A New Pathway to Approximate Energy Expenditure and Recovery of an Athlete
This work addresses the challenge of personalizing performance models for athletes, but it appears incremental as it builds on an existing theoretical concept without demonstrating broad impact.
The paper tackles the problem of modeling an individual athlete's energy expenditure and recovery by introducing a generalized interpretation of the three component hydraulic model, which removes dependencies on precise physiological measures and uses evolutionary computation for parameter fitting, though no concrete numerical results are provided.
This work proposes to use evolutionary computation as a pathway to allow a new perspective on the modeling of energy expenditure and recovery of an individual athlete during exercise. We revisit a theoretical concept called the "three component hydraulic model" which is designed to simulate metabolic systems during exercise and which is able to address recently highlighted shortcomings of currently applied performance models. This hydraulic model has not been entirely validated on individual athletes because it depends on physiological measures that cannot be acquired in the required precision or quantity. This paper introduces a generalized interpretation and formalization of the three component hydraulic model that removes its ties to concrete metabolic measures and allows to use evolutionary computation to fit its parameters to an athlete.