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Structural Health Monitoring Using Ultrasonic Guided-Waves and the Degree of Health Index

Overview
Journal Sensors (Basel)
Publisher MDPI
Specialty Biotechnology
Date 2021 Feb 5
PMID 33540636
Citations 6
Authors
Sergio Cantero-Chinchilla
Gerardo Aranguren
Jose Manuel Royo
Manuel Chiachio
Josu Etxaniz
Andrea Calvo-Echenique
Affiliations
Soon will be listed here.
Abstract

This paper proposes a new damage index named (DoH) to efficiently tackle structural damage monitoring in real-time. As a key contribution, the proposed index relies on a pattern matching methodology that measures the time-of-flight mismatch of sequential ultrasonic guided-wave measurements using fuzzy logic fundamentals. The ultrasonic signals are generated using the transmission beamforming technique with a phased-array of piezoelectric transducers. The acquisition is carried out by two phased-arrays to compare the influence of pulse-echo and pitch-catch modes in the damage assessment. The proposed monitoring approach is illustrated in a fatigue test of an aluminum sheet with an initial notch. As an additional novelty, the proposed pattern matching methodology uses the data stemming from the transmission beamforming technique for structural health monitoring. The results demonstrate the efficiency and robustness of the proposed framework in providing a qualitative and quantitative assessment for fatigue crack damage.

Citing Articles

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Lamb Wave Detection for Structural Health Monitoring Using a ϕ-OTDR System.

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Damage Detection of Regular Civil Buildings Using Modified Multi-Scale Symbolic Dynamic Entropy.

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Methodology for Detecting Progressive Damage in Structures Using Ultrasound-Guided Waves.

Aranguren G, Bilbao J, Etxaniz J, Gil-Garcia J, Rebollar C Sensors (Basel). 2022; 22(4).

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Structural engineering from an inverse problems perspective.

Gallet A, Rigby S, Tallman T, Kong X, Hajirasouliha I, Liew A Proc Math Phys Eng Sci. 2022; 478(2257):20210526.

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References
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