Inertial-load method determines maximal cycling power in a single exercise bout

A cycle ergometer was modified to measure power (P) with resistance provided solely by the moment of inertia (I) of the flywheel. P was calculated as the product of I, angular velocity (omega), and angular acceleration (alpha). Flywheel omega and alpha were determined by means of an optical sensor and a micro-controller based computer interface which measured time (+/- 1 microsecond) and allowed P to be calculated instantaneously (P-I) every 3 degrees of pedal crank rotation or averaged over one complete revolution of the pedal cranks (P-REV). Values for maximum P were identified from each bout (P-I max and P-REV max). Mechanical calibration of torque via a resistive strap proved this method to be both valid and accurate. Thirteen active male subjects performed four bouts of maximal acceleration lasting approximately 3-4 s with 2 min resting recovery. The mean coefficient of variation for P-REV max was 3.3 +/- 0.6% and the intraclass correlation was 0.99. P-REV max averaged 1317 +/- 66 W at 122 +/- 2 rpm, and P-I max averaged 2137 +/- 101 W at 131 +/- 2 rpm. P-REV max and P-I max were highly correlated (r = 0.86 and r = 0.80 respectively, P < 0.002) with estimated lean thigh volume. Therefore, the inertial-load method provides a valid and reliable determination of cycling power in one short exercise bout.