Neural network based control schemes for flexible-link manipulators: simulations and experiments

Neural network based control schemes for flexible-link manipulators: simulations and experiments

This paper presents simulation and experimental results on the performance of neural network-based controllers for tip position tracking of flexible-link manipulators. The controllers are designed by utilizing the modified output re-definition approach. The modified output re-definition approach req...

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Bibliographic Details
Published in:Neural networks Vol. 11; no. 7; pp. 1357 - 1377
Main Authors: Talebi, H.A., Khorasani, K., Patel, R.V.
Format: Journal Article
Language:English
Published: United States Elsevier Ltd 01-10-1998
Subjects:
Flexible-link manipulators
Inverse dynamics
Neural network based control
Non-minimum phase systems
Nonlinear control
Output redefinition
Tracking control
Output redefinition
Flexible-link manipulators
Inverse dynamics
Neural network based control
Non-minimum phase systems
Tracking control
Nonlinear control
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Summary:This paper presents simulation and experimental results on the performance of neural network-based controllers for tip position tracking of flexible-link manipulators. The controllers are designed by utilizing the modified output re-definition approach. The modified output re-definition approach requires only a priori knowledge about the linear model of the system and no a priori knowledge about the payload mass. Four different neural network schemes are proposed. The first two schemes are developed by using a modified version of the `feedback-error-learning' approach to learn the inverse dynamics of the flexible manipulator. Both schemes require only a linear model of the system for defining the new outputs and for designing conventional PD-type controllers. This assumption is relaxed in the third and fourth schemes. In the third scheme, the controller is designed based on tracking the hub position while controlling the elastic deflection at the tip. In the fourth scheme which employs two neural networks, the first network (referred to as the `output neural network') is responsible for specifying an appropriate output for ensuring minimum phase behavior of the system. The second neural network is responsible for implementing an inverse dynamics controller. The performance of the four proposed neural network controllers is illustrated by simulation results for a two-link planar flexible manipulator and by experimental results for a single flexible-link test-bed. The networks are all trained and employed as online controllers and no off-line training is required.
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ISSN:0893-6080
1879-2782
DOI:10.1016/S0893-6080(98)00038-0