Development of Structural Damage Detection Method Working with Contaminated Vibration Data via Autoencoder and Gradient Boosting

Vibration-based structural damage detection is one of the most promising venues for building smart and automated structural health monitoring applications; however, its applicability is impeded by a large amount of collected vibration data, and the performance could be undermined by degraded data. T...

Full description

Saved in:
Bibliographic Details
Published inPeriodica polytechnica. Civil engineering. Bauingenieurwesen Vol. 67; no. 3; p. 875
Main Author Dang, Viet-Hung
Format Journal Article
LanguageEnglish
German
Russian
Published Budapest Periodica Polytechnica, Budapest University of Technology and Economics 01.07.2023
Subjects
Algorithms
Case studies
Civil engineering
Coders
Contamination
Damage detection
Deep learning
Detection
Feature extraction
Frame structures
Frameworks
Human error
Machine learning
Missing data
Neural networks
Noise
Robustness (mathematics)
Sensors
Signal processing
Structural damage
Structural health monitoring
Vectors
Vibration
Vibration monitoring
Online AccessGet full text

Cover

More Information
Summary:Vibration-based structural damage detection is one of the most promising venues for building smart and automated structural health monitoring applications; however, its applicability is impeded by a large amount of collected vibration data, and the performance could be undermined by degraded data. Therefore, this study develops a robust framework, dubbed AutoBoost-SDD, that can effectively handle contaminated vibration data and provide reliable monitoring results within reasonable computational resources. The proposed method consists of three key components. Firstly, multi-domain feature extraction techniques are utilized to convert high-dimensional raw data into informative feature vectors. Secondly, the auto-encoder deep learning architecture is leveraged to refine feature vectors of contaminated data. Finally, a tree-based boosting machine learning algorithm, namely LightGBM, is employed to assess the structures’ operational states using learned output from the second step. The viability and performance of the proposed framework are illustrated via three case studies involving numerical data of a 5-degree of freedom system, a 2D frame structure, and experimental data of a large-scale 18-story frame structure from the literature. The results show that the AutoBoost-SDD framework is able to provide reasonable detection results despite the presence of various contaminations, including noisy, missing, and anomalous data.
ISSN:0553-6626
1587-3773
DOI:10.3311/PPci.22373