Effects of Spatial Variation of Ground Motion (SVGM) on Seismic Vulnerability of Ultra-high Tower and Multi-tower Cable-stayed Bridges

AbstractThe development of fragility functions that express the probability of collapse of a building as a function of some ground motion intensity measure is an effective tool to assess seismic vulnerability of structures. However, a number of factors ranging from ground motion selection to modeling decisions can influence the quantification of collapse probability. A methodical investigation was carried out to examine the effects of component modeling and ground motion selection in establishing demand and collapse risk of a typical reinforced concrete frame building. The primary system considered in this study is a modern 6-story RC moment frame building that was designed to current code provisions in a seismically active region. Both concentrated and distributed plasticity beam–column elements were used to model the building frame and several options were considered in constitutive modeling for both options. Incremental dynamic analyses (IDA) were carried out using two suites of ground motions—the first set comprised site-dependent ground motions, while the second set was a compilation of hazard-consistent motions using the conditional scenario spectra approach. Findings from the study highlight the influence of modeling decisions and ground motion selection in the development of seismic collapse fragility functions and the characterization of risk for various demand levels.

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Building Seismic Vulnerability Study for China High Rises

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.353-356.2301 ◽

2013 ◽

Vol 353-356 ◽

pp. 2301-2304

Author(s):

Fan Wu ◽

Ming Wang ◽

Xin Yuan Yang

Keyword(s):

Ground Motion ◽

Structural Damage ◽

Seismic Vulnerability ◽

Fragility Curves ◽

Response Spectrum ◽

Earthquake Ground Motion ◽

Published Data ◽

Rapid Urbanization ◽

High Rise ◽

Story Drift

High-rise buildings, as a result of rapid urbanization in China, become one of popular structure kind. However, there have been few seismic vulnerability studies on high-rise buildings, and few fragility curves have been developed for the buildings. Based on the published data of more than 50 high rises and super high rises, the structural information such as building heights, mode periods, locations and sites, the maximum design story drift ratios, are collected and analyzed. The vulnerability analysis for high rises uses response spectrum displacement as seismic ground motion input, since the structures have comparatively long natural period. Using statistics and regression analysis, the relationship between the maximum story drift ratio and response spectrum displacement is established. Based on height groups and earthquake design codes, the fragility curves of different performance levels can be developed. These curves can provide good loss estimation of high rise structural damage under earthquake ground motion.

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Effect of spatial variability of ground motion on non-linear dynamic behavior of cable stayed bridges

MATEC Web of Conferences ◽

10.1051/matecconf/201714902044 ◽

2018 ◽

Vol 149 ◽

pp. 02044

Author(s):

Mouloud Ouanani ◽

Boualem Tiliouine ◽

Malek Hammoutene

Keyword(s):

Spatial Variability ◽

Dynamic Behavior ◽

Ground Motion ◽

Linear Dynamic ◽

Non Linear ◽

Cable Stayed Bridges

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Multi-angle and nonuniform ground motions on cable-stayed bridges

Earthquake Spectra ◽

10.1177/87552930211051393 ◽

2021 ◽

pp. 875529302110513

Author(s):

Eleftheria Efthymiou ◽

Alfredo Camara

Keyword(s):

Seismic Response ◽

Ground Motion ◽

Seismic Waves ◽

Incidence Angle ◽

Design Parameters ◽

System Configuration ◽

Cable System ◽

Parametric Problem ◽

Wide Range ◽

Cable Stayed Bridges

The definition of the spatial variability of the ground motion (SVGM) is a complex and multi-parametric problem. Its effect on the seismic response of cable-stayed bridges is important, yet not entirely understood to date. This work examines the effect of the SVGM on the seismic response of cable-stayed bridges by means of the time delay of the ground motion at different supports, the loss of coherency of the seismic waves, and the incidence angle of the seismic waves. The focus herein is the effect of the SVGM on cable-stayed bridges with various configurations in terms of their length and of design parameters such as the pylon shape and the pylon–cable system configuration. The aim of this article is to provide general conclusions that are applicable to a wide range of canonical cable-stayed bridges and to contribute to the ongoing effort to interpret and predict the effect of the SVGM in long structures. This work shows that the effect of the SVGM on the seismic response of cable-stayed bridges varies depending on the pylon shape, height, and section dimensions; on the cable-system configuration; and on the response quantity of interest. Furthermore, the earthquake incidence angle defines whether the SVGM is important to the seismic response of the cable-stayed bridges. It is also confirmed that the SVGM excites vibration modes of the bridges that do not contribute to their seismic response when identical support motion is considered.

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Spatial variation model of seismic ground motion for Istanbul

DÜMF Mühendislik Dergisi ◽

10.24012/dumf.701211 ◽

2020 ◽

Author(s):

Ebru HARMANDAR

Keyword(s):

Spatial Variation ◽

Ground Motion ◽

Seismic Ground Motion ◽

Variation Model

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Influence of Multiple-Support Excitation on Seismic Response of Reinforced Concrete Arch Bridges

Applied Sciences ◽

10.3390/app10010017 ◽

2019 ◽

Vol 10 (1) ◽

pp. 17 ◽

Cited By ~ 3

Author(s):

Marta Savor Novak ◽

Damir Lazarevic ◽

Josip Atalic ◽

Mario Uros

Keyword(s):

Reinforced Concrete ◽

Spatial Variation ◽

Seismic Response ◽

Ground Motion ◽

Seismic Analysis ◽

Numerical Study ◽

Relative Significance ◽

Multiple Support ◽

Arch Bridges ◽

Support Excitation

Although post-earthquake observations identified spatial variation of ground motion (i.e., multiple-support excitation) as a frequent cause of the unfavorable response of long-span bridges, this phenomenon is often not taken into account in seismic design to simplify the calculation procedure. This study investigates the influence of multiple-support excitation accounting for coherency loss and wave-passage effects on the seismic response of reinforced concrete deck arch bridges of long spans founded on rock sites. Parametric numerical study was conducted using the time-history method, the response spectrum method, and a simplified procedure according to the European seismic standards. Results showed that multiple-support excitation had a detrimental influence on response of almost all analyzed bridges regardless of considered arch span. Both considered spatial variation effects, acting separately or simultaneously, proved to be very important, with their relative significance depending on the response values and arch locations analyzed and seismic records used. Therefore, it is suggested that all spatially variable ground-motion effects are taken into account in seismic analysis of similar bridges.

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