Linking Gait Dynamics to Mechanical Cost of Legged Locomotion

For millenia, legged locomotion has been of central importance to humans for hunting, agriculture, transportation, sport, and warfare. Today, the same principal considerations of locomotor performance and economy apply to legged systems designed to serve, assist, or be worn by humans in urban and natural environments. Energy comes at a premium not only for animals, wherein suitably fast and economical gaits are selected through organic evolution, but also for legged robots that must carry sufficient energy in their batteries. Although a robot's energy is spent at many levels, from control systems to actuators, we suggest that the mechanical cost of transport is an integral energy expenditure for any legged system—and measuring this cost permits the most direct comparison between gaits of legged animals and robots. Although legged robots have matched or even improved upon total cost of transport of animals, this is typically achieved by choosing extremely slow speeds or by using regenerative mechanisms. Legged robots have not yet reached the low mechanical cost of transport achieved at speeds used by bipedal and quadrupedal animals. Here we consider approaches used to analyze gaits and discuss a framework, termed mechanical cost analysis, that can be used to evaluate the economy of legged systems. This method uses a point mass perspective to evaluate the entire stride as well as to identify individual events that accrue mechanical cost. The analysis of gait began at the turn of the last century with spatiotemporal analysis facilitated by the advent of cine film. These advances gave rise to the “gait diagram,” which plots duty factors and phase separations between footfalls. This approach was supplanted in the following decades by methods using force platforms to determine forces and motions of the center of mass (CoM)—and analytical models that characterize gait according to fluctuations in potential and kinetic energy. Mechanical cost analysis draws from these approaches and provides a unified framework that interprets the spatiotemporal sequencing of leg contacts within the context of CoM dynamics to determine mechanical cost in every instance of the stride. Diverse gaits can be evaluated and compared in biological and engineered systems using mechanical cost analysis.

[1]  David R. Carrier,et al.  The Energetic Paradox of Human Running and Hominid Evolution [and Comments and Reply] , 1984, Current Anthropology.

[2]  Marko Ackermann,et al.  Predictive simulation of gait at low gravity reveals skipping as the preferred locomotion strategy. , 2012, Journal of biomechanics.

[3]  G. Zug Crocodilian Galloping: An Unique Gait for Reptiles , 1974 .

[4]  Peter Aerts,et al.  One step beyond: Different step-to-step transitions exist during continuous contact brachiation in siamangs , 2012, Biology Open.

[5]  Craig P. McGowan,et al.  Why do mammals hop? Understanding the ecology, biomechanics and evolution of bipedal hopping , 2018, Journal of Experimental Biology.

[6]  S. Collins,et al.  The advantages of a rolling foot in human walking , 2006, Journal of Experimental Biology.

[7]  A. Seyfarth,et al.  Stable Upright Walking and Running using a simple Pendulum based Control Scheme , 2008 .

[8]  G. Cavagna Force platforms as ergometers. , 1975, Journal of applied physiology.

[9]  R. Blickhan The spring-mass model for running and hopping. , 1989, Journal of biomechanics.

[10]  John E A Bertram,et al.  Understanding brachiation: insight from a collisional perspective , 2003, Journal of Experimental Biology.

[11]  A response to Cartmill et al.: Primate gaits and arboreal stability , 2007 .

[12]  J. Bertram,et al.  Acceleration and balance in trotting dogs. , 1999, The Journal of experimental biology.

[13]  S. Renous,et al.  Asymmetrical gaits of juvenile Crocodylus johnstoni, galloping Australian crocodiles , 2002 .

[14]  Jeffrey H. Lang,et al.  Design Principles for Energy-Efficient Legged Locomotion and Implementation on the MIT Cheetah Robot , 2015, IEEE/ASME Transactions on Mechatronics.

[15]  V. Abdala,et al.  Muscles of Vertebrates: Comparative Anatomy, Evolution, Homologies and Development , 2010 .

[16]  R. McN. Alexander,et al.  The Gaits of Bipedal and Quadrupedal Animals , 1984 .

[17]  R. Full,et al.  Mechanics of a rapid running insect: two-, four- and six-legged locomotion. , 1991, The Journal of experimental biology.

[18]  Tad McGeer,et al.  Passive Dynamic Walking , 1990, Int. J. Robotics Res..

[19]  John Guckenheimer,et al.  The Dynamics of Legged Locomotion: Models, Analyses, and Challenges , 2006, SIAM Rev..

[20]  M. Hildebrand The Adaptive Significance of Tetrapod Gait Selection , 1980 .

[21]  R J Full,et al.  How animals move: an integrative view. , 2000, Science.

[22]  Andrew A. Biewener,et al.  Gravity, posture and locomotion in primates , 1991, International Journal of Primatology.

