Abstract
The function of the human leg during walking and running is complex. One issue is the segmented structure of the leg, which consists of thigh, shank and foot. The situation is further challenged by the parallel arrangement of muscles spanning a single or multiple leg joints. How is the leg function organized to make typical movements such as walking and running possible and easily accessible? In this paper, we review a number of biomechanical models based on the spring-mass model, which may help to better understand how compliant leg function can be used and properly adjusted to selected movement tasks. This includes the emergence and stabilization of walking and running patterns. One general characteristic of movements based on compliant leg function is the functional redundancy in the leg adjustment, i.e. at a given speed, walking or running can be achieved with different leg strategies. This principle of redundant leg adjustments fulfilling the same general goal of movement is a key for understanding the organization of human locomotion.
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References
Blickhan, R.: The spring-mass model for running and hopping. J. Biomech. 22, 1217–1227 (1989)
Bullimore, S.R., Burn, J.F.: Consequences of forward translation of the point of force application for the mechanics of running. J. Theor. Biol. 238, 211–219 (2006)
Bullimore, S.R., Burn, J.F.: Ability of the planar spring-mass model to predict mechanical parameters in running humans. J. Theor. Biol. 248, 686–695 (2007)
Cavagna, G.A., Saibene, F.P., Margaria, R.: Mechanical work in running. J. Appl. Physiol. 19, 249–256 (1964)
Cavagna, G.A.: The landing-take-off asymmetry in human running. J. Exp. Biol. 209, 4051–4060 (2006)
Geyer, H., Seyfarth, A., Blickhan, R.: Compliant leg behaviour explains basic dynamics of walking and running. Proc. R. Soc. B. 273(1603), 2861–2867 (2006)
Günther, M., Blickhan, R.: Joint stiffness of the ankle and the knee in running. J. Biomech. 35, 1459–1474 (2002)
Hansen, A.H., Childress, D.S., Miff, S.C., Gard, S.A., Mesplay, K.P.: The human ankle during walking: implications for design of biomimetic ankle prostheses. J. Biomech. 37, 1467–1474 (2004)
Ishikawa, M., Komi, P.V.: The role of the stretch reflex in the gastrocnemius muscle during human locomotion at various speeds. J. Appl. Physiol. 103, 1030–1036 (2007)
Kuitunen, S., Komi, P.V., Kyröläinen, H.: Knee and ankle joint stiffness in sprint running. Medicine & Science in Sports & Exercise 34, 166–173 (2002)
Lipfert, S.W.: Kinematic and dynamic similarities between walking and running. Verlag Dr. Kovac (2010)
Malcolm, P., Fiers, P., Segers, V., Van Caekenberghe, I., Lenoir, M., De Clercq, D.: Experimental study on the role of the ankle push off in the walk-to-run transition by means of a powered ankle-foot-exoskeleton. Gait & Posture 30, 322–327 (2009)
Poulakakis, I., Grizzle, J.: Formal embedding of the spring loaded inverted pendulum in an asymmetric hopper. In: Proc. of the European Control Conference, Kos, Greece (2007)
Maus, H.M., Rummel, J., Blum, Y., Seyfarth, A.: Stable upright walking and running using a simple pendulum based control scheme. In: Marques, L., Almeida, A., Tokhi, M.O., Virk, G.S. (eds.) Advances in Mobile Robotics: Proc. of 11th CLAWAR, pp. 623–629. World Scientific (2008)
Maus, H.M., Lipfert, S.W., Gross, M., Rummel, J., Seyfarth, A.: Upright human gait did not provide a major mechanical challenge for our ancestors. Nature Communications (2010), doi:10.1038/ncomms1073
Maykranz, D., Grimmer, S., Lipfert, S.W., Seyfarth, A.: Foot function in spring mass running. In: Dillmann, R., Beyerer, J., Stiller, C., Zöllner, J.M., Gindele, T. (eds.) Autonome Mobile Systeme 2009, pp. 81–88. Springer (2009)
McMahon, T.A., Cheng, G.C.: The mechanics of running: how does stiffness couple with speed? Journal of Biomechanics 23(1), 65–78 (1990)
Neptune, R.R., Sasaki, K.: Ankle plantar flexor force production is an important determinant of the preferred walk-to-run transition speed. J. Exp. Biol. 208, 799–808 (2005)
Rummel, J., Seyfarth, A.: Stable running with segmented legs. Int. J. Robot. Res. 27(8), 919–934 (2008)
Rummel, J., Blum, Y., Seyfarth, A.: From walking to running. In: Dillmann, R., Beyerer, J., Stiller, C., Zöllner, J.M., Gindele, T. (eds.) Autonome Mobile Systeme 2009, pp. 89–96. Springer (2009); Broy, M., Dener, E. (eds.) Software Pioneers, pp. 10–13. Springer, Heidelberg (2002)
Seyfarth, A., Geyer, H., Günther, M., Blickhan, R.: A movement criterion for running. J. Biomech. 35, 649–655 (2002)
Seyfarth, A., Günther, M., Blickhan, R.: Stable operation of an elastic three-segment leg. Biological Cybernetics 84, 365–382 (2001)
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Seyfarth, A., Lipfert, S., Rummel, J., Maus, M., Maykranz, D. (2013). Walking and Running: How Leg Compliance Shapes the Way We Move. In: Mombaur, K., Berns, K. (eds) Modeling, Simulation and Optimization of Bipedal Walking. Cognitive Systems Monographs, vol 18. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-36368-9_17
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DOI: https://doi.org/10.1007/978-3-642-36368-9_17
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