ORIGINAL PAPER
Within- and between-session reliability of a pedal force system for power output and pedal force effectiveness measurements
1
La Trobe Rural Health School, La Trobe University, Bendigo, Australia
2
Sports Performance Research Institute New Zealand, Auckland University of Technology, Auckland, New Zealand
Submission date: 2019-04-30
Acceptance date: 2020-01-24
Publication date: 2020-04-18
Hum Mov. 2020;21(4):69-78
KEYWORDS
TOPICS
ABSTRACT
Purpose:
The study assessed within- and between-session reliability of power output (PO) and pedal force effectiveness and compared PO from the pedals with the Lode Excalibur cycle ergometer.
Methods:
Seventeen male cyclists performed 10 trials at 3 levels of PO (1.5, 2.5, and 3.5 W/kg) and 3 cadences (60, 80, and 100 rpm) in 2 sessions. Instrumented pedals and a portable motion tracking system were synchronized to collect pedal forces and 3D full body motion, respectively. PO and the index of effectiveness (IE) were compared within and between sessions for the pedals while PO was compared with the Lode Excalibur.
Results:
Good agreement was observed for PO within sessions whilst right and left pedal IEs were moderate. Betweensession reliability ranged from poor to good for PO measured from the pedals, and reliability for IE ranged from poor to good. Significant differences in PO were observed between the pedals and the Lode Excalibur ergometer (17–50 W).
Conclusions:
The customized system to measure pedal forces was reliable within a given session for measuring IE and PO but variability in data increased in the second session, potentially because of the repositioning of the motion tracking sensors. Validity in measuring PO from the pedals without the use of the crank encoder is questionable.
The study assessed within- and between-session reliability of power output (PO) and pedal force effectiveness and compared PO from the pedals with the Lode Excalibur cycle ergometer.
Methods:
Seventeen male cyclists performed 10 trials at 3 levels of PO (1.5, 2.5, and 3.5 W/kg) and 3 cadences (60, 80, and 100 rpm) in 2 sessions. Instrumented pedals and a portable motion tracking system were synchronized to collect pedal forces and 3D full body motion, respectively. PO and the index of effectiveness (IE) were compared within and between sessions for the pedals while PO was compared with the Lode Excalibur.
Results:
Good agreement was observed for PO within sessions whilst right and left pedal IEs were moderate. Betweensession reliability ranged from poor to good for PO measured from the pedals, and reliability for IE ranged from poor to good. Significant differences in PO were observed between the pedals and the Lode Excalibur ergometer (17–50 W).
Conclusions:
The customized system to measure pedal forces was reliable within a given session for measuring IE and PO but variability in data increased in the second session, potentially because of the repositioning of the motion tracking sensors. Validity in measuring PO from the pedals without the use of the crank encoder is questionable.
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