Shear loading detection of through bolts in bridge structures using a percussion‐based one‐dimensional memory‐augmented convolutional neural network

Wang, Furui; Song, Gangbing; Mo, Y. L.

doi:10.1111/mice.12602

Cited by 49 publications

(30 citation statements)

References 62 publications

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“…In the context of novelty detection, novel neural network architectures, such as CNN and RNN, were practised in the literature. For instance, CNNs were operated on both 1D signals (F. Wang et al., 2021), and 2D images (Guo et al., 2021; N. Wang et al., 2020). 2D CNN can also receive sensors’ data in the format of a 2D grid (Sajedi & Liang, 2020, 2021), preserving the spatial distribution of sensors.…”

Section: Methodsmentioning

confidence: 99%

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Toward a general unsupervised novelty detection framework in structural health monitoring

Soleimani‐Babakamali

Sepasdar

Nasrollahzadeh

et al. 2022

Computer aided Civil Eng

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This study proposes an unsupervised, online structural health monitoring framework robust to the sensor configuration, that is, the number and placement of sensors. The proposed methodology leverages generative adversarial networks (GANs). The GAN's discriminator network is the novelty detector, while its generator provides additional data to tune the detection threshold. GAN models are trained with the fast Fourier transform of structural accelerations as input, avoiding the need for any structure-specific feature extraction. Dense, convolutional (convolutional neural network), and long short-term memory (LSTM) units are evaluated as discriminators under different GAN training loss patterns, that is, the differences between discriminator and generator training losses. Resultsshow that the LSTM-based discriminators and the suggested threshold tuning technique to be robust even in loss patterns with overfitted discriminators, a probable outcome of limited training sets. The framework is evaluated on two benchmark datasets. With only 100 s of training data, it achieved 95% novelty detection accuracy, distinguishing between different damage classes and identifying their resurgence under varying sensor configurations. Finally, the majorityvote-ensemble of discriminator-generator pairs at different training epochs is introduced to reduce false alarms, improve novelty detection accuracy and stability.

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Section: Methodsmentioning

confidence: 99%

Section: Gan Architecturementioning

confidence: 99%

Toward a general unsupervised novelty detection framework in structural health monitoring

Soleimani‐Babakamali

Sepasdar

Nasrollahzadeh

et al. 2022

Computer aided Civil Eng

View full text Add to dashboard Cite

show abstract

“…The GCN was first proposed by LeCun et al. (1998) as inspired by the motivation of the CNN (Guo et al., 2020, 2021; Jeong et al., 2020; Tang et al., 2021; F. Wang et al., 2021). Graph neural network is a special neural network that can directly operate on graphic structural data.…”

Section: Gcn‐drl Modelmentioning

confidence: 99%

A graph convolution network‐deep reinforcement learning model for resilient water distribution network repair decisions

Fan

Zhang

2022

Computer aided Civil Eng

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Water distribution networks (WDNs) are critical infrastructure for communities. The dramatic expansion of the WDNs associated with urbanization makes them more vulnerable to high-consequence hazards such as earthquakes, which requires strategies to ensure their resilience. The resilience of a WDN is related to its ability to recover its service after disastrous events. Sound decisions on the repair sequence play a crucial role to ensure a resilient WDN recovery. This paper introduces the development of a graph convolutional neural network-integrated deep reinforcement learning (GCN-DRL) model to support optimal repair decisions to improve WDN resilience after earthquakes. A WDN resilience evaluation framework is first developed, which integrates the dynamic evolution of WDN performance indicators during the post-earthquake recovery process. The WDN performance indicator considers the relative importance of the service nodes and the extent of post-earthquake water needs that are satisfied. In this GCN-DRL model framework, the GCN encodes the information of the WDN. The topology and performance of service nodes (i.e., the degree of water that needs satisfaction) are inputs to the GCN; the outputs of GCN are the reward values (Q-values) corresponding to each repair action, which are fed into the DRL process to select the optimal repair sequence from a large action space to achieve highest system resilience. The GCN-DRL model is demonstrated on a testbed WDN subjected to three earthquake damage scenarios. The performance of the repair decisions by the GCN-DRL model is compared with those by four conventional decision methods. The results show that the recovery sequence by the GCN-DRL model achieved the highest system resilience index values and the fastest recovery of system performance. Besides, by using transfer learning based on a pre-trained model, the GCN-DRL model achieved high computational efficiency in determining the optimal repair sequences under new damage scenarios. This novel GCN-DRL model features robustness and universality to support optimal repair decisions to ensure resilient WDN recovery from earthquake damages.

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“…It is vital to mention that multiple AI techniques have been incorporated to explain the solutions based on civil engineering problems amongst various machine learning (ML) algorithms [ 11 , 12 , 13 ]. Moreover, complex engineering problems can be simplified by utilizing the pattern recognition abilities of common AI algorithms [ 14 , 15 , 16 , 17 , 18 ]. Therefore, typical features of conventional AI techniques, i.e., Neural Network (NN), have been extensively employed by researchers to model various mechanical properties of concrete.…”

Section: Introductionmentioning

confidence: 99%

Forecasting Strength of CFRP Confined Concrete Using Multi Expression Programming

et al. 2021

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This study provides the application of a machine learning-based algorithm approach names “Multi Expression Programming” (MEP) to forecast the compressive strength of carbon fiber-reinforced polymer (CFRP) confined concrete. The suggested computational Multiphysics model is based on previously reported experimental results. However, critical parameters comprise both the geometrical and mechanical properties, including the height and diameter of the specimen, the modulus of elasticity of CFRP, unconfined strength of concrete, and CFRP overall layer thickness. A detailed statistical analysis is done to evaluate the model performance. Then the validation of the soft computational model is made by drawing a comparison with experimental results and other external validation criteria. Moreover, the results and predictions of the presented soft computing model are verified by incorporating a parametric analysis, and the reliability of the model is compared with available models in the literature by an experimental versus theoretical comparison. Based on the findings, the valuation and performance of the proposed model is assessed with other strength models provided in the literature using the collated database. Thus the proposed model outperformed other existing models in term of accuracy and predictability. Both parametric and statistical analysis demonstrate that the proposed model is well trained to efficiently forecast strength of CFRP wrapped structural members. The presented study will promote its utilization in rehabilitation and retrofitting and contribute towards sustainable construction material.

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Shear loading detection of through bolts in bridge structures using a percussion‐based one‐dimensional memory‐augmented convolutional neural network

Cited by 49 publications

References 62 publications

Toward a general unsupervised novelty detection framework in structural health monitoring

Toward a general unsupervised novelty detection framework in structural health monitoring

A graph convolution network‐deep reinforcement learning model for resilient water distribution network repair decisions

Forecasting Strength of CFRP Confined Concrete Using Multi Expression Programming

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