Two Body Dynamic Model for Speed Skating Driven by the Skaters Leg Extension

E. van der Kruk; H. E. J. Veeger; F. C. T. van der Helm; A. L. Schwab

Two Body Dynamic Model for Speed Skating Driven by the Skaters Leg Extension

E. van der Kruk, H. E. J. Veeger, F. C. T. van der Helm, A. L. Schwab

2015

Abstract

In speed skating forces are generated by pushing in a sideward direction against an environment, which moves relative to the skater. There is a distinct difference in the coordination pattern among (elite) speed skaters. Models can help to give insight in this peculiar skating technique and ideally find an optimal motion pattern for each individual speed skater. The objectives of this study are to present a verified three dimensional inverse skater model with minimal complexity, modelling the speed skating motion on the straights. The model is driven by the changing distance between the torso and the skate , which is also the true input of the skater to generate a global motion. Additionally this input, which is indirectly also a measure of the knee extension of the skater, is a variable familiar to the speed skaters and coaches. In this extended abstract we verify this novel model for two strokes (left and right) of one skater through correlation with observed kinematics and forces. Preliminary results presented show that the model, despite the simplicity, was able to simulate the upper body movement accurately, while The forces on the skate were underestimated.

References

Allinger, T.L. & Bogert, A.J., 1997. Skating technique for the straights based on the optimization of a simulation study. Medicine and Science in Sports and Exercise, 29, pp.279-286.
Cabrera, D., Ruina, A. & Kleshnev, V., 2006. A simple 1+ dimensional model of rowing mimics observed forces and motions. Human Movement Science, 25(2), pp.192-220.
Van Ingen Schenau, G.J., 1982. The influence of air friction in speed skating. Journal of Biomechanics, 15(6), pp.449-458.
De Koning, J.J. et al., 1987. Push-Off Force in Speed Skating. , pp.103-109.
De Koning, J.J., De Groot, G. & Van Ingen Schenau, G.J., 1992. Ice friction during speed skating. Journal of Biomechanics, 25(6), pp.565-571.
Van der Kruk, E. et al., (submitted) 2015. wireless instrumented klapskates for speed skating,submitted Otten, E., 2003. Inverse and forward dynamics: models of multi-body systems. Phil. Trans. R. Soc. Lond., pp.1493-1500.

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Paper Citation

in Harvard Style

van der Kruk E., E. J. Veeger H., C. T. van der Helm F. and Schwab A. (2015). Two Body Dynamic Model for Speed Skating Driven by the Skaters Leg Extension . In - icSPORTS, ISBN , pages 0-0

in Bibtex Style

@conference{icsports15,
author={E. van der Kruk and H. E. J. Veeger and F. C. T. van der Helm and A. L. Schwab},
title={Two Body Dynamic Model for Speed Skating Driven by the Skaters Leg Extension},
booktitle={ - icSPORTS,},
year={2015},
pages={},
publisher={SciTePress},
organization={INSTICC},
doi={},
isbn={},
}

in EndNote Style

TY - CONF
JO - - icSPORTS,
TI - Two Body Dynamic Model for Speed Skating Driven by the Skaters Leg Extension
SN -
AU - van der Kruk E.
AU - E. J. Veeger H.
AU - C. T. van der Helm F.
AU - Schwab A.
PY - 2015
SP - 0
EP - 0
DO -