Evolving splines: an alternative locomotion controller for a bipedal robot

Author

Boeing, A. ; Braunl, T.

Author_Institution

Dept. of Electr. & Electron. Eng., Western Australia Univ., Nedlands, WA, Australia

Volume

2

fYear

2002

fDate

2-5 Dec. 2002

Firstpage

798

Abstract

Evolutionary algorithms have often been applied to evolve controllers for robot locomotion. In an attempt to imitate biological systems, most previous approaches have utilized neural networks and central pattern generators to construct the controllers. In contrast to the conventional approach, control points for Hermite splines are evolved, rather than neuron weightings. A spline based control system has the advantages that it is simple to implement, requires little processing power, and the complexity of the controller can easily be altered. Initially limiting the splines control point parameters allows for faster evolution of the initial gait, and by progressively adding extra parameters the initial gait can be refined to produce an optimized final gait. This provides the robot designer with an early approximate gait for the robot, in less time than required to evolve a full control sequence by other means.

Keywords

gait analysis; genetic algorithms; legged locomotion; motion control; splines (mathematics); Hermite splines; biological systems; bipedal robot; evolutionary algorithms; gait generation; genetic algorithm; locomotion controller; neural networks; neuron weightings; pattern generators; robot designer; spline control system; Biological control systems; Biological systems; Centralized control; Control systems; Evolution (biology); Evolutionary computation; Neural networks; Neurons; Refining; Robot control;

fLanguage

English

Publisher

ieee

Conference_Titel

Control, Automation, Robotics and Vision, 2002. ICARCV 2002. 7th International Conference on

Print_ISBN

981-04-8364-3

Type

conf

DOI

10.1109/ICARCV.2002.1238524

Filename

1238524