase (β = 0.224) were also significant predictors. Sprint practitioners are encouraged, where possible, to consider the continuous magnitude of the GRFs produced throughout the block phase in addition to selected discrete values. Journal Article Journal of Sports Sciences 37 5 560 567 0264-0414 1466-447X 31 12 2019 2019-12-31 10.1080/02640414.2018.1521713 COLLEGE NANME Sport and Exercise Sciences COLLEGE CODE STSC Swansea University 2020-07-08T14:26:06.5486382 2018-09-07T09:25:16.1988600 Faculty of Science and Engineering School of Engineering and Applied Sciences - Uncategorised Neil Bezodis 0000-0003-2229-3310 1 Sean Walton 0000-0002-6451-265X 2 Ryu Nagahara 3 0043730-07092018092656.pdf bezodis2018(2).pdf 2018-09-07T09:26:56.4770000 Output 736549 application/pdf Accepted Manuscript true 2019-10-11T00:00:00.0000000 true eng |
| title |
Understanding the track and field sprint start through a functional analysis of the external force features which contribute to higher levels of block phase performance |
| spellingShingle |
Understanding the track and field sprint start through a functional analysis of the external force features which contribute to higher levels of block phase performance Neil Bezodis Sean Walton |
| title_short |
Understanding the track and field sprint start through a functional analysis of the external force features which contribute to higher levels of block phase performance |
| title_full |
Understanding the track and field sprint start through a functional analysis of the external force features which contribute to higher levels of block phase performance |
| title_fullStr |
Understanding the track and field sprint start through a functional analysis of the external force features which contribute to higher levels of block phase performance |
| title_full_unstemmed |
Understanding the track and field sprint start through a functional analysis of the external force features which contribute to higher levels of block phase performance |
| title_sort |
Understanding the track and field sprint start through a functional analysis of the external force features which contribute to higher levels of block phase performance |
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534588568c1936e94e1ed8527b8c991b 0ec10d5e3ed3720a2d578417a894cf49 |
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534588568c1936e94e1ed8527b8c991b_***_Neil Bezodis 0ec10d5e3ed3720a2d578417a894cf49_***_Sean Walton |
| author |
Neil Bezodis Sean Walton |
| author2 |
Neil Bezodis Sean Walton Ryu Nagahara |
| format |
Journal article |
| container_title |
Journal of Sports Sciences |
| container_volume |
37 |
| container_issue |
5 |
| container_start_page |
560 |
| publishDate |
2019 |
| institution |
Swansea University |
| issn |
0264-0414 1466-447X |
| doi_str_mv |
10.1080/02640414.2018.1521713 |
| college_str |
Faculty of Science and Engineering |
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facultyofscienceandengineering |
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Faculty of Science and Engineering |
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facultyofscienceandengineering |
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Faculty of Science and Engineering |
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School of Engineering and Applied Sciences - Uncategorised{{{_:::_}}}Faculty of Science and Engineering{{{_:::_}}}School of Engineering and Applied Sciences - Uncategorised |
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| description |
This study aimed to identify the continuous ground reaction force (GRF) features which contribute to higher levels of block phase performance. Twenty-three sprint-trained athletes completed starts from their preferred settings during which GRFs were recorded separately under each block. Continuous features of the magnitude and direction of the resultant GRF signals which explained 90% of the variation between the sprinters were identified. Each sprinter’s coefficient score for these continuous features was then input to a linear regression model to predict block phase performance (normalised external power). Four significant (p < 0.05) predictor features associated with GRF magnitude were identified; there were none associated with GRF direction. A feature associated with greater rear block GRF magnitudes from the onset of the push was the most important predictor (β = 1.185), followed by greater front block GRF magnitudes for the final three-quarters of the push (β = 0.791). Features which included a later rear block exit (β = 0.254) and greater front leg GRF magnitudes during the mid-push phase (β = 0.224) were also significant predictors. Sprint practitioners are encouraged, where possible, to consider the continuous magnitude of the GRFs produced throughout the block phase in addition to selected discrete values. |
| published_date |
2019-12-31T03:55:03Z |
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1763752755978043392 |
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11.017797 |