Structural Identification of an 18-Story RC Building in Nepal Using Post-Earthquake Ambient Vibration and Lidar Data

Yu, Hanshun; Mohammed, Mohammed A.; Mohammadi, Mohammad Ebrahim; Moaveni, Babak; Barbosa, André R.; Stavridis, Andreas; Wood, Richard L.

doi:10.3389/fbuil.2017.00011

Cited by 25 publications

(22 citation statements)

References 36 publications

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“…Typically, the modes of buildings can be identified with a model order of 50 or less . However, the first mode of the 10‐story building is only identified when a much higher system order is considered.…”

Section: System Identificationmentioning

confidence: 99%

System identification and modeling of a dynamically tested and gradually damaged 10‐story reinforced concrete building

Yousefianmoghadam

Behmanesh²,

Stavridis

et al. 2017

Earthq Engng Struct Dyn

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SummaryThis paper discusses the dynamic tests, system identification, and modeling of a 10-story reinforced concrete building. Six infill walls were demolished in 3 stages during the tests to introduce damage. In each damage stage, dynamic tests were conducted by using an eccentric-mass shaker. Accelerometers were installed to record the torsional and translational responses of the building to the induced excitation, as well as its ambient vibration. The modal properties in all damage states are identified using 2 operational modal analysis methods that can capture the effect of the wall demolition. The modal identification is facilitated by a finite element model of the building. In turn, the model is validated through the comparison of the numerically and experimentally obtained modal parameters. The validated model is used in a parametric study to estimate the influence of structural and nonstructural elements on the dynamic properties of the building and to assess the validity of commonly used empirical formulas found in building codes. Issues related to the applicability and feasibility of system identification on complex structures, as well as considerations for the development of accurate, yet efficient, finite element models are also discussed.

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Section: System Identificationmentioning

confidence: 99%

System identification and modeling of a dynamically tested and gradually damaged 10‐story reinforced concrete building

Yousefianmoghadam

Behmanesh²,

Stavridis

et al. 2017

Earthq Engng Struct Dyn

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“…In addition, LiDAR has the ability to work at day and night, even in adverse conditions, such as in poor illumination or through clouds and smoke. A number of studies have used post-even LiDAR imageries to detect building damage [20][21][22][23]. There are also some studies that combined optical imagery with SAR imagery.…”

Section: Introductionmentioning

confidence: 99%

Identifying Collapsed Buildings Using Post-Earthquake Satellite Imagery and Convolutional Neural Networks: A Case Study of the 2010 Haiti Earthquake

Liu

Buchroithner

2018

Remote Sensing

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Earthquake is one of the most devastating natural disasters that threaten human life. It is vital to retrieve the building damage status for planning rescue and reconstruction after an earthquake. In cases when the number of completely collapsed buildings is far less than intact or less-affected buildings (e.g., the 2010 Haiti earthquake), it is difficult for the classifier to learn the minority class samples, due to the imbalance learning problem. In this study, the convolutional neural network (CNN) was utilized to identify collapsed buildings from post-event satellite imagery with the proposed workflow. Producer accuracy (PA), user accuracy (UA), overall accuracy (OA), and Kappa were used as evaluation metrics. To overcome the imbalance problem, random over-sampling, random under-sampling, and cost-sensitive methods were tested on selected test A and test B regions. The results demonstrated that the building collapsed information can be retrieved by using post-event imagery. SqueezeNet performed well in classifying collapsed and non-collapsed buildings, and achieved an average OA of 78.6% for the two test regions. After balancing steps, the average Kappa value was improved from 41.6% to 44.8% with the cost-sensitive approach. Moreover, the cost-sensitive method showed a better performance on discriminating collapsed buildings, with a PA value of 51.2% for test A and 61.1% for test B. Therefore, a suitable balancing method should be considered when facing imbalance dataset to retrieve the distribution of collapsed buildings.

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“…At the same time, a large number of analytical investigations of the behaviour of masonry infilled RC building structures have been pursued, at different modelling scales and levels of complexity, in order to predict the effect of masonry infills on infilled frame response and failure (Smith and Carter, 1969;Dhanasekar and Page, 1986;Fardis and Calvi, 1995;Crisafulli, 1997;Kappos and Ellul, 2000;Chrysostomou et al, 2002;Fajfar, 2002, 2008a,b;Repapis et al, 2006b;Borzi et al, 2008;Bakas et al, 2009;Asteris and Cotsovos, 2012;Chrysostomou and Asteris, 2012;Ellul and D'Ayala, 2012;Haldar and Singh, 2012;Lagaros, 2012;Vougioukas, 2012;Sarhosis et al, 2014;Zeris, 2014;Jeon et al, 2015;Bolea, 2016;Dumaru et al, 2016;Furtado et al, 2016;Morfidis and Kostinakis, 2017). More recently, with the advancement of testing and data acquisition hardware, together with the evolution of fast and efficient algorithms for data handling techniques, these two approaches above are jointly pursued in full scale field testing vis-à-vis the dynamic model identification (OMA) in order to establish the dynamic characteristics of full scale structures under excitation (Rainieri, 2008;Yu et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Seismic Assessment of Non-conforming Infilled RC Buildings Using IDA Procedures

Repapis

Zeris

2019

Front. Built Environ.

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The seismic performance of existing non-conforming reinforced concrete (RC) buildings is numerically investigated, taking into account the presence of clay brick masonry infill walls. The effect of infill walls on the seismic response of RC frames is widely recognised and has been a subject of numerous analytical and experimental investigations. In this context, Static Pushover analyses of typical existing RC infilled frames have established these structures' inelastic characteristics, focusing on the significant contribution of infill walls to their dynamic characteristics, overstrength, form irregularity and damage. Furthermore, more comprehensive studies of inelastic static response considered the typical variability among different generations of constructed buildings in Greece since the 60s in the form, the seismic design and detailing practice and the structural materials, with different masonry infill configurations and properties. In the present study, the results from such Static Pushover analyses are extended with Incremental Dynamic Analysis predictions using a large number of recorded base excitation from recent destructive earthquakes in Greece and abroad. Evaluation of the time history predictions and comparisons with the Static Pushover analysis findings corroborate that the presence of regular arrangements of perimeter infill walls increase considerably the stiffness and resistance to lateral loads of the infilled RC structures, while at the same time, reducing their global ductility and deformability. Fully or partially infilled RC frames can perform well, while frames with an open floor usually have the worst performance due to the formation of an unintentional soft storey. The analyses further prove that lower strength masonry provides the building with lower overstrength but higher ductility.

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Structural Identification of an 18-Story RC Building in Nepal Using Post-Earthquake Ambient Vibration and Lidar Data

Cited by 25 publications

References 36 publications

System identification and modeling of a dynamically tested and gradually damaged 10‐story reinforced concrete building

System identification and modeling of a dynamically tested and gradually damaged 10‐story reinforced concrete building

Identifying Collapsed Buildings Using Post-Earthquake Satellite Imagery and Convolutional Neural Networks: A Case Study of the 2010 Haiti Earthquake

Seismic Assessment of Non-conforming Infilled RC Buildings Using IDA Procedures

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