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

[24]  Marc H. Raibert,et al.  Trotting and Bounding in a Planar Two-legged Model , 1985 .

[25]  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.

[26]  G. Cavagna,et al.  The sources of external work in level walking and running. , 1976, The Journal of physiology.

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

[28]  T. McMahon,et al.  The mechanics of running: how does stiffness couple with speed? , 1990, Journal of biomechanics.

[29]  Z. Afelt,et al.  Speed control in animal locomotion: transitions between symmetrical and nonsymmetrical gaits in the dog. , 1983, Acta neurobiologiae experimentalis.

[30]  Reinhard Blickhan,et al.  Positioning the hip with respect to the COM: Consequences for leg operation. , 2015, Journal of theoretical biology.

[31]  A. Kuo A simple model of bipedal walking predicts the preferred speed-step length relationship. , 2001, Journal of biomechanical engineering.

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

[33]  A. Minetti Invariant aspects of human locomotion in different gravitational environments. , 2001, Acta astronautica.

[34]  P. Aerts,et al.  The dynamics of hylobatid bipedalism: evidence for an energy-saving mechanism? , 2006, Journal of Experimental Biology.

[35]  A E Minetti,et al.  The biomechanics of skipping gaits: a third locomotion paradigm? , 1998, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[36]  D. Raichlen,et al.  Lateral sequence walking in infant Papio cynocephalus: implications for the evolution of diagonal sequence walking in primates. , 2005, American journal of physical anthropology.

[37]  J. Bertram,et al.  External forces and torques generated by the brachiating white-handed gibbon (Hylobates lar). , 2000, American journal of physical anthropology.

[38]  Reinhard Blickhan,et al.  Compliant leg behaviour explains basic dynamics of walking and running , 2006, Proceedings of the Royal Society B: Biological Sciences.

[39]  Steven Vogel,et al.  Comparative Biomechanics: Life's Physical World , 2003 .

[40]  B. Jayne,et al.  Comparative three-dimensional kinematics of the hindlimb for high-speed bipedal and quadrupedal locomotion of lizards , 1999, The Journal of experimental biology.

[41]  C. T. Farley,et al.  Determinants of the center of mass trajectory in human walking and running. , 1998, The Journal of experimental biology.

[42]  Bernd Eggers,et al.  Bones Structure And Mechanics , 2016 .

[43]  P A Willems,et al.  Biomechanics of locomotion in Asian elephants , 2010, Journal of Experimental Biology.

[44]  S. Carroll,et al.  Fossils, genes and the evolution of animal limbs , 1997, Nature.

[45]  Michael Günther,et al.  A model-experiment comparison of system dynamics for human walking and running. , 2012, Journal of theoretical biology.

[46]  Daniel Schmitt,et al.  Adaptive value of ambling gaits in primates and other mammals , 2006, Journal of Experimental Biology.

[47]  T R Reynolds,et al.  Stride length and its determinants in humans, early hominids, primates, and mammals. , 1987, American journal of physical anthropology.

[48]  Chandana Paul,et al.  Low-bandwidth reflex-based control for lower power walking: 65 km on a single battery charge , 2014, Int. J. Robotics Res..

[49]  David V. Lee,et al.  A comparative collision-based analysis of human gait , 2013, Proceedings of the Royal Society B: Biological Sciences.

[50]  D. Schmitt,et al.  Forelimb and hind limb loading patterns during below branch quadrupedal locomotion in the two‐toed sloth , 2017 .

[51]  Rodger Kram,et al.  Biomechanics: Are fast-moving elephants really running? , 2003, Nature.

[52]  D. Bramble,et al.  Endurance running and the evolution of Homo , 2004, Nature.

[53]  Hartmut Geyer,et al.  Walking and Running with Passive Compliance: Lessons from Engineering: A Live Demonstration of the ATRIAS Biped , 2018, IEEE Robotics & Automation Magazine.

[54]  G. Cavagna,et al.  Mechanical work in terrestrial locomotion: two basic mechanisms for minimizing energy expenditure. , 1977, The American journal of physiology.

[55]  Daniel Schmitt,et al.  Understanding the adaptive value of diagonal-sequence gaits in primates: a comment on Shapiro and Raichlen, 2005. , 2007, American journal of physical anthropology.

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

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

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

[59]  Daniel P. Ferris,et al.  Biomechanics and energetics of walking on uneven terrain , 2013, Journal of Experimental Biology.

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

[61]  Russ Tedrake,et al.  Efficient Bipedal Robots Based on Passive-Dynamic Walkers , 2005, Science.

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

[63]  J. Bertram,et al.  Motions of the running horse and cheetah revisited: fundamental mechanics of the transverse and rotary gallop , 2009, Journal of The Royal Society Interface.

[64]  K. Kramer,et al.  Insect Cuticle Sclerotization , 1992 .