Abstract
A large number of power meters have become commercially available during the last decades to provide power output (PO) measurement. Some of these power meters were evaluated for validity in the literature. This study aimed to perform a review of the available literature on the validity of cycling power meters. PubMed, SPORTDiscus, and Google Scholar have been explored with PRISMA methodology. A total of 74 studies have been extracted for the reviewing process. Validity is a general quality of the measurement determined by the assessment of different metrological properties: Accuracy, sensitivity, repeatability, reproducibility, and robustness. Accuracy was most often studied from the metrological property (74 studies). Reproducibility was the second most studied (40 studies) property. Finally, repeatability, sensitivity, and robustness were considerably less studied with only 7, 5, and 5 studies, respectively. The SRM power meter is the most used as a gold standard in the studies. Moreover, the number of participants was very different among them, from 0 (when using a calibration rig) to 56 participants. The PO tested was up to 1700 W, whereas the pedalling cadence ranged between 40 and 180 rpm, including submaximal and maximal exercises. Other exercise conditions were tested, such as torque, position, temperature, and vibrations. This review provides some caveats and recommendations when testing the validity of a cycling power meter, including all of the metrological properties (accuracy, sensitivity, repeatability, reproducibility, and robustness) and some exercise conditions (PO range, sprint, pedalling cadence, torque, position, participant, temperature, vibration, and field test).
Highlights
This review provides an exhaustive list of where manufacturers perform power output (PO) measurements, including the pedal(s) (e.g., Garmin Vector, PowerTap P1), crank arm(s) (e.g., Stages), spider crank (SRM), chainrings (e.g., PowerTap C1), chain (e.g., Polar S710), bottom bracket axle (e.g., Rotor, InPower), rear hub (e.g., PowerTap G3, MaxOne), home-trainers (e.g., CycleOps, Powerbeam, Wahoo, Elite), and ergometers (e.g., Monark, Lode)
From our point of view, it is important to investigate the validity of power meters by assessing five essential metrological properties
The main findings of this review show that various technology and heterogeneous protocols were reported among the studies, including different metrological properties, gold standard systems, statistical analyses, and exercise conditions
Summary
Power output (PO) [1] measurement during riding is an interesting method to quantify the intensity of exercise produced by cyclists or patients. This measurement is widely used in cycling during training and monitoring [2,3,4,5,6,7] to test or validate mathematical models [8,9,10,11,12,13,14,15,16,17,18], assess the physical potential of cyclists [19,20,21,22,23,24] or measure performance requirements in competitions [25,26,27,28,29,30,31]. It is not always easy to make the link between the statistical analyses and the metrological properties studied
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