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Abstract

This paper presents a study on the impact of earthquake types (shallow crustal, deep inslab, and megathrust Cascadia interface earthquakes) and aftershocks on loss assessment of non-code-conforming reinforced concrete (RC) buildings. The loss assessment is formulated within the performance-based earthquake engineering framework. The dependency between the maximum and residual inter-story drift ratios are captured using copulas. Finite-element models that take into account key hysteretic characteristics of non-ductile RC frames were adopted and incremental dynamic analysis is utilized to compute collapse risk. The proposed procedure is applied to a set of 2-, 4-, 8-, and 12-story non-ductile reinforced concrete frames located in Victoria, British Columbia, Canada. From the results, the aftershock showed marked difference for the 2-story building. At annual probability of 10⁻²–10⁻³, crustal and inslab events with M_w6.5 to M_w7.5 contributed the most to the loss as these events occur more frequently. At rarer annual probability of 10⁻³–10⁻⁴, the Cascadia event having M_w8.5 to M_w9.0 is predominant and contributed the most to the loss.

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References

AIR Worldwide, 2013. Study of Impact and the Insurance and Economic Cost of a Major Earthquake in British Columbia and Ontario/Québec, Insurance Bureau of Canada, Toronto, Canada, 345 pp.

Atkinson

G. M.

, and Goda

, 2011. Effects of seismicity models and new ground motion prediction equations on seismic hazard assessment for four Canadian cities, Bulletin of the Seismological Society of America 101, 176–189.

Baker

J. W.

, 2011. The conditional mean spectrum: a tool for ground motion selection, Journal of Structural Engineering 137, 322–331.

Cornell

C. A.

, and Krawinkler

, 2000. Progress and challenges in seismic performance assessment, PEER Center News 3, available at http://peer.berkeley.edu/news/2000spring/performance.html.

Ebrahimian

, Jalayer

, Asprone

, Lombardi

A. M.

, Marzocchi

, Prota

, and Manfredi

, 2014. A performance-based framework for adaptive seismic aftershock risk assessment, Earthquake Engineering & Structural Dynamics 43, 2179–2197.

Goda

, and Taylor

C. A.

, 2012. Effects of aftershocks on peak ductility demand due to strong ground motion records from shallow crustal earthquakes, Earthquake Engineering & Structural Dynamics 41, 2311–2330.

Goda

, and Tesfamariam

, 2015. Multi-variate seismic demand modelling using Copulas: Application to non-ductile reinforced concrete frame in Victoria, Canada, Structural Safety 56, 39–51.

Goda

, and Tesfamariam

, 2016. Seismic risk management of existing reinforced concrete buildings in the Cascadia subduction zone, ASCE Natural Hazard Review, doi: 10.1061/(ASCE)NH.1527-6996.0000206.

Goda

, Atkinson

G. M.

, and Hong

H. P.

, 2011. Seismic loss estimation of wood-frame houses in southwestern British Columbia, Structural Safety 33, 123–135.

10.

Goda

, Kiyota

, Mohan Pokhrel

, Chiaro

, Katagiri

, Sharma

, and Wilkinson , 2015. The 2015 Gorkha Nepal earthquake: insights from earthquake damage survey, Frontiers in Built Environment 1, http://dx.doi.org/10.3389/fbuil.2015.00008.

11.

Goda

, Wenzel

, and De Risi

, 2015. Empirical assessment of nonlinear seismic demand of mainshock–aftershock ground-motion sequences for Japanese earthquakes, Frontiers in Built Environment 1, doi: 10.3389/fbuil.2015.00006.

12.

Goldfinger

, Grijalva

, Bürgmann

, Morey

A. E.

, Johnson

J. E.

, Nelson

C. H.

, Gutiérrez-Pastor

, Ericsson

, Karabanov

, Chaytor

J. D.

, Patton

, and Gràcia

, 2008. Late Holocene rupture of the northern San Andreas fault and possible stress linkage to the Cascadia subduction zone, Bulletin of the Seismological Society of America 98, 861–889.

13.

Haselton

C. B.

, Liel

A. B.

, Lange

S. T.

, and Deierlein

G. G.

, 2008. Beam-Column Element Model Calibrated for Predicting Flexural Response Leading to Global Collapse of RC Frame Buildings. PEER Report 2007/03, PEER Center, University of California, Berkeley, Berkeley, CA.

14.

ICBO 1967. Uniform Building Code. International Conference of Building Officials, Pasadena, CA.

15.

Koduru

S.D.

, and Haukaas

, 2010. Probabilistic seismic loss assessment of a Vancouver high-rise building, ASCE Journal of Structural Engineering 136, 235–245.

16.

Liel

A. B.

, and Deierlein

G. G.

, 2008. Assessing the Collapse Risk of California's Existing Reinforced Concrete Frame Structures: Metrics for Seismic Safety Decisions, Technical Report No. 166, John A. Blume Center Earthquake Engineering Center, Stanford, CA.

17.

Luco

, and Bazzurro

, 2007. Does amplitude scaling of ground motion records result in biased nonlinear structural drift responses?, Earthquake Engineering & Structural Dynamics 36, 1813–1835.

18.

Maffei

, Telleen

, and Nakayama

, 2008. Probability-based seismic assessment of buildings, considering post-earthquake safety, Earthquake Spectra 24, 667–699.

19.

Mahsuli

, and Haukaas

, 2013. Seismic risk analysis with reliability methods, Part II: Analysis, Structural Safety 42, 63–74.

20.

McNeil

A. J.

, Frey

, and Embrechts

, 2005. Quantitative Risk Management: Concepts, Techniques and Tools, Princeton University Press, Princeton, NJ.

21.

Onur

, Ventura

C. E.

, and Finn

W. D. L.

, 2005. Regional seismic risk in British Columbia-damage and loss distribution in Victoria and Vancouver, Canadian Journal of Civil Engineering 32, 361–371.

22.

Raghunandan

, Liel

A. B.

, and Luco

, 2015. Collapse risk of buildings in the Pacific Northwest region due to subduction earthquakes, Earthquake Spectra 31, 2087–2115.

23.

Ramirez

C. M.

, and Miranda

, 2009. Building-specific Loss Estimation Methods & Tools for Simplified Performance-based Earthquake Engineering, Technical Report No. 171, John A. Blume Center Earthquake Engineering Center, Stanford, CA.

24.

Ruiz-García

, and Miranda

, 2006. Residual displacement ratios for assessment of existing structures, Earthquake Engineering & Structural Dynamics 35, 315–336.

25.

Salami

M. R.

, and Goda

, 2014. Seismic loss estimation of residential wood-frame buildings in southwestern British Columbia considering mainshock-aftershock sequences, Journal of Performance of Constructed Facilities 28, A4014002.

26.

Tesfamariam

, and Goda

, 2015. Loss estimation for non-ductile reinforced concrete building in Victoria, British Columbia, Canada: effects of megathrust M_w9-class subduction earthquakes and aftershocks, Earthquake Engineering & Structural Dynamics, doi: 10.1002/eqe.2585.

27.

Tesfamariam

, Goda

, and Mondal

, 2015. Seismic vulnerability of RC frame with unreinforced masonry infill due to main shock-aftershock earthquake sequences, Earthquake Spectra 31, 1427–1449.

28.

Vamvatsikos

, and Cornell

C. A.

, 2002. Incremental dynamic analysis, Earthquake Engineering & Structural Dynamics 31, 491–514.

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Impact of Earthquake Types and Aftershocks on Loss Assessment of Non-Code-Conforming Buildings: Case Study with Victoria,British Columbia

Abstract

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