Active vibration control of an elastically connected double-string continuous system

Active vibration control of an elastically connected double-string continuous system

The paper deals with the optimal control of a distributed host structure consisting of two elastically connected complex continuous double-string system and subjected to certain excitation load. Investigation of the behavior of such system is of great theoretical and practical importance. A techniqu...

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Bibliographic Details
Published in:Journal of the Franklin Institute Vol. 344; no. 5; pp. 684 - 697
Main Authors: Kucuk, Ismail, Sadek, Ibrahim
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-08-2007
Subjects:
Displacement control
Feedback control
Fredholm integral equations
Optimal control
Optimality conditions
String
Optimality conditions
Displacement control
String
Feedback control
Fredholm integral equations
Optimal control
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Summary:The paper deals with the optimal control of a distributed host structure consisting of two elastically connected complex continuous double-string system and subjected to certain excitation load. Investigation of the behavior of such system is of great theoretical and practical importance. A technique is proposed to actively damp out the undesired vibrations in the structures by a combination of applied actuators and displacement feedback gains. Two performance measures, involving energies at the terminal time as well as applied and feedback control efforts, are introduced. The optimality conditions of the applied actuators are derived by using the method of eigenfunction expansion and calculus of variations. The feedback parameters are numerically determined from the solution of a minimization problem. The proposed approach is illustrated by a numerical example involving a system which consists of two strings subjected to a continuous load.
ISSN:0016-0032
1879-2693
DOI:10.1016/j.jfranklin.2006.02.004