Structural health monitoring of a 250‐m super‐tall building and operational modal analysis using the fast Bayesian FFT method

Zhang, Feng‐Liang; Yang, Yanping; Xiong, Haibei; Yang, Jie; Yu, Zhi

doi:10.1002/stc.2383

Cited by 31 publications

(25 citation statements)

References 53 publications

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“…Under such circumstances, civil structures may seriously suffer from damage and subsequently trigger catastrophic failure and even collapse. To ensure the health and safety of such structural systems and reduce economic and human losses caused by the occurrence of damage, structural health monitoring (SHM) is a great necessity for every society with any culture, geographical location, and economic development 1–5 . In fact, SHM is an emergent and diagnostic tool for damage detection and structural condition assessment.…”

Section: Introductionmentioning

confidence: 99%

Ensemble learning‐based structural health monitoring by Mahalanobis distance metrics

Sarmadi

Entezami

Razavi³

et al. 2020

Struct Control Health Monit

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Section: Introductionmentioning

confidence: 99%

Ensemble learning‐based structural health monitoring by Mahalanobis distance metrics

Sarmadi

Entezami

Razavi³

et al. 2020

Struct Control Health Monit

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“…Generally, conventional signal processing techniques such as Fast Fourier Transform (FFT) [1][2][3], and Short-Time Fourier Transform (STFT) [4,5] are employed to analyze the linear and stationary signals. However, the responses of structures in the real world are inherently nonlinear according to structural health monitoring systems [6,7] and non-stationary.…”

Section: Introductionmentioning

confidence: 99%

Structural Damage Localization and Quantification Based on a CEEMDAN Hilbert Transform Neural Network Approach: A Model Steel Truss Bridge Case Study

Mousavi

Zhang

Masri

et al. 2020

Sensors

111

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Vibrations of complex structures such as bridges mostly present nonlinear and non-stationary behaviors. Recently, one of the most common techniques to analyze the nonlinear and non-stationary structural response is Hilbert–Huang Transform (HHT). This paper aims to evaluate the performance of HHT based on complete ensemble empirical mode decomposition with adaptive noise (CEEMDAN) technique using an Artificial Neural Network (ANN) as a proposed damage detection methodology. The performance of the proposed method is investigated for damage detection of a scaled steel-truss bridge model which was experimentally established as the case study subjected to white noise excitations. To this end, four key features of the intrinsic mode function (IMF), including energy, instantaneous amplitude (IA), unwrapped phase, and instantaneous frequency (IF), are extracted to assess the presence, severity, and location of the damage. By analyzing the experimental results through different damage indices defined based on the extracted features, the capabilities of the CEEMDAN-HT-ANN model in detecting, addressing the location and classifying the severity of damage are efficiently concluded. In addition, the energy-based damage index demonstrates a more effective approach in detecting the damage compared to those based on IA and unwrapped phase parameters.

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“…Whilst the latter is time-consuming and not suitable for quantitative analysis, image analysis-based detection techniques, on the other hand, can be quite challenging and fully dependent on the quality of images taken under different real-world situations (e.g., light, shadow, noise, etc.). In recent years, researchers have experimented with the application of a number of soft computing and machine learning-based detection techniques as an attempt to increase the level of automation of asset condition inspection [13,14,15,16,17,18,19,20]. The notable efforts include; structural health monitoring with Bayesian method [13], surface crack estimation using Gaussian regression, support vector machines (SVM), and neural networks [14], SVM for wall defects recognition [15], crack-detection on concrete surfaces using deep belief networks (DBN) [16], crack detection in oak flooring using ensemble methods of random forests (RF) [17], deterioration assessment using fuzzy logic [18], defect detection of ashlar masonry walls using logistic regression [19,20].…”

Section: Introductionmentioning

confidence: 99%

“…In recent years, researchers have experimented with the application of a number of soft computing and machine learning-based detection techniques as an attempt to increase the level of automation of asset condition inspection [13,14,15,16,17,18,19,20]. The notable efforts include; structural health monitoring with Bayesian method [13], surface crack estimation using Gaussian regression, support vector machines (SVM), and neural networks [14], SVM for wall defects recognition [15], crack-detection on concrete surfaces using deep belief networks (DBN) [16], crack detection in oak flooring using ensemble methods of random forests (RF) [17], deterioration assessment using fuzzy logic [18], defect detection of ashlar masonry walls using logistic regression [19,20]. The literature also includes a number of papers devoted to the detection of defects in infrastructural assets such as cracks in road surfaces, bridges, dams, and sewerage pipelines [21,22,23,24,25,26,27,28,29,30].…”

Section: Introductionmentioning

confidence: 99%

Deep Learning for Detecting Building Defects Using Convolutional Neural Networks

Perez

Tah

Mosavi

2019

Sensors

154

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Clients are increasingly looking for fast and effective means to quickly and frequently survey and communicate the condition of their buildings so that essential repairs and maintenance work can be done in a proactive and timely manner before it becomes too dangerous and expensive. Traditional methods for this type of work commonly comprise of engaging building surveyors to undertake a condition assessment which involves a lengthy site inspection to produce a systematic recording of the physical condition of the building elements, including cost estimates of immediate and projected long-term costs of renewal, repair and maintenance of the building. Current asset condition assessment procedures are extensively time consuming, laborious, and expensive and pose health and safety threats to surveyors, particularly at height and roof levels which are difficult to access. This paper aims at evaluating the application of convolutional neural networks (CNN) towards an automated detection and localisation of key building defects, e.g., mould, deterioration, and stain, from images. The proposed model is based on pre-trained CNN classifier of VGG-16 (later compaired with ResNet-50, and Inception models), with class activation mapping (CAM) for object localisation. The challenges and limitations of the model in real-life applications have been identified. The proposed model has proven to be robust and able to accurately detect and localise building defects. The approach is being developed with the potential to scale-up and further advance to support automated detection of defects and deterioration of buildings in real-time using mobile devices and drones.

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Structural health monitoring of a 250‐m super‐tall building and operational modal analysis using the fast Bayesian FFT method

Cited by 31 publications

References 53 publications

Ensemble learning‐based structural health monitoring by Mahalanobis distance metrics

Ensemble learning‐based structural health monitoring by Mahalanobis distance metrics

Structural Damage Localization and Quantification Based on a CEEMDAN Hilbert Transform Neural Network Approach: A Model Steel Truss Bridge Case Study

Deep Learning for Detecting Building Defects Using Convolutional Neural Networks

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