The goal of this research was to examine the accuracy of three methods used to indicate the hip joint center (HJC) in seated steady-state cycling. Two of the methods have been used in previous studies of cycling biomechanics and included tracking a marker placed over the superior aspect of the greater trochanter, a location that estimates the center of rotation of the hip joint, and assuming that the hip is fixed. The third method was new and utilized an anthropometric relationship to determine the hip joint location from a marker placed over the anterior-superior iliac spine. To perform a comparative analysis of errors inherent in the three methods, a standard method which located the true hip joint center was developed. The standard method involved establishing a pelvis-fixed coordinate system using a triad of video markers attached to an intracortical pin. Three-dimensional motion analysis quantified the true hip joint center position coordinates. To provide data for the comparative analysis, the intracortical pin was anchored to a single subject who pedaled at nine cadence-workrate combinations while data for all four methods were simultaneously recorded. At all cadence-workrate combinations the new method was more accurate than the trochanter method with movement errors lower by a factor of 2 in the vertical direction and a factor of 3 in the horizontal direction. Relative to the errors introduced by the fixed hip assumption, the new method was also generally more accurate by at least a factor of 2 in the horizontal direction and had comparable accuracy in the vertical direction. For computed kinetic quantities, the new method most accurately indicated hip joint force power but the fixed hip method most accurately indicated the work produced by the hip joint force over the crank cycle.
[1]
S. Aleshinsky.
An energy 'sources' and 'fractions' approach to the mechanical energy expenditure problem--II. Movement of the multi-link chain model.
,
1986,
Journal of biomechanics.
[2]
Maury L. Hull,et al.
The Effect of Pedal Platform Height on Cycling Biomechanics
,
1990
.
[3]
J. Hagberg,et al.
Effect of pedaling rate on submaximal exercise responses of competitive cyclists.
,
1981,
Journal of applied physiology: respiratory, environmental and exercise physiology.
[4]
M L Hull,et al.
A mechanically decoupled two force component bicycle pedal dynamometer.
,
1988,
Journal of biomechanics.
[5]
P R Cavanagh,et al.
Knee flexor moments during propulsion in cycling--a creative solution to Lombard's Paradox.
,
1985,
Journal of biomechanics.
[6]
S Y Aleshinsky,et al.
An energy 'sources' and 'fractions' approach to the mechanical energy expenditure problem--I. Basic concepts, description of the model, analysis of a one-link system movement.
,
1986,
Journal of biomechanics.
[7]
R. Gregor,et al.
The biomechanics of cycling.
,
1991,
Exercise and sport sciences reviews.
[8]
M L Hull,et al.
A method for biomechanical analysis of bicycle pedalling.
,
1985,
Journal of biomechanics.