Optimal muscular coordination strategies for jumping

Pandy, Marcus G.; Zajac, Felix E.

Affiliations

¹Design Division, Mechanical Engineering Department, Stanford University, Stanford, CA 94305-4021, U.S.A.

²Rehabilitation Research and Development Center (153), Veterans’ Administration Medical Center, Palo Alto, CA 94304-1200, U.S.A.

³Present address: Department of Kinesiology and Health Education, The University of Texas at Austin, Austin, TX 78712, U.S.A.

Abstract

This paper presents a detailed analysis of an optimal control solution to a maximum height squat jump, based upon how muscles accelerate and contribute power to the body segments during the ground contact phase of jumping. Quantitative comparisons of model and experimental results expose a proximal-to-distal sequence of muscle activation (i.e. from hip to knee to ankle). We found that the contribution of muscles dominates both the angular acceleration and the instantaneous power of the segments. However, the contributions of gravity and segmental motion are insignificant, except the latter become important during the final 10% of the jump. Vasti and gluteus maximus muscles are the major energy producers of the lower extremity. These muscles are the prime movers of the lower extremity because they dominate the angular acceleration of the hip toward extension and the instantaneous power of the trunk. In contrast, the ankle plantarflexors (soleus, gastrocnemius, and the other plantarflexors) dominate the total energy of the thigh, though these muscles also contribute appreciably to trunk power during the final 20% of the jump. Therefore, the contribution of these muscles to overall jumping performance cannot be neglected. We found that the biarticular gastrocnemius increases jump height (i.e. the net vertical displacement of the center of mass of the body from standing) by as much as 25%. However, this increase is not due to any unique biarticular action (e.g. proximal-to-distal power transfer from the knee to the ankle), since jumping performance is similar when gastrocnemius is replaced with a uniarticular ankle plantarflexor.

Links

DOI: 10.1016/0021-9290(91)90321-D

PubMed: 2026629

WoS: A1991FC28500001

History

Revised: 1990-02-28

Cited Works (9)

Year	Entry
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Cited By (38)

Year	Entry
2007	Erdemir A, McLean S, Herzog W, van den Bogert AJ. Model-based estimation of muscle forces exerted during movements. Clin Biomech (Bristol, Avon). February 2007;22(2):131-154.
1999	Anderson FC, Pandy MG. A dynamic optimization solution for vertical jumping in three dimensions. Comput Methods Biomech Biomed Eng. 1999;2(3):201-231.
2002	Zajac FE, Neptune RR, Kautz SA. Biomechanics and muscle coordination of human walking, I: introduction to concepts, power transfer, dynamics and simulations. Gait Post. December 2002;16(3):215-232.
2003	Zajac FE, Neptune RR, Kautz SA. Biomechanics and muscle coordination of human walking, II: lessons from dynamical simulations and clinical implications. Gait Post. February 2003;17(1):1-17.
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1993	Zajac FE. Muscle coordination of movement: a perspective. J Biomech. 1993;26(suppl 1):109-124.
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1996	Fregly BJ, Zajac FE. A state-space analysis of mechanical energy generation, absorption, and transfer during pedaling. J Biomech. January 1996;29(1):81-90.
2023	Holt NC, Mayfield DL. Muscle-tendon unit design and tuning for power enhancement, power attenuation, and reduction of metabolic cost. J Biomech. May 2023;153:111585.
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2004	Ashby BM. Coordination of Upper and Lower Limbs in the Standing Long Jump: Kinematics, Dynamics, and Optimal Control [PhD thesis]. Stanford University; July 2004.
2016	Chen X. In Vivo Microendoscopy Measurements of Skeletal Muscle Sarcomeres in Humans and ALS Mice [PhD thesis]. Stanford University; August 2016.
1995	Cole GK. Loading of the Joints of the Lower Extremities During the Impact Phase in Running [PhD thesis]. Calgary, AB: University of Calgary; July 1995.
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1998	Wright IC. A Simulation Study of the Contribution of Several Factors to Ankle Sprain Susceptibility [PhD thesis]. Calgary, AB: University of Calgary; December 1998.
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1992	Kautz SA. Biomechanics of Pedalling With Non-Circular Chainrings in Cycling [PhD thesis]. Davis, University of California; 1992.
1992	Gu M-J. Biomechanical Analysis of Postural Balance in Young and Elderly Adults During Perturbed Stance [PhD thesis]. University of Michigan; 1992.
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2021	Wilkinson R. Rock and Roll: The Effects of Centre of Mass Movement and Bicycle Lean on the Biomechanics of Cycling [PhD thesis]. Brisbane, Australia: University of Queensland; 2021.
1994	Ziegler JM. A Dynamic Computational Model of the Human Knee Joint With Implementation in Two Optimal Control Models [PhD thesis]. University of Texas at Austin; August 1994.
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2015	Mansouri Boroujeni M. Dynamic Simulation and Neuromuscular Control of Movement: Applications for Predictive Simulations of Balance Recovery [PhD thesis]. Knoxville, University of Tennessee; May 2015.
2017	Schlotman TE. Dynamic Simulation and Analysis of Gait Modification for Treating Knee Osteoarthritis [PhD thesis]. Knoxville, University of Tennessee; May 2017.
2010	Patel R. Performance of a Two-Foot Vertical Jump: What is More Important Hip or Knee Dominance? [Master's thesis]. University of Waterloo; 2010.