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**Harvard**

Svensson, J., Andersson, P. och Kropp, W. (2008) *An impedance matching technique for active-passive vibration control*.

** BibTeX **

@conference{

Svensson2008,

author={Svensson, Jonas and Andersson, Patrik and Kropp, Wolfgang},

title={An impedance matching technique for active-passive vibration control},

booktitle={Acoustics 08, Paris, June 29-July 4, 2008},

abstract={Impedance matching techniques have shown potential for active vibration control of structures in bending. Such structures are commonly described by Euler-Bernoulli theory. Previous studies concerning impedance matching of these structures have only considered scalar quantities. However, for an Euler-Bernoulli beam four field variables are involved which implies that a scalar impedance is insufficient. The purpose of this study is therefore to expand the technique to include full 2x2 matrices. This is achieved by first deriving the reflection matrix as a function of the characteristic impedance matrices of an Euler-Bernoulli beam and an arbitrary termination impedance. An active impedance load is then introduced in order to manipulate the reflection matrix. A theoretical example is given where the approach is utilized to match the junction between an Euler-Bernoulli beam and a sandwich composite. This proposed active-passive damping configuration employs active control to enclose all incident power in the sandwich composite. Results show that the active impedance load is responsible for the main part of the power absorption over a broad frequency range.},

year={2008},

}

** RefWorks **

RT Conference Proceedings

SR Print

ID 73265

A1 Svensson, Jonas

A1 Andersson, Patrik

A1 Kropp, Wolfgang

T1 An impedance matching technique for active-passive vibration control

YR 2008

T2 Acoustics 08, Paris, June 29-July 4, 2008

AB Impedance matching techniques have shown potential for active vibration control of structures in bending. Such structures are commonly described by Euler-Bernoulli theory. Previous studies concerning impedance matching of these structures have only considered scalar quantities. However, for an Euler-Bernoulli beam four field variables are involved which implies that a scalar impedance is insufficient. The purpose of this study is therefore to expand the technique to include full 2x2 matrices. This is achieved by first deriving the reflection matrix as a function of the characteristic impedance matrices of an Euler-Bernoulli beam and an arbitrary termination impedance. An active impedance load is then introduced in order to manipulate the reflection matrix. A theoretical example is given where the approach is utilized to match the junction between an Euler-Bernoulli beam and a sandwich composite. This proposed active-passive damping configuration employs active control to enclose all incident power in the sandwich composite. Results show that the active impedance load is responsible for the main part of the power absorption over a broad frequency range.

LA eng

OL 30