Energetics of actively powered locomotion using the simplest walking model

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Kuo, Arthur D.¹

Energetics of actively powered locomotion using the simplest walking model

J Biomech Eng. February 2002;124(1):113-120

©2002 ASME

Affiliations

¹Dept. of Mechanical Engineering and Applied Mechanics, University of Michigan, Ann Arbor, MI 48109-2125
Abstract

We modified an rreducibly simple model of passive dynamic walking to walk on level ground, and used it to study the energetics of walking and the preferred relationship between speed and step length in humans. Powered walking was explored using an impulse applied at toe-off immediately before heel strike, and a torque applied on the stance leg. Although both methods can supply energy through mechanical work on the center of mass, the toe-off impulse is four times less costly because it decreases the collision loss at heel strike. We also studied the use of a hip torque on the swing leg that tunes its frequency but adds no propulsive energy to gait. This spring-like actuation can further reduce the collision loss at heel strike, improving walking energetics. An idealized model yields a set of simple power laws relating the toe-off impulses and effective spring constant to the speed and step length of the corresponding gait. Simulations incorporating nonlinear equations of motion and more realistic inertial parameters show that these power laws apply to more complex models as well.
Links

DOI: 10.1115/1.1427703

PubMed: 11871597

WoS: 000175343500016
History

Received: 1999-09-20

Revised: 2001-09-17

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Cited By (26)

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2004	Neptune RR, Zajac FE, Kautz SA. Muscle force redistributes segmental power for body progression during walking. Gait Post. April 2004;19(2):194-205.
2006	Liu MQ, Anderson FC, Pandy MG, Delp SL. Muscles that support the body also modulate forward progression during walking. J Biomech. 2006;39(14):2623-2630.
2008	Liu MQ, Anderson FC, Schwartz MH, Delp SL. Muscle contributions to support and progression over a range of walking speeds. J Biomech. November 14, 2008;41(15):3243-3252.
2023	Ebers MR, Rosenberg MC, Kutz JN, Steele KM. A machine learning approach to quantify individual gait responses to ankle exoskeletons. J Biomech. August 2023;157:111695.
2013	Shamaei K, Sawicki GS, Dollar AM. Estimation of quasi-stiffness and propulsive work of the human ankle in the stance phase of walking. PLoS One. March 2013;8(3):e59935.
2020	Schroeder RT. Gait Entrainment in Coupled Oscillator Systems: Clarifying the Role of Energy Optimization in Human Walking [PhD thesis]. Edith Cowan University; 2020.
2019	Robertson MA. Modular Soft Pneumatic Actuator System Design for Compliance Matching [PhD thesis]. Swiss Federal Institute of Technology Lausanne; 2019.
2016	Islam M. Studies on Gait Control Using a Portable Pneumatically Powered Anklefoot Orthosis (PPAFO) During Human Walking [PhD thesis]. University of Illinois at Urbana-Champaign; 2016.
2020	Simha SN. Principles of Energy Optimization Underlying Human Walking Gait Adaptations [PhD thesis]. Simon Fraser University; 2020.
2008	Liu MQ-M. Muscle Contributions to Support and Progression Over a Range of Walking Speeds [PhD thesis]. Stanford University; October 2008.
2011	Fox MD. Understanding Biomechanical Causes and Functional Mechanism of Treatment for Stiff-Knee Gait in Cerebral Palsy [PhD thesis]. Stanford University; May 2011.
2021	Poggensee KL. Understanding the Human Contribution to the Human-Exoskeleton System [PhD thesis]. Stanford University; March 2021.
2004	Scovil CY. The Viability of a 3D Forward Dynamic Model of Walking as a Research Tool to Enhance Clinical Understanding of Gait Abnormalities [PhD thesis]. Calgary, AB: University of Calgary; March 2004.
2018	Ebrahimi A. The Development and Application of a Framework for Exploring the Energetics of Gait Strategy Adaptations [PhD thesis]. University of Delaware; 2018.
2018	Wei D. The First Step to a Framework for Gait-Training With a Bilateral Approach [Master's thesis]. University of Delaware; 2018.
2005	Dean JC. The Influence of System Dynamics on the Control and Energetics of Repetitive Human Movement [PhD thesis]. University of Michigan; 2005.
2005	Doke J. On the Preferred Step Frequencies of Walking: Mechanics and Energetics of Swinging the Human Leg [PhD thesis]. University of Michigan; 2005.
2008	Adamczyk PG. The Influence of Center of Mass Velocity Redirection on Mechanical and Metabolic Perfomance During Walking [PhD thesis]. University of Michigan; 2008.
2008	Collins SH. Dynamic Walking Principles Applied to Human Gait [PhD thesis]. University of Michigan; 2008.
2012	Zelik KE. Passive Energy-Saving Mechanisms in Human Locomotion [PhD thesis]. University of Michigan; 2012.
2017	Kang GE. Effects of Emotion and Mood Phase on Biomechanical Characteristics of Body Movements in Healthy Individuals and Individuals With Bipolar Disorder [PhD thesis]. University of Michigan; 2017.
2012	Kurse MU. Inference of Computational Models of Tendon Networks Via Sparse Experimentation [PhD thesis]. University of Southern California (USC); August 2012.
2014	Bohnsack NK. Adaptability of Stride-to-Stride Control of Stepping Movements in Human Walking and Running [PhD thesis]. University of Texas at Austin; May 2014.
2019	Honert EC. Ankle and Foot Biomechanics During Human Walking: Powerful Insights on Multiarticular Muscles, Soft Tissues, and Toe Joint Dynamics [PhD thesis]. Nashville, TN: Vanderbilt University; May 10, 2019.
2021	Rosenberg MC. Modeling and Predicting Response to Ankle Exoskeletons [PhD thesis]. University of Washington; 2021.
2023	Ebers MR. Machine Learning for Dynamical Models of Human Movement [PhD thesis]. University of Washington; 2023.