Abstract
It has been reported that performance in cycling time-trials is enhanced when power
is varied in response to gradient although such a mechanical pacing strategy has never
been confirmed experimentally in the field. The aim of this study was, therefore,
to assess the efficacy of mechanical pacing by comparing a constant power strategy
of 255 W with a variable power strategy that averaged to 255 W over an undulating
time-trial course. 20 experienced cyclists completed 4 trials over a 4 km course with
2 trials at an average constant power of 253 W and 2 trials where power was varied
in response to gradient and averaged 260 W. Time normalised to 255 W was 411±31.1 s
for the constant power output trials and 399±29.5 s for the variable power output
trials. The variable power output strategy therefore reduced completion time by 12±8 s
(2.9%) which was significant (p<0.001). Participants experienced difficulty in applying a constant power strategy
over an undulating course which acted to reduce their time gain. It is concluded that
a variable power strategy can improve cycling performance in a field time-trial where
the gradient is not constant.
Key words
pacing - modeling - time-trial - cycling
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Correspondence
Patrick Cangley
University of Brighton
Chelsea School
Hillbrow
BN20 7SR Eastbourne
United Kingdom
Telefon: + 44/1372/273 163
Fax: + 44/1372/273 163
eMail: p.cangley@brighton.ac.uk
