THE CRITICAL POWER CONCEPT - A REVIEW

被引：309

作者：

HILL, DW

机构：

[1] Exercise Physiology Laboratory, Department of Kinesiology, University of North Texas, Denton, Texas, 76203-3857

来源：

SPORTS MEDICINE | 1993年 / 16卷 / 04期

关键词：

D O I：

10.2165/00007256-199316040-00003

中图分类号：

G8 [体育];

学科分类号：

04 ; 0403 ;

摘要：

The basis of the critical power concept is that there is a hyperbolic relationship between power output and the time that the power output can be sustained. The relationship can be described based on the results of a series of 3 to 7 or more timed all-out predicting trials. Theoretically, the power asymptote of the relationship, CP (critical power), can be sustained without fatigue; in fact, exhaustion occurs after about 30 to 60 minutes of exercise at CP. Nevertheless, CP is related to the fatigue threshold, the ventilatory and lactate thresholds, and maximum oxygen uptake (VO2max), and it provides a measure of aerobic fitness. The second parameter of the relationship, AWC (anaerobic work capacity), is related to work performed in a 30-second Wingate test, work in intermittent high-intensity exercise, and oxygen deficit, and it provides a measure of anaerobic capacity. The accuracy of the parameter estimates may be enhanced by careful selection of the power outputs for the predicting trials and by performing a greater number of trials. These parameters provide fitness measures which are mode-specific, combine energy production and mechanical efficiency in 1 variable, and do not require the use of expensive equipment or invasive procedures. However, the attractiveness of the critical power concept diminishes if too many predicting trials are required for generation of parameter estimates with a reasonable degree of accuracy.

引用

页码：237 / 254

页数：18

共 57 条

[1]

Bar-Or O., The Wingate anaerobic test: an update on methodology, reliability, and validity, Sports Medicine, 4, pp. 381-394, (1987)

[2]

Bulbalian R., Wilcox A.R., Darabos B.L., Anaerobic contribution to distance running performance of trained cross-country athletes, Medicine and Science in Sports and Exercise, 18, pp. 107-113, (1986)

[3]

Carnevale T.J., Gaesser G.A., Effects of pedaling speed on the power-duration relationship for high-intensity exercise, Medicine and Science in Sports and Exercise, 23, pp. 242-246, (1991)

[4]

Coast J.R., Welch H.G., Linear increase in optimal pedal rate with increased power output in cycle ergometry, European Journal of Applied Physiology and Occupational Physiology, 53, pp. 339-342, (1985)

[5]

deVries H.A., Moritani T., Nagata A., Magnussen K., The relation between critical power and neuromuscular fatigue as estimated from electromyographic data, Ergonomics, 25, pp. 783-791, (1982)

[6]

deVries H.A., Tichy M.W., Housh T.J., Smyth K.D., Tichy A.M., Et al., A method for estimating physical working capacity at the fatigue threshold (PWC<sub>FT</sub>), Ergonomics, 30, pp. 1195-1204, (1987)

[7]

Gaesser G.A., Brooks G.A., Muscular efficiency during steady-rate exercise: effects of speed and work rate, Journal of Applied Physiology, 38, pp. 1132-1139, (1975)

[8]

Gaesser G.A., Carnevale T.J., Garfinkel A., Walter D.O., Modeling of the power-endurance relationship for high-intensity exercise. Abstract, Medicine and Science in Sports and Exercise, 22, (1990)

[9]

Gaesser G.A., Wilson L.A., Effects of continuous and interval training on the parameters of the power-endurance time relationship for high-intensity exercise, International Journal of Sports Medicine, 9, pp. 417-421, (1988)

[10]

Ginn E.M., Mackinnon L.T., The equivalence of onset of blood lactate accumulation, critical power and maximal lactate steady state during kayak ergometry. Abstract, (1989)

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