Evolutionary algorithms in kinematic design of robotic systems

Author

Chocron, O. ; Bidaud, P.

Author_Institution

Lab. de Robotique, CNRS, Velizy, France

Volume

2

fYear

1997

fDate

7-11 Sep 1997

Firstpage

1111

Abstract

Proposes an adaptative multi-chromosome evolutionary algorithm (AMEA) to perform task based design of modular robotic systems. The kinematic design is optimized by the AMEA which uses both binary and real encoding (for kinematic and configuration parameters). In the problem considered for illustration, the robotic system consists in a mobile base and a manipulator arm which may be built with serially assembled link and joint modules. The manipulator has to reach a predefined set of goal frames in a 3D cluttered environment. Its design is evaluated with geometric and kinematic performance measures. Optimization results for a 3D task are given and compared with a simple genetic algorithm. They clearly show the superiority of the multi-chromosome representation and adaptive operators in term of computing time and criteria optimization performance

Keywords

genetic algorithms; manipulator kinematics; mobile robots; robot kinematics; 3D cluttered environment; 3D task; adaptative multi-chromosome evolutionary algorithm; adaptive operators; binary encoding; geometric performance measures; kinematic design; kinematic performance measures; manipulator arm; mobile base; modular robotic systems; real encoding; robotic systems; task based design; Algorithm design and analysis; Assembly systems; Design optimization; Encoding; Evolutionary computation; Genetic algorithms; Kinematics; Manipulators; Mobile robots; Robotic assembly;

fLanguage

English

Publisher

ieee

Conference_Titel

Intelligent Robots and Systems, 1997. IROS '97., Proceedings of the 1997 IEEE/RSJ International Conference on

Conference_Location

Grenoble

Print_ISBN

0-7803-4119-8

Type

conf

DOI

10.1109/IROS.1997.655148

Filename

655148