Stability Analysis of Piezoelastic Structures for Robust Vibration Control

Thomas Rittenschober

Stability Analysis of Piezoelastic Structures for Robust Vibration Control

Thomas Rittenschober (Editor)

Institute of Control Systems

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

The design of an observer for self sensing actuation of functional materials requires acurate modeling of the piezoelastic structure under investigation. Under the assumption of linear piezoelasticity and Kirchhoff plate theory, the resulting mathematical structure facilitates controller design for harmonic disturbance suppression. Stability issues of the inﬁnite dimensional model are resolved in a straightforward manner by application of results on positive real transfer functions in conjunction with the small gain theorem. If the disturbance frequency is unknown, the proposed controller can be extended by an ordinary differential equation for the unknown frequency which is derived using a stability argument involving the Hamilton-Jacobi inequality.

Original language	English
Title of host publication	Proceedings Mathmod 09 Vienna, Abstract Volume
Editors	I. Troch, F. Breitenecker
Number of pages	7
Publication status	Published - Feb 2009

Publication series

Name	ARGESIM Report

Fields of science

102009 Computer simulation
203 Mechanical Engineering
202009 Electrical drive engineering
202034 Control engineering
202 Electrical Engineering, Electronics, Information Engineering
202027 Mechatronics
202003 Automation

JKU Focus areas

Mechatronics and Information Processing

Cite this

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abstract = "The design of an observer for self sensing actuation of functional materials requires acurate modeling of the piezoelastic structure under investigation. Under the assumption of linear piezoelasticity and Kirchhoff plate theory, the resulting mathematical structure facilitates controller design for harmonic disturbance suppression. Stability issues of the inﬁnite dimensional model are resolved in a straightforward manner by application of results on positive real transfer functions in conjunction with the small gain theorem. If the disturbance frequency is unknown, the proposed controller can be extended by an ordinary differential equation for the unknown frequency which is derived using a stability argument involving the Hamilton-Jacobi inequality.",

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AB - The design of an observer for self sensing actuation of functional materials requires acurate modeling of the piezoelastic structure under investigation. Under the assumption of linear piezoelasticity and Kirchhoff plate theory, the resulting mathematical structure facilitates controller design for harmonic disturbance suppression. Stability issues of the inﬁnite dimensional model are resolved in a straightforward manner by application of results on positive real transfer functions in conjunction with the small gain theorem. If the disturbance frequency is unknown, the proposed controller can be extended by an ordinary differential equation for the unknown frequency which is derived using a stability argument involving the Hamilton-Jacobi inequality.

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