Role of endothelial cells in cardiovascular function

A comprehensive review on modal parameter-based damage identification methods for beam-or plate-type structures is presented, and the damage identification algorithms in terms of signal processing are particularly emphasized. Based on the vibration features, the damage identification methods are classified into four major categories: natural frequency-based methods, mode shape-based methods, curvature mode shape-based methods, and methods using both mode shapes and frequencies, and their merits and drawbacks are discussed. It is observed that most mode shape-based and curvature mode shape-based methods only focus on damage localization. In order to precisely locate the damage, the mode shape-based methods have to rely on optimization algorithms or signal processing techniques; while the curvature mode shape-based methods are in general a very effective type of damage localization algorithms. As an implementation, a comparative study of five extensively-used damage detection algorithms for beam-type structures is conducted to evaluate and demonstrate the validity and effectiveness of the signal processing algorithms. This brief review aims to help the readers in identifying starting points for research in vibration-based damage identification and structural health monitoring and guides researchers and practitioners in better implementing available damage identification algorithms and signal processing methods for beam-or plate-type structures.

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Modeling and characterization of fiber-reinforced plastic honeycomb sandwich panels for highway bridge applications

Davalos

Qiao

et al. 2001

Composite Structures

205

125

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Curvature mode shape-based damage detection in composite laminated plates

Qiao

Lestari

et al. 2007

Composite Structures

210

123

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Interface crack between two shear deformable elastic layers

Wang

Qiao

2004

Journal of the Mechanics and Physics of Solids

101

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Mechanics and fracture of crack tip deformable bi-material interface

Qiao

Wang

2004

International Journal of Solids and Structures

100

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An improved peridynamic approach for quasi-static elastic deformation and brittle fracture analysis

Huang

Qiao

2015

International Journal of Mechanical Sciences

201

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Experimental Damage Identification of Carbon/Epoxy Composite Beams Using Curvature Mode Shapes

Hamey¹,

Lestari

Qiao

et al. 2004

Structural Health Monitoring

123

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Many composite materials and structures are susceptible to defects, which can significantly reduce the strength of structures and may grow to failure. To avoid the catastrophic failure of structures, development of a reliable method of structural health monitoring is one of the most important keys in maintaining the integrity and safety of structures. Dynamic response-based damage detection offers a simple procedure as an alternative to the conventional nondestructive evaluation techniques. However, this technique depends on the quality of measured data for its identification accuracy. In this article, experimental aspects of dynamic response-based damage detection technique on carbon/ epoxy composites are addressed. Smart piezoelectric materials are used as sensors or actuators to acquire the curvature modes of structures. These materials are surface-bonded to the beams. An impulse hammer is used as an actuating source as well. Four types of damage detection algorithms are evaluated for several possible damage configurations with two different excitation sources. The quality of damage identification with the four different detection algorithms is discussed. These experimental damage identification techniques using curvature modes and piezoelectric materials can be effectively used in damage detection and health monitoring of composite structures.

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Impact Mechanics and High-Energy Absorbing Materials: Review

2008

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Pizhong Qiao

Vibration-based Damage Identification Methods: A Review and Comparative Study

Modeling and characterization of fiber-reinforced plastic honeycomb sandwich panels for highway bridge applications

Curvature mode shape-based damage detection in composite laminated plates

Interface crack between two shear deformable elastic layers

Mechanics and fracture of crack tip deformable bi-material interface

An improved peridynamic approach for quasi-static elastic deformation and brittle fracture analysis

Experimental Damage Identification of Carbon/Epoxy Composite Beams Using Curvature Mode Shapes

Impact Mechanics and High-Energy Absorbing Materials: Review

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