The mechanics of sprint running

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The mechanics of sprint running

Giovanni A. Cavagna, L. Komarek and Stefania Mazzoleni

1. The effect of the velocity of shortening on the power developedby the muscles in sprint running was studied by measuring themechanical work done to accelerate the body forward from thestart to about 34 km/hr.

2. The work was measured at each step from the data obtainedby means of a platform sensitive to the force impressed by thefoot.

3. Almost the totality of the positive work done during thefirst second from the start is found as an increase of the kineticenergy of the body. However, as the speed of the run rises,air resistance and particularly the deceleration of the bodyforward, taking place at each step, rapidly increase, limitingthe speed of the run.

4. The average power developed by the muscles during the pushat each step increases with the velocity of running reaching3-4 h.p. at the maximal speed attained.

5. At low speed the contractile component of the muscles seemsto be mainly responsible for the power output, whereas at highspeed (25-34 km/hr) an appreciable fraction of the power appearsto be sustained by the mechanical energy stored in the `serieselastic elements' during stretching the contracted muscles (negativework) and released immediately after in the positive work phase.

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