Comparing Cycling World Hour Records, 1967-1996: Modeling with Empirical Data

Overview

Journal Med Sci Sports Exerc

Specialty Orthopedics

Date 1999 Dec 10

PMID 10589872

Citations 20

Authors

D R Bassett Jr

C R Kyle

L Passfield

J P Broker

E R Burke

Affiliations

Soon will be listed here.

Abstract

Purpose: The world hour record in cycling has increased dramatically in recent years. The present study was designed to compare the performances of former/current record holders, after adjusting for differences in aerodynamic equipment and altitude. Additionally, we sought to determine the ideal elevation for future hour record attempts.

Methods: The first step was constructing a mathematical model to predict power requirements of track cycling. The model was based on empirical data from wind-tunnel tests, the relationship of body size to frontal surface area, and field power measurements using a crank dynamometer (SRM). The model agreed reasonably well with actual measurements of power output on elite cyclists. Subsequently, the effects of altitude on maximal aerobic power were estimated from published research studies of elite athletes. This information was combined with the power requirement equation to predict what each cyclist's power output would have been at sea level. This allowed us to estimate the distance that each rider could have covered using state-of-the-art equipment at sea level. According to these calculations, when racing under equivalent conditions, Rominger would be first, Boardman second, Merckx third, and Indurain fourth. In addition, about 60% of the increase in hour record distances since Bracke's record (1967) have come from advances in technology and 40% from physiological improvements.

Results And Conclusions: To break the current world hour record, field measurements and the model indicate that a cyclist would have to deliver over 440 W for 1 h at sea level, or correspondingly less at altitude. The optimal elevation for future hour record attempts is predicted to be about 2500 m for acclimatized riders and 2000 m for unacclimatized riders.

Citing Articles

Biophysical characterization of the first ultra-cyclist in the world to break the 1,000 km barrier in 24-h non-stop road cycling: A case report.

Knechtle B, Forte P, Weiss K, Cuk I, Nikolaidis P, Sousa C Front Cardiovasc Med. 2022; 9:990382.

PMID: 36304551 PMC: 9592711. DOI: 10.3389/fcvm.2022.990382.

Influence and Mechanisms of Action of Environmental Stimuli on Work Near and Above the Severe Domain Boundary (Critical Power).

Richard N, Koehle M Sports Med Open. 2022; 8(1):42.

PMID: 35347469 PMC: 8960528. DOI: 10.1186/s40798-022-00430-1.

Power profiling and the power-duration relationship in cycling: a narrative review.

Leo P, Spragg J, Podlogar T, Lawley J, Mujika I Eur J Appl Physiol. 2021; 122(2):301-316.

PMID: 34708276 PMC: 8783871. DOI: 10.1007/s00421-021-04833-y.

The Effect of Cleat Position on Running Using Acceleration-Derived Data in the Context of Triathlons.

Evans S, James D, Rowlands D, Lee J Sensors (Basel). 2021; 21(17).

PMID: 34502790 PMC: 8433942. DOI: 10.3390/s21175899.

Improving biologic predictors of cycling endurance performance with near-infrared spectroscopy derived measures of skeletal muscle respiration: E pluribus unum.

Batterson P, Norton M, Hetz S, Rohilla S, Lindsay K, Subudhi A Physiol Rep. 2020; 8(2):e14342.

PMID: 31960629 PMC: 6971325. DOI: 10.14814/phy2.14342.