A foot and footwear mechanical power theoretical framework: Towards understanding energy storage and return in running footwear

Abstract

There is extreme interest surrounding the influence of advanced running footwear on running performance. The magnitude, timing, and location of mechanical energy storage and return in footwear may elucidate one way footwear influences running performance. However, the complexity of footwear makes it challenging to model footwear energy storage and return during running. The purpose of this study was to develop a practical framework for evaluating foot and footwear mechanical power profiles during running. First, a unified deformable power analysis (distal rearfoot power) was used to quantify mechanical power of the foot + footwear system. Then, qualitative mechanical power profiles of individual foot and footwear structure were developed using prior literature, benchtop footwear material properties, and experimental kinetics and kinematics. The result is a framework for understanding foot and footwear mechanical power during running using a two-stage analysis. First, foot + footwear power can be experimentally compared when running in various footwear constructions. Second, the developed framework can provide qualitative insights into which foot and footwear structures may contribute to differences in measured foot + footwear power. To highlight the utility of this framework, the timing, magnitude, and location of foot + footwear power is compared when running in different footwear constructions and with different running styles. The framework developed here provides a practical tool for footwear developers and researchers to gain intuition about the timing, relative magnitude, and location of energy storage and return from footwear during running. There are opportunities to expand on this framework to further connect footwear construction to running performance.