Comparison of the Mathematics and Physics Models Fitting of Velocity Time-Dependent for Usain Bolt in the 100 Metres Sprint

Artit Hutem; Aunchana Chansrakaew; Tanaporn Sornchai; Supaporn Hutem

doi:10.4028/www.scientific.net/JBBBE.31.11

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Comparison of the Mathematics and Physics Models Fitting of Velocity Time-Dependent for Usain Bolt in the 100 Metres Sprint
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Comparison of the Mathematics and Physics Models Fitting of Velocity Time-Dependent for Usain Bolt in the 100 Metres Sprint

Abstract:

In this research paper, we will develop a theory about the mathematical and physics models for the velocity-time of Usain Bolt in the 100 metres sprint during the Beijing olympic games 2008, Berlin world championships in Athletics 2009, and London olympic in 2012. We will use data from Usain Bolt’s distance, velocity and time as shown in K. Mackata and M. Antti research study of Usain Bolt’s kinematic parameter and will analyze them using mathematical and physics models in order to formulate a theoretical equations showing the power vitality of the sprinter value and his speed endurance as well. We will also use the Introduction to Sport Biomechanics by Roger Bartlett (pp.83-92) which covers the study of the hypothetical center of mass velocity time-dependent. And the comparison of the applied force is time-dependent oscillator which are all obtained from the mathematical and physics models1 and the applied force is time-dependent oscillator in mathematical and physics models2 and the experimentation done by in figure (1)-(3)

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Journal of Biomimetics, Biomaterials and Biomedical Engineering Vol. 31

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Journal of Biomimetics, Biomaterials and Biomedical Engineering (Volume 31)

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11-21

DOI:

https://doi.org/10.4028/www.scientific.net/JBBBE.31.11

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Online since:

March 2017

Authors:

Artit Hutem*, Aunchana Chansrakaew, Tanaporn Sornchai, Supaporn Hutem

Keywords:

Kinematic Parameter, Mathematical Model, Physics Model, Sport Physics, Usain Bolt

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