Predictive simulations of running gait reveal a critical dynamic role for the tail in bipedal dinosaur locomotion
Peter J. Bishop, Antoine Falisse, Friedl De Groote, John R. Hutchinson
Abstract
. Unexpectedly, our simulations involved pronounced lateroflexion movements of the tail. Rather than just being a static counterbalance, simulations indicate that the tail played a crucial dynamic role, with lateroflexion acting as a passive, physics-based mechanism for regulating angular momentum and improving locomotor economy, analogous to the swinging arms of humans. We infer this mechanism to have existed in many other bipedal non-avian dinosaurs as well, and our methodology provides new avenues for exploring the functional diversity of dinosaur tails in the future.
Topics & Concepts
BipedalismVertebrateGaitLeverage (statistics)Mechanism (biology)BiologyEvolutionary biologyTerrestrial locomotionFossil RecordComputer scienceEcologyAnatomyPhysicsArtificial intelligenceGeneBiochemistryQuantum mechanicsPhysiologyRobotic Locomotion and ControlProsthetics and Rehabilitation RoboticsVeterinary Orthopedics and Neurology