GA-Based Architecture Optimization of a 3-PUU Parallel Manipulator for Stiffness Performance

Author

Xu, Qingsong ; Li, Yangmin

Author_Institution

Dept. of Electromech. Eng., Macau Univ., Macao

Volume

2

fYear

0

fDate

0-0 0

Firstpage

9099

Lastpage

9103

Abstract

In this paper, an optimal design of a three-prismatic-universal-universal (3-PUU) translational parallel manipulator is performed using the genetic algorithm (GA) to achieve optimum stiffness characteristics. The stiffness matrix is derived intuitively based upon an overall Jacobian with the consideration of actuation and constraints, and the compliance subjected to both actuators and legs is taken into account to establish the stiffness model. A global stiffness index defined as the mean value of the determinant of stiffness matrix over the reachable workspace is adopted as a stiffness measure, meanwhile the architectural parameters are optimized via a GA approach. The research results are valuable in the design of a 3-PUU parallel manipulator for machine tool applications

Keywords

Jacobian matrices; genetic algorithms; manipulators; 3-PUU parallel manipulator; GA-based architecture optimization; Jacobian matrix; genetic algorithm; stiffness matrix; three-prismatic-universal-universal translational parallel manipulator; Actuators; Algorithm design and analysis; Constraint optimization; Design engineering; Finite difference methods; Genetic algorithms; Genetic engineering; Jacobian matrices; Kinematics; Machine tools; Genetic algorithm; mechanism design; parallel manipulators; stiffness; workspace;

fLanguage

English

Publisher

ieee

Conference_Titel

Intelligent Control and Automation, 2006. WCICA 2006. The Sixth World Congress on

Conference_Location

Dalian

Print_ISBN

1-4244-0332-4

Type

conf

DOI

10.1109/WCICA.2006.1713760

Filename

1713760