Abstract
At running speeds less than about 13 km h–1 the freely chosen step frequency (f free) is lower than the frequency at which the mechanical power is minimized (f min). This dissociation between f free and f min was investigated by measuring mechanical power, metabolic energy expenditure and apparent natural frequency of the body’s bouncing system (f sist) during running at three given speeds with different step frequencies. The f free requires a mechanical power greater than that at f min mainly due to a larger vertical oscillation of the body at each step. Energy expenditure is minimal and the mechanical efficiency is maximal at f free. At a given speed, an increase in step frequency above f free results in an increase in energy expenditure despite a decrease in mechanical power. On the other hand, a decrease in step frequency below f free results in a larger increase in energy expenditure associated with an increase in mechanical power. When the step frequency is forced to values above or below f free, f sist is forced to change similarly by adjusting the stiffness of the bouncing system. However the best match between f sist and step frequency takes place only in proximity of f free (2.6–2.8 Hz). It is concluded that during running at speeds less than 13 km h–1 energy is saved by tuning step frequency to f sist, even if this requires a mechanical power larger than necessary.
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Received: 13 January 1997 / Received after revision: 7 April 1997 / Accepted: 28 May 1997
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Cavagna, G., Mantovani, M., Willems, P. et al. The resonant step frequency in human running. Pflügers Arch 434, 678–684 (1997). https://doi.org/10.1007/s004240050451
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DOI: https://doi.org/10.1007/s004240050451