Neural Network Grasping Controller for Continuum Robots

Author

Braganza, D. ; Dawson, D.M. ; Walker, I.D. ; Nath, N.

Author_Institution

Dept. of Electr. & Comput. Eng., Clemson Univ., SC

fYear

2006

fDate

13-15 Dec. 2006

Firstpage

6445

Lastpage

6449

Abstract

Continuum or hyper-redundant robots are robots which exhibit behavior similar to biological trunks, tentacles and snakes. Unlike traditional robots, continuum robot manipulators do not have rigid joints, hence the manipulators are compliant, extremely dexterous, and capable of dynamic, adaptive manipulation in unstructured environments; however, the development of high-performance control algorithms for these manipulators is a challenging problem. In this paper, we present an approach to whole arm grasping control for continuum robots. The grasping controller is developed in two stages; high level path planning for the grasping objective, and a low level joint controller using a neural network feedforward component to compensate for dynamic uncertainties. These techniques are used to enable whole arm grasping without using contact force measurements and without using a dynamic model of the continuum robot

Keywords

compensation; dexterous manipulators; feedforward neural nets; neurocontrollers; path planning; redundant manipulators; uncertain systems; adaptive manipulation; arm grasping control; continuum robot manipulators; continuum robots; control algorithms; dynamic uncertainty; high level path planning; hyper-redundant robots; neural network feedforward component; neural network grasping controller; Feedforward neural networks; Force measurement; Grasping; Kinematics; Legged locomotion; Manipulator dynamics; Neural networks; Robot control; Sliding mode control; Vehicle dynamics;

fLanguage

English

Publisher

ieee

Conference_Titel

Decision and Control, 2006 45th IEEE Conference on

Conference_Location

San Diego, CA

Print_ISBN

1-4244-0171-2

Type

conf

DOI

10.1109/CDC.2006.377452

Filename

4177464