Usain Bolt's Physics: Derivation Analysis

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SUMMARY

This discussion centers on the analysis of Usain Bolt's race equations, particularly the differential equation for power. Participants critique the oversimplification of the model, emphasizing that Bolt's top speed during the constant speed phase is primarily limited by his biomechanical and physiological constraints rather than external factors like wind resistance. The conversation references a paper published in the American Journal of Physics (AJP) and highlights the importance of understanding the balance between ground reaction force and running mechanics in sprinting performance.

PREREQUISITES
  • Understanding of differential equations in physics
  • Knowledge of biomechanics related to sprinting
  • Familiarity with ground reaction forces and their impact on running speed
  • Basic principles of aerodynamics as they relate to athletic performance
NEXT STEPS
  • Study the paper published in AJP on Usain Bolt's race equations
  • Learn about the biomechanics of sprinting, focusing on stride length and frequency
  • Explore the effects of ground reaction forces on sprint performance
  • Investigate the role of wind resistance in athletic performance, particularly in sprinting
USEFUL FOR

Physicists, sports scientists, coaches, and athletes interested in the mechanics of sprinting and the mathematical modeling of athletic performance.

kaleidoscope
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I found this derivation of Usain Bolt's race equations and would like to know your opinion regarding the analysis (especially the differential equation for the power). Is it oversimplified or just fine?



https://www.youtube.com/watch?v=http://www.youtube.com/watch?v=xLXbLWiN1rQ
 
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Not sure if I have time to sit through a 9-minute YouTube video, but you can check out this paper that was published in AJP on the same topic.

http://arxiv.org/abs/0911.1952

I think the paper is a lot more convenient to study from than the video.

Zz.
 
I don't know the math that well, but I do know running and the vid attributes Bolt's top end speed in the constant speed phase of the run, from 40 through 100 meters, as the result of an equilibrium between the ground reaction force moving him forward and wind resistance as a force to the rear. That's a crock. After 40 meters Bolt has physically reached his biomechanical and physiological limit in his ability to increase the two primary variables related to running speed: stride length and stride frequency. Wind resistance does have a small effect, but I guarantee that if Bolt was able to increase his stride frequency by any amount that would transfer directly to his speed. Wind resistance as a function of terminal velocity pertains to free falling objects or perhaps jet aircraft, but this analysis was done by a math geek and not an athletic coach.
 

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