Neural network system for inverse kinematics problem in 3 DOF robotics

Author

Daya, Bassam ; Khawandi, Shadi ; Chauvet, Pierre

Author_Institution

Inst. of Technol. of Saida, Lebanese Univ., Lebanon, Lebanon

fYear

2010

fDate

23-26 Sept. 2010

Firstpage

1550

Lastpage

1557

Abstract

Inverse kinematics computation has been one of the main problems in robotics research. An inverse kinematic analysis addresses the problem of computing the sequence of joint motion from the Cartesian motion of an interested member, most often the end effector. Traditional methods such as geometric, iterative and algebraic are inadequate if the joint structure of the manipulator is more complex. In addition, periodic characteristic of trigonometric resulted non-convexity of IKM. As alternative approaches, neural networks have been widely used for inverse kinematics modeling and control in robotics. The idea is to build a network that learned all the trajectory path of a model in different setting. Computer simulations conducted on 3DOF robot manipulator shows the effectiveness of the approach.

Keywords

end effectors; manipulator kinematics; motion control; neurocontrollers; position control; 3 DOF robotics; 3DOF robot manipulator; Cartesian motion; end effector; inverse kinematic analysis; inverse kinematics computation; inverse kinematics modeling; joint structure; neural network system; periodic characteristic; robotics research; trajectory path; Neurons; Robots; Training; Degree of freedom (DOF); inverse kinematics model; multi-layered perceptron; neural networks; robotic arm;

fLanguage

English

Publisher

ieee

Conference_Titel

Bio-Inspired Computing: Theories and Applications (BIC-TA), 2010 IEEE Fifth International Conference on

Conference_Location

Changsha

Print_ISBN

978-1-4244-6437-1

Type

conf

DOI

10.1109/BICTA.2010.5645269

Filename

5645269