| scholarly article | Q13442814 |
| P50 | author | Tatjana Y Hubel | Q47273410 |
| P2093 | author name string | James R Usherwood | |
| P2860 | cites work | Predicting the energy cost of terrestrial locomotion: a test of the LiMb model in humans and quadrupeds | Q79596781 |
| Muscle mechanical advantage of human walking and running: implications for energy cost | Q80349239 | ||
| Influence of speed variation and age on the asymmetry of ground reaction forces and stride parameters of normal gait in children | Q81028880 | ||
| Changes in 3D joint dynamics during the first 5 months after the onset of independent walking: a longitudinal follow-up study | Q81544738 | ||
| Foot mechanics during the first six years of independent walking | Q83270648 | ||
| Compliant ankle function results in landing-take off asymmetry in legged locomotion | Q87212277 | ||
| Quantifying Ca2+ release and inactivation of Ca2+ release in fast- and slow-twitch muscles | Q87400009 | ||
| Foot speed, foot-strike and footwear: linking gait mechanics and running ground reaction forces | Q87691980 | ||
| Don't break a leg: running birds from quail to ostrich prioritise leg safety and economy on uneven terrain | Q28654211 | ||
| Faster top running speeds are achieved with greater ground forces not more rapid leg movements | Q30659157 | ||
| Energetics of bipedal running. I. Metabolic cost of generating force | Q32024314 | ||
| Running springs: speed and animal size. | Q34348754 | ||
| Energetics of running: a new perspective | Q34762537 | ||
| The cost of leg forces in bipedal locomotion: a simple optimization study | Q35112582 | ||
| Leg stiffness of sprinters using running-specific prostheses | Q36065437 | ||
| Development of independent walking in toddlers. | Q36784897 | ||
| Energy-saving mechanisms in walking and running | Q37552319 | ||
| Inverted pendular running: a novel gait predicted by computer optimization is found between walk and run in birds | Q41140191 | ||
| Constraints on muscle performance provide a novel explanation for the scaling of posture in terrestrial animals | Q41987749 | ||
| Fifteen observations on the structure of energy-minimizing gaits in many simple biped models | Q41993906 | ||
| The human foot and heel-sole-toe walking strategy: a mechanism enabling an inverted pendular gait with low isometric muscle force? | Q42104239 | ||
| Shortening velocity and power output of skinned muscle fibers from mammals having a 25,000-fold range of body mass | Q42121486 | ||
| Energetically optimal running requires torques about the centre of mass | Q42218914 | ||
| The spring-mass model for running and hopping | Q45163238 | ||
| The metabolic cost of walking in humans, chimpanzees, and early hominins | Q47643606 | ||
| Energetic cost of producing cyclic muscle force, rather than work, to swing the human leg. | Q50977253 | ||
| Trunk orientation causes asymmetries in leg function in small bird terrestrial locomotion. | Q51036977 | ||
| Computer optimization of a minimal biped model discovers walking and running. | Q51964673 | ||
| Energetics of actively powered locomotion using the simplest walking model. | Q52045493 | ||
| Development of pendulum mechanism and kinematic coordination from the first unsupported steps in toddlers. | Q52087515 | ||
| On the locomotion of mammals. | Q53054601 | ||
| Mechanical and metabolic determinants of the preferred step width in human walking. | Q53885554 | ||
| Compliant leg behaviour explains basic dynamics of walking and running. | Q55355285 | ||
| 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 | Q57525665 | ||
| Multiple Walking Speed–frequency Relations are Predicted by Constrained Optimization | Q57525682 | ||
| Wave pattern of ground reaction force of growing children | Q68171682 | ||
| Scaling body support in mammals: limb posture and muscle mechanics | Q69644513 | ||
| Ground reaction forces at different speeds of human walking and running | Q69733037 | ||
| Energetic aspects of muscle contraction | Q69810274 | ||
| The mechanics of running: how does stiffness couple with speed? | Q70255618 | ||
| Fourier analysis of forces exerted in walking and running | Q71269384 | ||
| P275 | copyright license | Creative Commons Attribution 3.0 Unported | Q14947546 |
| P6216 | copyright status | copyrighted | Q50423863 |
| P433 | issue | Pt 18 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | entomology | Q39286 |
| aquatic science | Q4782809 | ||
| P304 | page(s) | 2830-9 | |
| P577 | publication date | 2015-09-01 | |
| P1433 | published in | The Journal of Experimental Biology | Q1355917 |
| P1476 | title | Children and adults minimise activated muscle volume by selecting gait parameters that balance gross mechanical power and work demands | |
| P478 | volume | 218 |
| Q38811991 | A unified theory for the energy cost of legged locomotion |
| Q92689414 | An instrumented centrifuge for studying mouse locomotion and behaviour under hypergravity |
| Q41711352 | Measuring the Energy of Ventilation and Circulation during Human Walking using Induced Hypoxia |
| Q41225756 | Physiological, aerodynamic and geometric constraints of flapping account for bird gaits, and bounding and flap-gliding flight strategies |
| Q92088712 | Spring-loaded inverted pendulum goes through two contraction-extension cycles during the single-support phase of walking |
| Q64063657 | The Landscape of Movement Control in Locomotion: Cost, Strategy, and Solution |
| Q53072239 | The influence of speed and size on avian terrestrial locomotor biomechanics: Predicting locomotion in extinct theropod dinosaurs. |
| Q42328305 | The muscle-mechanical compromise framework: Implications for the scaling of gait and posture |
| Q57493303 | The scaling or ontogeny of human gait kinetics and walk-run transition: The implications of work vs. peak power minimization |
| Q41062863 | Work minimization accounts for footfall phasing in slow quadrupedal gaits |
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