Effective Crack Damage Detection Using Multilayer Sparse Feature Representation and Incremental Extreme Learning Machine

Effective Crack Damage Detection Using Multilayer Sparse Feature Representation and Incremental Extreme Learning Machine

Detecting cracks within reinforced concrete is still a challenging problem, owing to the complex disturbances from the background noise. In this work, we advocate a new concrete crack damage detection model, based upon multilayer sparse feature representation and an incremental extreme learning mach...

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Bibliographic Details
Published in:Applied sciences Vol. 9; no. 3; p. 614
Main Authors: Wang, Baoxian, Li, Yiqiang, Zhao, Weigang, Zhang, Zhaoxi, Zhang, Yufeng, Wang, Zhe
Format: Journal Article
Language:English
Published: Basel MDPI AG 12-02-2019
Subjects:
Algorithms
Background noise
Big Data
Classification
Concrete
crack damage detection
Cracks
Damage detection
Deep learning
extreme learning machine
Fault diagnosis
feature classification
Feature recognition
Fracture mechanics
Identification
Image rotation
Learning algorithms
Methods
multilayer feature learning
Multilayers
Neural networks
Reinforced concrete
Representations
Sensors
sparse autoencoder
Stress concentration
Wavelet transforms
China
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Summary:Detecting cracks within reinforced concrete is still a challenging problem, owing to the complex disturbances from the background noise. In this work, we advocate a new concrete crack damage detection model, based upon multilayer sparse feature representation and an incremental extreme learning machine (ELM), which has both favorable feature learning and classification capabilities. Specifically, by cropping and using a sliding window operation and image rotation, a large number of crack and non-crack patches are obtained from the collected concrete images. With the existing image patches, the defect region features can be quickly calculated by the multilayer sparse ELM autoencoder networks. Then, the online incremental ELM classified network is used to recognize the crack defect features. Unlike the commonly-used deep learning-based methods, the presented ELM-based crack detection model can be trained efficiently without tediously fine-tuning the entire-network parameters. Moreover, according to the ELM theory, the proposed crack detector works universally for defect feature extraction and detection. In the experiments, when compared with other recently developed crack detectors, the proposed concrete crack detection model can offer outstanding training efficiency and favorable crack detecting accuracy.
ISSN:2076-3417
2076-3417
DOI:10.3390/app9030614