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Multiple actuator fault tolerance for static nonlinear systems based on minimum velocity jump

conference contribution
posted on 2011-01-01, 00:00 authored by Hamid AbdiHamid Abdi, Saeid Nahavandi, Zoran NajdovskiZoran Najdovski, Yakov Frayman
Static nonlinear systems are common when the model of the kinematics of mechanical or civil structures is analyzed for instance kinematics of robotic manipulators. This paper addresses the maximum effort toward fault tolerance for any number of the locked actuators failures in static nonlinear systems. It optimally reconfigures the inputs via a mapping that maximally accommodates the failures. The mapping maps the failures to an extra action of healthy actuators that results to a minimum jump for the velocity of the output variables. Then from this mapping, the minimum jump of the velocity of the output is calculated. The conditions for a zero velocity jump of the output variables are discussed. This shows that, when the conditions of fault tolerance are maintained, the proposed framework is capable of fault recovery not only at fault instances but also at the whole output trajectory. The proposed mapping is validated by three case studies.

History

Pagination

4690 - 4695

Location

Milano, Italy

Open access

  • Yes

Start date

2011-08-28

End date

2011-09-02

ISBN-13

9783902661937

Language

eng

Publication classification

E1 Full written paper - refereed

Copyright notice

2011, International Federation of Automatic Control (IFAC)

Editor/Contributor(s)

S Bittanti, A Cenedese, S Zampieri

Title of proceedings

IFAC 2011 : Proceedings of the 18th IFAC World Congress

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