This paper presents the analysis, design and experimental results of a development program for a robotic leg to be used to kick soccer balls to evaluate new shoe and ball designs for the sport of soccer. The motivation is to be seen in the ability to reproduce and vary kicks reliably to allow more accurate evaluation of new shoe and ball designs without the use of extensive human-kick data sets, statistical evaluations and unquantifiable and unknown experimental errors. The leg was designed with a combination of active and spring-assisted actuator modules to allow the leg to transfer momentum to a soccer ball to achieve take-off speeds of up to 40 m/sec. A removable foot allows for testing of various shoes. Preliminary experimental results have shown that the ball can be kicked with enough range and spin to hit inside the upper corners of a goal at a distance of 20 m and a height of 2.5 m with an accuracy of +/- one ball diameter (0.25 m), with a maximum range of 40 m.
[1]
Arkady S. Voloshin,et al.
Dynamic loading on flamenco dancers: A biomechanical study
,
1989
.
[2]
G A Arangio,et al.
The foot as a shock absorber.
,
1990,
Journal of biomechanics.
[3]
A S Voloshin.
Shock absorption during running and walking.
,
1988,
Journal of the American Podiatric Medical Association.
[4]
G A Arangio,et al.
An application of beam theory to determine the stress and deformation of long bones.
,
1989,
Journal of biomechanics.
[5]
G A Arangio,et al.
A biomechanical model of the foot.
,
1986,
Journal of biomechanics.
[6]
Marc H. Raibert,et al.
Legged Robots That Balance
,
1986,
IEEE Expert.
[7]
S. Plagenhoef,et al.
Patterns of human motion;: A cinematographic analysis
,
1971
.