Development of a Twenty20 Field-Based Simulation for Cricket Fast Bowlers (FBS-T20)

Milne, Ethan C.; Vickery, Will M.; Dascombe, Ben J.; Borges, Nattai R.

Title: Development of a Twenty20 Field-Based Simulation for Cricket Fast Bowlers (FBS-T20)
Creator: Milne, Ethan C.; Vickery, Will M.; Dascombe, Ben J.; Borges, Nattai R.
Relation: Journal of Strength and Conditioning Research Vol. 36, Issue 10, p. 2905-2911
Publisher Link: http://dx.doi.org/10.1519/JSC.0000000000003912
Publisher: Lippincott Williams & Wilkins
Resource Type: journal article
Date: 2022
Description: This project assessed the validity and reliability of a novel Twenty20 cricket pace bowling simulation (FBS-T20) that could be used to facilitate match-specific testing and training outside of match play. Six recreational pace bowlers completed 3 identical sessions of the FBS-T20. The FBS-T20 consisted of 4 bowling and 16 fielding overs. During the bowling overs, a bowling accuracy test and bowling approach speed were measured, whereas during the fielding overs, 10-m sprint performance was assessed. Distance covered, heart rate (HR), and rating of perceived exertion (RPE) were also collected throughout the FBS-T20. Validity was determined through comparison with previously reported Twenty20 pace bowling match demands, and intersession reliabilities were assessed. Distances covered in speed zones were valid (p > 0.05) with the exception of significantly lower jog values in the FBS-T20 (957–1,279 vs. 2,195 m; p = 0.04-<0.001). The maximal HR was found to be valid, but the mean HR was significantly higher than previously published data (147–151 bpm vs. 133 bpm; p = 0.014–0.003). Distances covered demonstrated high levels of reliability, with increasing reliability found after additional sessions (coefficient of variation [CV]% = 3.8–14.4). The HR (CV% = 4.8–6.3) and session RPE (CV% = 10.8) demonstrated moderate reliability, whereas approach speed, 10-m sprint, and bowling skills test results possessed low levels of reliability. The FBS-T20 is a practically viable testing and training tool that is valid and reliable for distances covered at high speeds. One full familiarization session is recommended for optimal reliability.
Subject: time-motion analysis; validity; reliability; match simulation; physiological responses
Identifier: http://hdl.handle.net/1959.13/1474029
Identifier: uon:49185
Identifier: ISSN:1064-8011
Language: eng
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