Urban scale risk assessment including SSI and site amplification

Large-scale risk analysis is typically performed considering existing fragility curves, calculated in most cases without adequately accounting for local site amplification (SAmp) and soil-structure interaction (SSI) effects. Nevertheless, foundation flexibility and local site effects may lead to a s...

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Veröffentlicht in:Bulletin of earthquake engineering 2023-03, Vol.21 (4), p.1821-1846
Hauptverfasser: Amendola, Chiara, Pitilakis, Dimitris
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description Large-scale risk analysis is typically performed considering existing fragility curves, calculated in most cases without adequately accounting for local site amplification (SAmp) and soil-structure interaction (SSI) effects. Nevertheless, foundation flexibility and local site effects may lead to a substantial difference in the fragility or loss estimates. Including these effects on the city-scale vulnerability analysis is challenging due to the complexity of defining the whole interacting urban system. We propose a novel framework for the fragility assessment of structures considering the influence of SSI and local site amplification effects, suitable for large-scale applications. The applicability of the proposed approach is based on globally available data regarding the soil, the foundation, and the building portfolio. Site amplification is considered directly in the resulting fragility curves using site response analyses. An improved taxonomy is adopted to make the approach implementable in the OpenQuake software, introducing V S,30 and H/B within the structural features as proxies for the site and SSI effects. Finally, following the performance-based earthquake engineering framework, the outcomes of the methodological framework are adopted to estimate the nominal probability of failure for selected building classes belonging to the majority of structural types of the city of Thessaloniki, Northern Greece. The main findings demonstrate that the conventional way of calculating fragility curves may lead to a different seismic risk evaluation, especially in soft soil formations.
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subjects Amplification
Civil Engineering
Earth and Environmental Science
Earth Sciences
Earthquake engineering
Earthquakes
Environmental Engineering/Biotechnology
Fragility
Frameworks
Geophysics/Geodesy
Geotechnical Engineering & Applied Earth Sciences
Hydrogeology
Mathematical analysis
Original Article
Probability theory
Risk analysis
Risk assessment
Seismic activity
Seismic engineering
Seismic hazard
Software
Soil
Soil formation
Soil-structure interaction
Structural Geology
Taxonomy
Vulnerability
title Urban scale risk assessment including SSI and site amplification
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