On the stabilization of the disk-beam system via torque and direct strain feedback controls

Boumediene Chentouf; Jun Min Wang

doi:10.1109/TAC.2015.2406974

On the stabilization of the disk-beam system via torque and direct strain feedback controls

Boumediene Chentouf^*, Jun Min Wang

^*Corresponding author for this work

School of Mathematics and Statistics

Sultan Qaboos University

Research output: Contribution to journal › Article › peer-review

25 Citations (Scopus)

Abstract

This note deals with the stabilization problem of a rotating disk-beam system. The proposed feedback law consists of a nonlinear torque control exerted on the disk, whereas a direct strain control is applied at the beam with a rigid offset. As a consequence, we end up with a nondissipative nonlinear hybrid PDE-ODE system and hence the existence and stability of solutions of the system cannot be addressed by using standard methods such as energy-multiplier or frequency-domain. To overcome this situation, we adopt the Riesz basis methodology and show that the closed-loop system is well-posed and stable as long as the angular velocity of the disk is less than a well-defined value related to the beam. The results are illustrated through a wide set of numerical examples.

Original language	English
Article number	7047787
Pages (from-to)	3006-3011
Number of pages	6
Journal	IEEE Transactions on Automatic Control
Volume	60
Issue number	11
DOIs	https://doi.org/10.1109/TAC.2015.2406974
Publication status	Published - 1 Nov 2015

Keywords

Riesz basis
Rotating disk-beam
direct strain control
stability
torque control

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10.1109/TAC.2015.2406974

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abstract = "This note deals with the stabilization problem of a rotating disk-beam system. The proposed feedback law consists of a nonlinear torque control exerted on the disk, whereas a direct strain control is applied at the beam with a rigid offset. As a consequence, we end up with a nondissipative nonlinear hybrid PDE-ODE system and hence the existence and stability of solutions of the system cannot be addressed by using standard methods such as energy-multiplier or frequency-domain. To overcome this situation, we adopt the Riesz basis methodology and show that the closed-loop system is well-posed and stable as long as the angular velocity of the disk is less than a well-defined value related to the beam. The results are illustrated through a wide set of numerical examples.",

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AB - This note deals with the stabilization problem of a rotating disk-beam system. The proposed feedback law consists of a nonlinear torque control exerted on the disk, whereas a direct strain control is applied at the beam with a rigid offset. As a consequence, we end up with a nondissipative nonlinear hybrid PDE-ODE system and hence the existence and stability of solutions of the system cannot be addressed by using standard methods such as energy-multiplier or frequency-domain. To overcome this situation, we adopt the Riesz basis methodology and show that the closed-loop system is well-posed and stable as long as the angular velocity of the disk is less than a well-defined value related to the beam. The results are illustrated through a wide set of numerical examples.

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On the stabilization of the disk-beam system via torque and direct strain feedback controls

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Keywords

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