建立高于无氧阈功率的运动能力消耗和恢复模型。

Modeling the expenditure and reconstitution of work capacity above critical power.

机构信息

Department of Sport and Health Sciences, College of Life and Environmental Sciences, St. Luke's Campus, University of Exeter, Exeter, Devon, United Kingdom.

出版信息

Med Sci Sports Exerc. 2012 Aug;44(8):1526-32. doi: 10.1249/MSS.0b013e3182517a80.

DOI:10.1249/MSS.0b013e3182517a80

PMID:22382171

Abstract

PURPOSE

The critical power (CP) model includes two constants: the CP and the W' [P = (W' / t) + CP]. The W' is the finite work capacity available above CP. Power output above CP results in depletion of the W' complete depletion of the W' results in exhaustion. Monitoring the W' may be valuable to athletes during training and competition. Our purpose was to develop a function describing the dynamic state of the W' during intermittent exercise.

METHODS

After determination of V˙O(2max), CP, and W', seven subjects completed four separate exercise tests on a cycle ergometer on different days. Each protocol comprised a set of intervals: 60 s at a severe power output, followed by 30-s recovery at a lower prescribed power output. The intervals were repeated until exhaustion. These data were entered into a continuous equation predicting balance of W' remaining, assuming exponential reconstitution of the W'. The time constant was varied by an iterative process until the remaining modeled W' = 0 at the point of exhaustion.

RESULTS

The time constants of W' recharge were negatively correlated with the difference between sub-CP recovery power and CP. The relationship was best fit by an exponential (r = 0.77). The model-predicted W' balance correlated with the temporal course of the rise in V˙O(2) (r = 0.82-0.96). The model accurately predicted exhaustion of the W' in a competitive cyclist during a road race.

CONCLUSIONS

We have developed a function to track the dynamic state of the W' during intermittent exercise. This may have important implications for the planning and real-time monitoring of athletic performance.

摘要

目的

临界功率（CP）模型包含两个常数：CP 和 W'[P = (W' / t) + CP]。W' 是 CP 以上的有限工作能力。CP 以上的功率输出会导致 W' 的消耗，W' 的完全消耗会导致衰竭。在训练和比赛期间，监测 W' 可能对运动员有价值。我们的目的是开发一个描述间歇运动中 W' 动态状态的函数。

方法

在确定最大摄氧量（V˙O(2max)）、CP 和 W' 后，7 名受试者在不同天在自行车测力计上完成了四项单独的运动测试。每个方案包括一组间隔：60 秒在严重的功率输出下，然后在较低的规定功率输出下恢复 30 秒。间隔重复，直到衰竭。这些数据被输入到一个连续方程中，假设 W' 剩余的平衡是指数重建的，以预测 W' 剩余的平衡。通过迭代过程改变时间常数，直到在衰竭点模型化的剩余 W' = 0。

结果

W' 再充电的时间常数与亚 CP 恢复功率和 CP 之间的差值呈负相关。该关系通过指数（r = 0.77）最佳拟合。模型预测的 W' 平衡与 V˙O(2)上升的时间过程相关（r = 0.82-0.96）。该模型准确预测了在公路比赛中一名竞技自行车运动员的 W' 衰竭。

结论

我们已经开发了一种在间歇运动中跟踪 W' 动态状态的函数。这可能对运动表现的计划和实时监测有重要意义。

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建立高于无氧阈功率的运动能力消耗和恢复模型。

Modeling the expenditure and reconstitution of work capacity above critical power.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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