Fibre Bragg grating sensor-based damage response monitoring of an asymmetric reinforced concrete shear wall structure subjected to progressive seismic loads

Zhang, Chunwei; Alam, Zeshan; Sun, Li; Su, Zhongxin; Samali, Bijan

doi:10.1002/stc.2307

Cited by 93 publications

(23 citation statements)

References 59 publications

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“…As such, based on extensive research, various seismic design and rehabilitation methods for buildings have been developed and refined . However, EQ‐induced structural damage continues to occur because the basic concept of seismic engineering is based on probability theory, and EQ occurrence prediction involves many uncertainties . In particular, when seismic damage occurs to a building, future use of that building may be restricted, causing inconvenience for occupants and financial problems.…”

Section: Introductionmentioning

confidence: 99%

“…[1][2][3] However, EQ-induced structural damage continues to occur because the basic concept of seismic engineering is based on probability theory, and EQ occurrence prediction involves many uncertainties. 4 In particular, when seismic damage occurs to a building, future use of that building may be restricted, causing inconvenience for occupants and financial problems. Thus, prompt and adequate strategies for seismic performance evaluation are required to retrofit or reuse the building.…”

Section: Introductionmentioning

confidence: 99%

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Seismic response prediction method for building structures using convolutional neural network

Park

2020

Struct Control Health Monit

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Summary In this study, a method of predicting the seismic responses of building structures based on a convolutional neural network (CNN) is proposed. In the method, the time histories of acceleration responses previously measured in a building during earthquakes are used in the CNN input layer, with the corresponding time histories of the displacement responses being used in the CNN output layer. The correlations between the features automatically extracted from the acceleration responses by the convolution and pooling operations in the various CNN layers and the displacement responses in the CNN output layer are established through CNN training. The trained CNN predicts the displacement responses for a future earthquake event using only the measured acceleration responses. To verify the validity of the proposed method, a numerical study on the ASCE benchmark model and an experimental study on a reinforced concrete frame structure are conducted. In the numerical study, the structural responses of the ASCE model subject to artificial earthquakes are utilized for CNN training, and the performance of the trained CNN is verified through seismic response prediction. In the experimental study, shaking table tests are performed for various earthquakes to measure the seismic responses of the reinforced concrete test structure. The seismic response prediction performance of the proposed method is examined using CNN trained with the measured seismic responses. Furthermore, the performances of CNNs trained with different numbers of datasets generated by the proposed data generation method based on data overlapping with the same data pool are discussed with related to the number of CNN training iteration number.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Seismic response prediction method for building structures using convolutional neural network

Park

2020

Struct Control Health Monit

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“…The production of sisal fiber as compared with synthetic fibers or even with asbestos fibers needs much less energy in addition to the ecological, social and economical benefits. Among all the natural fibers, sisal fiber can be used as reinforcing material due to its high strength and stiffness (Zhao,Li & Bai, 2014;Zhang, Alam, Sun, Su, &Samali, 2018). The addition of sisal fiber in concrete improves compressive strength and flexural strength (Bao& Li, 2010).…”

Section: Introductionmentioning

confidence: 99%

Mechanical and flexural performance of self compacting concrete with natural fiber

Kavitha

Venkatesan

Avudaiappan

et al. 2020

rdlc

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This paper investigates the effect of sisal fiber addition on fresh ,mechanical properties of self compacting concrete(SCC) and flexural performance of fiber reinforced RC beams made with mineral admixtures like Meta Kaolin (MK) and Fly Ash (FA)which is an industrial waste. The mixes were prepared by varying MK content from 5% to 15% with 5% increment with constant fly ash content of 30%. The results reveal that increasing the content of MK beyond 10% leads to reduction in strength. And also the negative influence of MK and fiber addition on workability performance was overcome by the addition of FA, super plasticizer and viscosity modifying agent (VMA). Based on the test results it is evidenced that FA and MK make use of mineral admixture in the production of SCC. It also clarifies that the addition of sisal fiber improves mechanical properties of concrete. The research work shows that the ultimate load of fiber reinforced RC beams was raised when compared to normal RC beams. The flexural toughness and ductility of concrete was found to increase appreciably when sisal fiber was added.

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“…HUMS is intended to monitor the health state of a structure and its consumed life, based on a series of permanently installed sensors 1–3 . In this framework, knowledge of the real load spectra 4 to which a structure is subjected during its service life and thus the associated strain and stress fields are mandatory for computing the consumed life and exploiting HUMS system data on real structures 5–7 . Thus, load monitoring is a requirement for aircrafts to promote the switch from the safe‐life design to the damage‐tolerant concept 8 since it allows continuous monitoring of the structure.…”

Section: Introductionmentioning

confidence: 99%

Numerical and experimental verification of an inverse‐direct approach for load and strain monitoring in aeronautical structures

Colombo

Sbarufatti

Bosco

et al. 2020

Struct Control Health Monit

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Fibre Bragg grating sensor-based damage response monitoring of an asymmetric reinforced concrete shear wall structure subjected to progressive seismic loads

Cited by 93 publications

References 59 publications

Seismic response prediction method for building structures using convolutional neural network

Seismic response prediction method for building structures using convolutional neural network

Mechanical and flexural performance of self compacting concrete with natural fiber

Numerical and experimental verification of an inverse‐direct approach for load and strain monitoring in aeronautical structures

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