Locomotion Energetics of the Ghost Crab: II. Mechanics of the Centre of Mass During Walking and Running

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Journal of Experimental Biology 130,155-174 (1987)
Published by Company of Biologists 1987

Locomotion Energetics of the Ghost Crab : II. Mechanics of the Centre of Mass During Walking and Running

REINHARD BLICKHAN ¹ and ROBERT J. FULL ²

¹ Concord Field Station, Harvard University, Bedford, MA 01730, USA; Fachbereich Biologie (16.4) Bau 6, Universität des Saarlandes, D-6800 Saarbrücken, FRG
² Department of Anatomy, University of Chicago, Chicago, IL 60637, USA; Department of Zoology, University of California, Berkeley, CA 94720, USA

Terrestrial locomotion involving appendages has evolved independentlyin vertebrates and arthropods. Differences in the mechanicaldesign of the locomotor apparatus could impose constraints onthe energetics of locomotion. The mechanical energy fluctuationsof the centre of mass of an arthropod, the ghost crab Ocypodequadrata (Fabricius), were examined by integrating the groundreaction forces exerted during sideways locomotion. Crabs useda pendulum-type energy exchange mechanism during walking, analogousto an egg rolling end over end, with the same effectivenessas birds and mammals. Moreover, ghost crabs were found to havetwo running gaits. A switch from a slow to a fast run occurredat the same speed and stride frequency predicted for the trot-galloptransition of a quadrupedal mammal of the same body mass. Inaddition, the mass-specific mechanical energy developed overa unit distance was independent of speed and was within thelimits measured for birds and mammals. Despite the obvious differencesin mechanical design between crabs and mammals, energy-conservingmechanisms and the efficiency of locomotion were remarkablysimilar. These similarities may result from the fact that themuscles that generate forces during terrestrial locomotion haverelatively conservative mechanical and energetic properties.

Key words: locomotion, arthropods, mechanics

Accepted on February 13, 1987

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