Prediction Equations for Marathon Performance: A Systematic Review

in International Journal of Sports Physiology and Performance
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Purpose: Despite the volume of available literature focusing on marathon running and the prediction of performance, no single prediction equations exists that is accurate for all runners of varying experiences and abilities. Indeed the relative merits and utility of the existing equations remain unclear. Thus, the aim of this study was to collate, characterize, compare, and contrast all available marathon prediction equations. Methods: A systematic review was conducted to identify observational research studies outlining any kind of prediction algorithm for marathon performance. Results: Thirty-six studies with 114 equations were identified. Sixty-one equations were based on training and anthropometric variables, whereas 53 equations included variables that required laboratory tests and equipment. The accuracy of these equations was denoted via a variety of metrics; r2 values were provided for 68 equations (r2 = .10–.99), and an SEE was provided for 19 equations (SEE 0.27–27.4 min). Conclusion: Heterogeneity of the data precludes the identification of a single “best” equation. Important variables such as course gradient, sex, and expected weather conditions were often not included, and some widely used equations did not report the r2 value. Runners should therefore be wary of relying on a single equation to predict their performance.

All authors are with the Insight Centre for Data Analytics; Keogh, Caulfield, and Doherty, the School of Public Health, Physiotherapy and Sports Science; and Smyth, Lawlor, and Berndsen, the School of Computer Science, University College Dublin, Dublin, Ireland.

Keogh (Alison.keogh@insight-centre.org) is corresponding author.

Supplementary Materials

    • Supplementary Material (PDF 341 KB)