Article: Active vibration control of a thick piezolaminated beam with imperfectly integrated sensor and actuator layers Journal: International Journal of Automation and Control (IJAAC) 2014 Vol.8 No.1 pp.58 - 87 Abstract: A spatial state-space formulation based on the linear two-dimensional piezoelasticity theory and involving local/global transfer matrices is applied to investigate the active vibration suppression of a simply supported, arbitrarily thick, orthotropic elastic beam, imperfectly integrated with spatially distributed piezoelectric actuator and sensor layers on its top and bottom surfaces, respectively. A linear spring-layer model is adopted to simulate the bonding imperfections between the host structure and the piezoelectric layers. To assist control system design, system identification is conducted by applying a frequency domain subspace approximation method with N4SID algorithm. The state space model is constructed from system identification and used for state estimation and development of control algorithm. A linear quadratic Gaussian (LQG) controller is subsequently designed and simulated based on the identified model in order to actively control the response of the smart structure. The accuracy of analysis is established with the aid of a commercial finite element package. Inderscience Publishers - linking academia, business and industry through research

Title: Active vibration control of a thick piezolaminated beam with imperfectly integrated sensor and actuator layers

Authors: Seyyed M. Hasheminejad; Mohammad Vahedi

Addresses: Acoustics Research Laboratory, Center of Excellence in Experimental Solid Mechanics and Dynamics, School of Mechanical Engineering, Iran University of Science and Technology, Narmak, Tehran 16846-13114, Iran ' Acoustics Research Laboratory, Center of Excellence in Experimental Solid Mechanics and Dynamics, School of Mechanical Engineering, Iran University of Science and Technology, Narmak, Tehran 16846-13114, Iran

Abstract: A spatial state-space formulation based on the linear two-dimensional piezoelasticity theory and involving local/global transfer matrices is applied to investigate the active vibration suppression of a simply supported, arbitrarily thick, orthotropic elastic beam, imperfectly integrated with spatially distributed piezoelectric actuator and sensor layers on its top and bottom surfaces, respectively. A linear spring-layer model is adopted to simulate the bonding imperfections between the host structure and the piezoelectric layers. To assist control system design, system identification is conducted by applying a frequency domain subspace approximation method with N4SID algorithm. The state space model is constructed from system identification and used for state estimation and development of control algorithm. A linear quadratic Gaussian (LQG) controller is subsequently designed and simulated based on the identified model in order to actively control the response of the smart structure. The accuracy of analysis is established with the aid of a commercial finite element package.

Keywords: piezocomposite beams; interfacial imperfection; exact solution; system identification; disturbance attenuation; optimal control; Kalman observer; active control; vibration control; sensors; piezoelectric actuators; piezoelasticity; transfer matrices; modelling; simulation; control system design; finite element analysis; FEA; linear quadratic Gaussian; LQG control; controller design.

DOI: 10.1504/IJAAC.2014.061662

International Journal of Automation and Control, 2014 Vol.8 No.1, pp.58 - 87

Received: 22 Dec 2012
Accepted: 02 Jun 2013
Published online: 30 Jun 2014 *

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Title: Active vibration control of a thick piezolaminated beam with imperfectly integrated sensor and actuator layers

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