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Neural hybrid control of manipulators, stability analysis

Published online by Cambridge University Press:  17 January 2001

N. Saadia
Affiliation:
LIIA-IUT de Creteil, 122, Rue Paul Armangot, 94400 Vitry Sur Seine Cedex (France)saadia@univ-paris12.fr
Y. Amirat
Affiliation:
LIIA-IUT de Creteil, 122, Rue Paul Armangot, 94400 Vitry Sur Seine Cedex (France)
J. Pontnau
Affiliation:
LIIA-IUT de Creteil, 122, Rue Paul Armangot, 94400 Vitry Sur Seine Cedex (France)
N.K. M'Sirdi
Affiliation:
Laboratoire de Robotique de Paris, 10–12, Avenue de l'Europe, 78140 Vélizy (France)nacer@robo.uvsq.fr

Abstract

The design and implementation of adaptive control for nonlinear unknown systems is extremely difficult. The nonlinear adaptive control for assembly robots performing a peg-in-hole insertion is one such an example. The recently intensively studied neural networks brings a new stage in the development of adaptive control, particularly for unknown nonlinear systems. The aim of this paper is to propose a new approach of hybrid force position control of an assembly robot based on artificial neural networks systems. An appropriate neural network is used to model the plant and is updated online. An artificial neural network controller is then directly evaluated using the updated neuro model. Two control structures are proposed and the stability analysis of the closed-loop system is investigated using the Lyapunov method. Experimental results demonstrate that the identification and control schemes suggested in this paper are efficient in practice.

Type
Research Article
Copyright
© 2001 Cambridge University Press

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