Predicting the metabolic energy costs of bipedalism using evolutionary robotics

doi:10.1242/jeb.00205

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The Journal of Experimental Biology 206, 1127-1136 (2003)
doi: 10.1242/jeb.00205

Predicting the metabolic energy costs of bipedalism using evolutionary robotics

W. I. Sellers¹^,*, L. A. Dennis² and R. H. Crompton³

^¹ Department of Human Sciences, Loughborough University, Loughborough LE11 3TU, UK
^² School of Computer Science and Information Technology, University of Nottingham, Jubilee Campus, Nottingham, NG8 1BB, UK
^³ Department of Human Anatomy and Cell Biology, University of Liverpool, The Sherrington Buildings, Ashton Street, Liverpool L69 3GE, UK

^* Author for correspondence (e-mail: W.I.Sellers{at}lboro.ac.uk)

Accepted 20 December 2002

To understand the evolution of bipedalism among the hominoidsin an ecological context we need to be able to estimate theenergetic cost of locomotion in fossil forms. Ideally such anestimate would be based entirely on morphology since, exceptfor the rare instances where footprints are preserved, thisis the only primary source of evidence available. In this paperwe use evolutionary robotics techniques (genetic algorithms,pattern generators and mechanical modeling) to produce a biomimeticsimulation of bipedalism based on human body dimensions. Themechanical simulation is a seven-segment, two-dimensional modelwith motive force provided by tension generators representingthe major muscle groups acting around the lower-limb joints.Metabolic energy costs are calculated from the muscle model,and bipedal gait is generated using a finite-state pattern generatorwhose parameters are produced using a genetic algorithm withlocomotor economy (maximum distance for a fixed energy cost)as the fitness criterion. The model is validated by comparingthe values it generates with those for modern humans. The result(maximum efficiency of 200 J m^–1) is within 15% of theexperimentally derived value, which is very encouraging and suggeststhat this is a useful analytic technique for investigating the locomotorbehaviour of fossil forms. Initial work suggests that in thefuture this technique could be used to estimate other locomotorparameters such as top speed. In addition, the animations producedby this technique are qualitatively very convincing, which suggeststhat this may also be a useful technique for visualizing bipedallocomotion.

Key words: bipedalism, biomechanics, locomotion, evolutionary computing, human

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