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Abstract

This paper presents the application of a rigorous probabilistic framework that estimates the number, severity, and distribution of casualties over a region. A brief summary of the model is included in this paper. The application is for casualties resulting from a Mw 8.8 earthquake scenario occurring on the sub-duction fault along the coastline of Lima, Peru. The case study demonstrates an application of the casualty model, including the procedures for acquiring the required information, the selection of model parameters, and a step-by-step explanation of the model-solving algorithms. The model provides an estimate of the joint probability distribution of multiseverity casualties, including spatial and across-severity correlations. This paper also shows how the model can be useful for (1) estimating 90th-percentile casualties, (2) identifying unsafe communities and structural typologies, and (3) providing evidence to support hospital collaboration policies across different districts to increase the patient treatment reliability. Additionally, the results demonstrate that empirical fatality prediction methodologies can underestimate fatality rates in countries with scarce and outdated fatality data.

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References

Aguilar

, Lazares

, Alarcón

, Quispe

, Uriarte

, and Calderón

, 2013. Actualización de la Microzonificación Sísmica de la cuidad de Lima, in The International Symposium for CISMID 25th Anniversary 17–18 August, 2012, Lima, Peru.

Allen

T. I.

, and Wald

D. J.

, 2007. Topographic Slope as a Proxy for Seismic Site-Conditions (V_S30) and Amplification Around the Globe. Tech. Rep. 2007-1357, United States Geological Survey, Reston, VA.

Beck

S. L.

, and Nishenko

S. P.

, 1990. Variations in the mode of great earthquake rupture along the central Peru subduction zone, Geophysical Research Letters 17, 1969–1972.

Ceferino

, Kiremidjian

A. S.

, and Deierlein

G. G.

, 2018. Probabilistic model for regional multi-severity casualty estimation due to bilding damage following an earthquake, Special Collection of ASCE-ASME Journal of Risk and Uncertainty in Engineering Systems: Part A: Civil Engineering. In press.

Dorbath

, Cisternas

, and Dorbath

, 1990. Assessment of the size of large and great historical earthquakes in Peru, Bulletin of the Seismological Society of America 80, 551–576.

Federal Emergency Management Agency (FEMA), 2015. Multi-Hazard Loss Estimation Methodology: Earthquake Model, Hazus–MH 2.1: Technical Manual Washington, D.C., available at http://www.fema.gov/media-library-data/20130726-1820-25045-6286/hzmh2_1_eq_tm.pdf (last accessed 1 August 2017).

Global Earthquake Model (GEM) Secretariat, 2015. On the South America Risk Assessment (SARA) Final Report 2015, Version 1.0. Tech. Rep., GEM Foundation, Pavia, Italy.

Goda

, and Atkinson

G. M.

, 2009. Probabilistic characterization of spatially correlated response spectra for earthquakes in Japan, Bulletin of the Seismological Society of America 99, 3003–3020.

Goda

, and Hong

H. P.

, 2008. Spatial correlation of peak ground motions and response spectra, Bulletin of the Seismological Society of America 98, 354–365.

10.

Goncharov

, and Frolova

, 2011. Chapter 10: Casualty estimation due to earthquakes: injury structure and dynamics, Human Casualties in Earthquakes: Progress in Modelling and Mitigation ( Spence

, So

, Scawthorn

, eds.), Springer, New York, NY, 141–152.

11.

Jaiswal

, and Wald

, 2010. An empirical model for global earthquake fatality estimation, Earthquake Spectra 26, 1017–1037.

12.

Jaiswal

, Wald

D. J.

, and Hearne

M. G.

, 2009. Estimating Casualties for Large Earthquakes Worldwide Using an Empirical Approach, Tech. Rep. 2009–1136, U.S. Geological Survey (USGS) Reston, VA.

13.

Johnston

, Standring

, Ronan

, Lindell

, Wilson

, Cousins

, Aldridge

, Ardagh

M. W.

, Deely

J. M.

, Jensen

, Kirsch

, and Bissell

, 2014. The 2010/2011 Canterbury earthquakes: context and cause of injury, Natural Hazards 73, 627–637.

14.

Lallemant

, Burton

, Ceferino

, Bullock

, and Kiremidjian

, 2017. A framework and case study for earthquake vulnerability assessment of incrementally expanding buildings, Earthquake Spectra 33, 1369–1384.

15.

Markhvida

, Ceferino

, and Baker

J. W.

, 2018. Modeling spatially correlated spectral accelerations at multiple periods using principal component analysis and geostatistics, Earthquake Engineering & Structural Dynamics 47, 1107–1123.

16.

Ministerio de Vivienda, 2016. Norma Técnica E.030 Diseño Sismorresistente.

17.

Noh

H. Y.

, Kiremidjian

, Ceferino

, and So

, 2017. Bayesian updating of earthquake vulnerability functions with application to mortality rates, Earthquake Spectra 33, 1173–1189.

18.

Oak Ridge National Laboratory, 2013. LandScan Global Population Database, available at https://purl.stanford.edu/dd452vk1873 (last accessed 1 August 2017).

19.

Silva

, Crowley

, Pagani

, Monelli

, and Pinho

, 2014. Development of the Open-Quake engine, the Global Earthquake Model's open-source software for seismic risk assessment, Natural Hazards 72, 1409–1427.

20.

U.S. Geological Survey (USGS), 2015. Earthquakes with 1,000 or More Deaths 1900–2014, Tech. Rep., USGS, Reston, VA.

21.

Villar-Vega

, Silva

, Crowley

, Yepes

, Tarque

, Acevedo

A. B.

, Hube

M. A.

, Gustavo

C. D.

, and Santa María

, 2017. Development of a fragility model for the residential building stock in South America, Earthquake Spectra 33, 581–604.

22.

Walker

, 2008. Shaky Colonialism: The 1746 Earthquake-Tsunami in Lima, Peru, and Its Long Aftermath, Duke University Press, Durham, NC.

23.

Wells

D. L.

, and Coppersmith

K. J.

, 1994. New empirical relationships among magnitude, rupture length, rupture width, rupture area, and surface displacement, Bulletin of the Seismological Society of America 84, 974–1002.

24.

Yepes-Estrada

, Silva

, Valcárcel

, Acevedo

A. B.

, Tarque

, Hube

M. A.

, Coronel

, and Santa María

, 2017. Modeling the residential building inventory in South America for seismic risk assessment, Earthquake Spectra 33, 299–322.

25.

Zhao

J. X.

, Zhang

, Asano

, Ohno

, Oouchi

, Takahashi

, Ogawa

, Irikura

, Thio

H. K.

, Somerville

P. G.

, Fukushima

, and Fukushima

, 2006. Attenuation relations of strong ground motion in Japan using site classification based on predominant period, Bulletin of the Seismological Society of America 96, 898–913.

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Regional Multiseverity Casualty Estimation Due to Building Damage following a Mw 8.8 Earthquake Scenario in Lima,Peru

Abstract

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