An Intensity Measure for the Rocking Fragility Analysis of Rigid Blocks Subjected to Floor Motions

Liu, Hanquan; Huang, Yong; Liu, Xiaohui

doi:10.3390/su15032418

Cited by 6 publications

(12 citation statements)

References 60 publications

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“…Figure 4 displays six selected runs of rotation-time history derived from the experiment and the simulation. The comparison shows that this numerical model with discrete damping can correctly approximate the maximum rocking angle and predict overturning [59,60].…”

Section: Experimental Verificationsmentioning

confidence: 88%

“…Correspondingly, for a rocking-overturning fragility analysis, various IMs, including univariate IMs [57,58] and bivariate ones [56], have been proposed. A novel dimensionless IM, determined by the excitation magnitude, frequency, and block geometry parameters, was presented by Liu et al [59] for evaluating the seismic rocking fragility, which demonstrates a closer correlation with the maximum rocking angle, thus achieve less dispersion of the fragility functions.…”

Section: Introductionmentioning

confidence: 99%

“…In addition, the least squares method is used to obtain the parameters of the fragility functions. A novel IM [59], used for the first time in an overturning fragility analysis, receives the smallest hybrid ratio and the smallest coefficient of variation compared with some well-known IMs. Finally, the effect of different analysis strip widths is also examined, and the results show that the overturning fragility curves have good robustness against the change of the analysis strip width.…”

Section: Introductionmentioning

confidence: 99%

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Seismic Overturning Fragility Analysis for Rigid Blocks Subjected to Floor Motions

2023

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This paper investigates the seismic rocking-overturning fragility of freestanding rigid blocks subjected to one-sine acceleration pulses from a probabilistic perspective. An equivalent single-degree-of-freedom (SDOF) model with a bespoke discrete damper is used to simulate the responses of four blocks with varying geometries under excitation with various characteristics. The simulation results are used to perform an overturning fragility analysis and evaluate the performance of various intensity measures (IMs). An IM strip, referred to as a hybrid strip, can be observed in the analysis, within which both safe rocking and overturning occur. For IM values outside of the hybrid strip, there exists a clear distinction between these two states. In this study, we introduce the hybrid ratio, a parameter that can estimate the size of the hybrid strip of different IMs. The hybrid ratio is defined as the combination of two ratios of hybrid strip width and the two IM strip widths corresponding to safe rocking and overturning, respectively. The effect of the different analysis strip widths is also examined in the overturning fragility analysis. The results suggest that the IM determined by excitation magnitude, frequency, and block geometry parameters demonstrates its superiority compared with some well-known IMs by having the smallest hybrid ratio and coefficient of variation, as well as good robustness of the overturning fragility curves against the change of the analysis strip width.

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Section: Experimental Verificationsmentioning

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Seismic Overturning Fragility Analysis for Rigid Blocks Subjected to Floor Motions

2023

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“…Later, Petrone et al 21 and Lachanas et al 22 verified the importance of PGV and PGA to the overturning of slender and stocky rocking structures, respectively. Liu et al 23 showed the influence of the combined consideration of peak and frequency characteristics of the ground excitation on rocking response. Further accreditation of velocity and frequency characteristics as optimal intensity measures (IMs) (i.e., exhibiting a strong correlation with the response) came from Pappas et al 24 and Kavvadias et al 25 Recently, Giouvanidis and Dimitrakopoulos 26 revealed the remarkable contribution of duration-based characteristics, such as the uniform duration t uni and cumulative absolute velocity of exceedance CAV exc , to rocking amplification (i.e., rocking without overturning).…”

Section: Introductionmentioning

confidence: 99%

“…verified the importance of PGV and PGA to the overturning of slender and stocky rocking structures, respectively. Liu et al 23 . showed the influence of the combined consideration of peak and frequency characteristics of the ground excitation on rocking response.…”

Section: Introductionmentioning

confidence: 99%

A multi‐level approach to predict the seismic response of rigid rocking structures using artificial neural networks

Banimahd,

Giouvanidis,

Karimzadeh

et al. 2024

Earthq Engng Struct Dyn

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This paper explores the use of Artificial Neural Networks (ANN) for the rocking problem. The paper adopts rigid rocking blocks of different sizes and slenderness, which undergo rocking motion without sliding and bouncing when subjected to recorded earthquakes. This research focuses on the cases where the blocks overturn or safely return to their initial (rest) position at the end of the ground shaking. An ANN model is trained to efficiently categorise the response into overturning or safe rocking using the structural parameters, ground motion characteristics, and the coefficient of restitution as input. The results show the substantial contribution of velocity and frequency characteristics of the ground motion to overturning. In addition, ANN is used to predict the response amplitude and identify the most critical input variables that govern safe rocking. The analysis reveals that rocking amplitude is governed by a combination of duration, frequency, and intensity characteristics of the ground excitation. Interestingly, the maximum incremental velocity (MIV), a novel intensity measure for the rocking literature, shows a substantial correlation with the rocking amplitude. In this context, this paper proposes closed‐form expressions using the most influential input variables to provide a quick, yet adequately accurate, response prediction. Finally, this study pays special attention to the contribution of the coefficient of restitution, which, in general, is less critical to the peak safe rocking response, while it becomes more important to the overturning response.

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Seismic effectiveness assessment of nylon lines for the protection of museum artifacts via shaking table tests

Zou,

Yang,

Wang

et al. 2024

Construction and Building Materials

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An Intensity Measure for the Rocking Fragility Analysis of Rigid Blocks Subjected to Floor Motions

Cited by 6 publications

References 60 publications

Seismic Overturning Fragility Analysis for Rigid Blocks Subjected to Floor Motions

Seismic Overturning Fragility Analysis for Rigid Blocks Subjected to Floor Motions

A multi‐level approach to predict the seismic response of rigid rocking structures using artificial neural networks

Seismic effectiveness assessment of nylon lines for the protection of museum artifacts via shaking table tests

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