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Evaluating the Effect of a Flexible Spine on the Evolution of Quadrupedal Gaits

Jared M. Moore, Craig P. McGowan, Philip K. McKinley

Year
2015
Citations
5
Access
Open access

Abstract

Animals demonstrate a level of agility currently unmatched in their robotic counterparts.The elasticity of muscles and tendons increase not only performance, but also the efficiency of movements.In contrast, robots are often constructed with rigid components connected by motors.However, recently compliant actuators and materials have been introduced to enhance robot designs, emulating the flexibility of natural organisms.In this paper, we incorporate passive flexibility into the spine of a quadruped animat and employ computational evolution to generate gaits.Results indicate that spine flexibility significantly increases both performance and efficiency of evolved individuals.Moreover, evolving the degree of spine flexibility along with artificial neural network controllers produces the highest performing solutions. Related WorkIncorporating flexible materials holds promise for increasing the functionality of robotic systems.In aquatic robots, mimicking fin-like appendages can increase agility, power efficiency, and robustness.Anderson and Chhabra (2002) demonstrated a hybrid rigid-body, flexible-tail robotic tuna that exhibited increased maneuverability at high speeds compared to traditional autonomous underwater vehi-

Keywords

QuadrupedalismComputer scienceSPINE (molecular biology)BiologyAnatomyBioinformatics

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