Unsupervised deep learning approach using a deep auto-encoder with a one-class support vector machine to detect damage

Wang, Zilong; Cha, Young‐Jin

doi:10.1177/1475921720934051

Cited by 191 publications

(109 citation statements)

References 41 publications

(59 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…A one-class support vector machine (OC-SVM) is then served as the damage detector on the basis of the extracted features. Wang and Cha [24] also propose a damage detection method integrated with an autoencoder and an OC-SVM. The autoencoder is designed to acquire features related to the damage information from the acceleration signals, while the OC-SVM is a classifier that determines damage states of samples.…”

Section: B Deep Learning Methodsmentioning

confidence: 99%

“…After each excitation, the building is exposed to the same random white noise to record its ambient response, which is supposed to significantly vary as excitation intensity increases. [24]. Given that the frequency is proportional to √ [33]- [34], where is the stiffness of building, therefore, the stiffness of building degrades by 23.1%, 34.5%, and 44.3% after excitations with 25%, 50%, and 100% intensities compared with the undamaged state.…”

Section: A Datasetmentioning

confidence: 99%

See 1 more Smart Citation

A Deep Learning-Based Framework for Damage Detection With Time Series

et al. 2021

View full text Add to dashboard Cite

Natural hazards have caused damages to buildings and infrastructures and economic losses in many countries. Immediate emergency response requires accurate damage detection. In recent studies, advances in deep learning approaches have put forward the development of data-driven damage detection. However, these proposed approaches can successfully classify damaged samples into different damage states without quantifying them. Therefore, we propose a deep learning-based framework for damage detection, which comprises signal processing and damage recognition modules. The signal processing module is introduced to denoise the noisy signals collected from sensors and process the denoised signals via fast Fourier transform. The damage recognition module is characterized by a novel network with the architecture of encoder-decoder-encoder. We train the network with only undamaged samples to capture the pattern in the undamaged state. In the testing stage, given an unknown damage state, we feed damaged samples into the trained network to quantify it by outputting the corresponding probability of damage. We conduct experiments to verify the validity and feasibility of the proposed framework with a dataset of a building subjected to excitations. Our approach can map samples from various damage states to a specific probability of damage, which increases as the intensity of excitation increases. INDEX TERMSEncoder-decoder-encoder, Damage detection, Deep learning, Probability of damage, Signal processing.

show abstract

Section: B Deep Learning Methodsmentioning

confidence: 99%

Section: A Datasetmentioning

confidence: 99%

A Deep Learning-Based Framework for Damage Detection With Time Series

et al. 2021

View full text Add to dashboard Cite

show abstract

“…이러한 대형구조물의 사용연한 증가는 구조물의 유지 보수 및 성능 평가에 대한 중요성을 부각시켰 으며, 이에 따라 성능 평가를 위한 정확한 모델 개발의 필요성 이 증가하고 있다 (Gong and Park, 2019). 2015년 서해대교에 서 낙뢰로 인해 케이블이 파단되었을 때, 현재 상태를 반영하 는 사용 가능한 유한요소모델의 개발에 72시간 이상의 시간 이 소요된 것으로 파악되었으며 (Gil et al, 2016), 소록대교의 구조식별 작업에 준비 단계를 제외한 순수 계측 및 분석에 약 2일이 소요되었고, 모델 업데이팅 작업의 최적화 프로그 램 실행에 약 2일이 소요된 것으로 알려져 있다 (Sung, 2018 (Lin et al, 2017;Tran-Ngoc et al, 2018;Yoon et al, 2018;Lim and Yoon, 2019;Wang and Cha, 2020).…”

Section: 서 론unclassified

Development of FE Model Updating for Three-Story Building considering Soil-Structure Interaction

Park¹,

Jung²,

Yoon³

2020

J. Korean Soc. Hazard Mitig

View full text Add to dashboard Cite

Owing to the development of construction technology, structures are becoming increasingly taller. Furthermore, with the improvement in construction materials, the service life of the structures is also increasing. The increased service life of large structures has highlighted the importance of structure maintenance and performance evaluation; thus, the need for an accurate model development for performance evaluation is increasing. This study predicts the structural characteristics through finite element (FE) model updating using a genetic algorithm (GA). The GA was applied to determine whether the structural member was damaged. In particular, it is intended to improve the reliability of the FE model updating during a seismic load by considering the soil-structure interaction effect that has been overlooked in the existing model updating study. The results of this study show that the model that considers the soil-structure interaction can estimate the dynamic characteristics of the structure more accurately compared to the model that does not consider the soil-structure interaction. The accuracy of the updated parameters by the proposed method was found to be over 90%.

show abstract

“…In this context, focusing on the feature classification for damage detection, AE models have been used for automatic and semi‐automatic feature extraction. In Wang and Cha, 36 Wang et al utilized a seven‐layer autoencoder trained with undamaged acceleration data as an automatic extractor of damage‐sensitive features and an one‐class support vector machine algorithm (OC‐SVM) for statistical modeling and feature classification. After the training, the test step is carried out with data from unknown health states.…”

Section: Introductionmentioning

confidence: 99%

Damage‐sensitive feature extraction with stacked autoencoders for unsupervised damage detection

Silva

Santos

et al. 2021

Struct Control Health Monit

View full text Add to dashboard Cite

Summary In most real‐world monitoring scenarios, the lack of measurements from damaged conditions requires the application of unsupervised approaches, mainly the ones based on modal features estimated from raw vibration data through traditional system identification methods. Although numerous successful applications using modal parameters have been reported, they have demonstrated to be insufficient to estimate a robust set of damage‐sensitive features. Inspired by the idea of compressed sensing and deep learning, an intelligent two‐level feature extraction approach using stacked autoencoders over pre‐processed vibration data is proposed. This procedure can improve the performance of traditional damage detection classifiers by compressing modal parameters into a smaller set of highly informative features when considering information entropy metrics. The proposed technique demonstrates significant improvement in the performance of damage detection and classification approaches when evaluated on the well‐known monitoring data sets from the Z‐24 Bridge, where several damage scenarios were carried out under rigorous operational and environmental effects.

show abstract

Unsupervised deep learning approach using a deep auto-encoder with a one-class support vector machine to detect damage

Cited by 191 publications

References 41 publications

A Deep Learning-Based Framework for Damage Detection With Time Series

A Deep Learning-Based Framework for Damage Detection With Time Series

Development of FE Model Updating for Three-Story Building considering Soil-Structure Interaction

Damage‐sensitive feature extraction with stacked autoencoders for unsupervised damage detection

Contact Info

Product

Resources

About