Work minimization accounts for footfall phasing in slow quadrupedal gaits

Quadrupeds, like most bipeds, tend to walk with an even left/right footfall timing. However, the phasing between hind and forelimbs shows considerable variation. Here, we account for this variation by modeling and explaining the influence of hind-fore limb phasing on mechanical work requirements. These mechanics account for the different strategies used by: (1) slow animals (a group including crocodile, tortoise, hippopotamus and some babies); (2) normal medium to large mammals; and (3) (with an appropriate minus sign) sloths undertaking suspended locomotion across a range of speeds. While the unusual hind-fore phasing of primates does not match global work minimizing predictions, it does approach an only slightly more costly local minimum. Phases predicted to be particularly costly have not been reported in nature.

[1]  John E A Bertram,et al.  A collisional perspective on quadrupedal gait dynamics , 2011, Journal of The Royal Society Interface.

[2]  R. McGhee,et al.  On the stability properties of quadruped creeping gaits , 1968 .

[3]  M Hildebrand,et al.  Symmetrical gaits of horses. , 1965, Science.

[4]  Jaynie F. Yang,et al.  Interlimb coordination in human crawling reveals similarities in development and neural control with quadrupeds. , 2009, Journal of neurophysiology.

[5]  L. Margetts,et al.  Exploring Diagonal Gait Using a Forward Dynamic Three-Dimensional Chimpanzee Simulation , 2013, Folia Primatologica.

[6]  R. Woledge The energetics of tortoise muscle , 1968, The Journal of physiology.

[7]  M. Hildebrand Symmetrical gaits of dogs in relation to body build , 1968, Journal of morphology.

[8]  R. Marsh,et al.  The effects of length trajectory on the mechanical power output of mouse skeletal muscles. , 1997, The Journal of experimental biology.

[9]  A. Ruina,et al.  A collisional model of the energetic cost of support work qualitatively explains leg sequencing in walking and galloping, pseudo-elastic leg behavior in running and the walk-to-run transition. , 2005, Journal of theoretical biology.

[10]  Manoj Srinivasan,et al.  Computer optimization of a minimal biped model discovers walking and running , 2006, Nature.

[11]  Bridging Motor Control and Biomechanics the Muscle–mechanical Compromise Framework: Implications for the Scaling of Gait and Posture the Premise behind the Muscle– Mechanical Compromise Framework , .

[12]  M. Hildebrand Symmetrical gaits of primates , 1967 .

[13]  R M Alexander,et al.  Fourier analysis of forces exerted in walking and running. , 1980, Journal of biomechanics.

[14]  C. T. Farley,et al.  Biomechanics of quadrupedal walking: how do four-legged animals achieve inverted pendulum-like movements? , 2004, Journal of Experimental Biology.

[15]  Jaynie F. Yang,et al.  Developmental constraints of quadrupedal coordination across crawling styles in human infants. , 2012, Journal of neurophysiology.

[16]  Manoj Srinivasan,et al.  Idealized walking and running gaits minimize work , 2007, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[17]  Alexander Petrovitch,et al.  Limb kinematics during locomotion in the two-toed sloth (Choloepus didactylus, Xenarthra) and its implications for the evolution of the sloth locomotor apparatus. , 2010, Zoology.

[18]  Arthur D Kuo,et al.  Energetics of actively powered locomotion using the simplest walking model. , 2002, Journal of biomechanical engineering.

[19]  D. Schmitt,et al.  Gait kinetics of above- and below-branch quadrupedal locomotion in lemurid primates , 2016, Journal of Experimental Biology.

[20]  Tatjana Y. Hubel,et al.  Children and adults minimise activated muscle volume by selecting gait parameters that balance gross mechanical power and work demands , 2015, Journal of Experimental Biology.

[21]  J. Vilensky,et al.  PRIMATE LOCOMOTION: Utilization and Control of Symmetrical Gaits , 1989 .

[22]  Alan M. Wilson,et al.  Mechanics of dog walking compared with a passive, stiff-limbed, 4-bar linkage model, and their collisional implications , 2007, Journal of Experimental Biology.

[23]  J. Gray Studies in the Mechanics of the Tetrapod Skeleton , 1944 .

[24]  R. M. Alexander,et al.  Optimization and gaits in the locomotion of vertebrates. , 1989, Physiological reviews.

[25]  P. Lemelin,et al.  Origins of primate locomotion: gait mechanics of the woolly opossum. , 2002, American journal of physical anthropology.

[26]  Andrew J. Spence,et al.  Closing the loop in legged neuromechanics: An open-source computer vision controlled treadmill , 2013, Journal of Neuroscience Methods.

[27]  James R. Usherwood,et al.  Constraints on muscle performance provide a novel explanation for the scaling of posture in terrestrial animals , 2013, Biology Letters.

[28]  A. R. Biknevicius,et al.  Correlation of symmetrical gaits and whole body mechanics: debunking myths in locomotor biodynamics. , 2006, Journal of experimental zoology. Part A, Comparative experimental biology.

[29]  J. Hurov Diagonal walking in captive infant vervet monkeys , 1982, American journal of primatology.

[30]  M. Cartmill,et al.  Support polygons and symmetrical gaits in mammals , 2002 .

[31]  R. Alexander,et al.  The gaits of chelonians: walking techniques for very low speeds , 2009 .

[32]  R. Alexander,et al.  A dynamic similarity hypothesis for the gaits of quadrupedal mammals , 2009 .

[33]  John E. A. Bertram,et al.  Understanding Mammalian Locomotion: Concepts and Applications , 2016 .

[34]  Daniel E. Koditschek,et al.  Longitudinal quasi-static stability predicts changes in dog gait on rough terrain , 2017, Journal of Experimental Biology.