Damage Detection in a Glass Plate Using Outlier Analysis

Kai Yang; Keith Worden; Jem A. Rongong

doi:10.4028/www.scientific.net/KEM.569-570.847

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Sensor Fusion on Structural Monitoring Data Analysis: Application to a Cable-Stayed Bridge
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Damage Detection of a Substructure Based on Response Reconstruction in Frequency Domain
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Integrating Singular Spectrum Analysis with Damage Detection of Structure
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A Two-Stage Scheme for Plate Damage Identification Based on Lock-in Thermography and Dynamic Analysis
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Damage Detection in a Glass Plate Using Outlier Analysis
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Numerical Studies on Wavelet-Based Crack Detection Based on Velocity Response of a Beam Subjecting to Moving Load
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Two Dimensional Damage Localization Using the Interpolation Method
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Spatial Filter for Operational Deflection Shape Component Filtration
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Damage Detection in Nonlinear Structures Using Discrete-Time Volterra Series
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HomeKey Engineering MaterialsKey Engineering Materials Vols. 569-570Damage Detection in a Glass Plate Using Outlier...

Damage Detection in a Glass Plate Using Outlier Analysis

Abstract:

This work constitutes a damage detection study of a glass plate using the statistical approach of outlier analysis, which is also referred to here as novelty detection. A glass plate instrumented with low-profile, surface-bonded transducers is used in the investigation. Ultrasonic Lamb waves are applied for detecting various crack length on the same plate. The study reveals a distinction between the damage and undamaged plate, and also assesses the severity of damage.

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Periodical:

Key Engineering Materials (Volumes 569-570)

Pages:

847-853

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.569-570.847

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Online since:

July 2013

Authors:

Kai Yang, Keith Worden, Jem A. Rongong

Keywords:

Damage Detection, Glass Plate, Lamb Wave, Outlier Analysis

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