Phase-Specific Force and Time Predictors of Standing Long Jump Distance

in Journal of Applied Biomechanics

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John R. Harry Texas Tech University

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John Krzyszkowski Texas Tech University

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Luke D. Chowning Texas Tech University

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Kristof Kipp Texas Tech University
Marquette University

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DOI:
https://doi.org/10.1123/jab.2021-0093
Keywords:
ground reaction force; soccer; regression
First Published Online:
09 Jul 2021
In Print:
Volume 37: Issue 5
Page Range:
400–407
Restricted access

This study sought to identify potential predictors of standing long jump (SLJ) performance using force–time strategy metrics within the unloading, eccentric yielding, eccentric braking, and concentric phases. Fifteen National Collegiate Athletic Association division 1 male soccer players (19 [1] y, 1.81 [0.94] m, 80.3 [22.4] kg) performed 3 maximum-effort SLJs, while 3-dimensional ground reaction force (GRF) data were obtained. Regularized regression models were used to investigate associations between force–time strategy metrics and 2 metrics of SLJ performance (ie, jump distance and modified reactive strength index). Jump height and eccentric yielding time were the only predictors of jump distance that also demonstrated large correlations to jump distance. Anterior–posterior unloading yank, average concentric vertical force, and concentric phase duration were the only predictors of modified reactive strength index that also demonstrated large correlations to modified reactive strength index. To maximize SLJ distance in high-level soccer athletes, human performance practitioners could design interventions to drive changes in strategy to increase jump height and decrease eccentric yielding time. To improve SLJ explosiveness, interventions to drive changes in unloading and concentric force application and decrease concentric time could be emphasized. Importantly, unique variable combinations can be targeted when training for SLJ distance and explosiveness adaptations.

Harry, Krzyszkowski, and Chowning are with the Human Performance & Biomechanics Laboratory, Department of Kinesiology & Sport Management, Texas Tech University, Lubbock, TX, USA. Kipp is with the Motion Analysis and Biomechanics Laboratory, Department of Physical Therapy—Program in Exercise Science, Marquette University, Milwaukee, WI, USA.

Harry (john.harry@ttu.edu) is corresponding author.
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