Abstract
The objective of this paper is to demonstrate how assessment of seismic vulnerability can be effective in protection against earthquakes. Findings are reported from a case study in a densely populated urban area near an active fault, utilizing practical methods and exact engineering data. Vulnerability factors were determined due to technical considerations, and a field campaign was performed to collect the required data. Multi-criteria decision making was carried out by means of an analytical hierarchy process including a fuzzy standardization. Earthquake scenarios were applied through an implicit vulnerability model. GIS was utilized and the results were analyzed by classifying the state of vulnerability in levels as very low, low, moderate, high, and very high. Seismic resilience was evaluated as vulnerabilities below the moderate state, being about 40% in an intensity of 6 Mercalli and less than 10% in 10 Mercalli. It is concluded that seismic resilience in the area studied is not acceptable, the area is vulnerable in the expected scenarios, and due to the high seismicity of the region, proper crisis management planning is required in parallel with attempts toward retrofitting. In this regard, an emergency map was developed with reference to the assessed vulnerabilities.
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References
Abdollahzadeh G, Sazjini M and Asghari A (2015), “Seismic Fragility Assessment of Special Truss Moment Frames (STMF) Using the Capacity Spectrum Method,” Civil Engineering Infrastructures Journal, 48(1): 1–8.
Alizadeh M, Hashim M, Alizadeh E, Shahabi H, Karami MR, Beiranvand Pour A, Pradhan B and Zabihi H (2018), “Multi-Criteria Decision Making (MCDM) Model for Seismic Vulnerability Assessment (SVA) of Urban Residential Buildings,” ISPRS International Journal of Geo-Information, 7 (11): paper no. 444; 22 pages.
Ambraseys NN and Melville CP (1982), A History of Persian Earthquakes, Cambridge University Press, Cambridge, UK.
Barbat AH, Pujades LG and Lantada N (2008), “Seismic Damage Evaluation in Urban Areas Using the Capacity Spectrum Method: Application to Barcelona,” Soil Dynamics and Earthquake Engineering, 28(10–11): 851–865.
Benitez J, Delgado-Galvan X, Gutierrez JA and Izquierdo J (2011), “Balancing Consistency and Expert Judgment in AHP,” Mathematical and Computer Modelling, 54(7–8): 1785–1790.
BHRC (2020), “Housing and Urban Development Library,” Road, Housing & Urban Development Research Center of Iran (BHRC). Accessed for the last time on January 2020 via https://lib.bhrc.ac.ir/Simwebclt/WebAccess/SimWebPortal.dll?LANG=2.
Bray JD and Rodriguez-Marek A (2004), “Characterization of Forward-Directivity Ground Motions in the Near-fault Region,” Soil Dynamics and Earthquake Engineering, 24(11): 815–828.
Bruneau M, Chang SE, Eguchi RT, Lee GC, O’Rourke TD, Reinhorn AM, Shinozuka M, Tierney K, Wallace WA and von Winterfeldt D (2003), “A Framework to Quantitatively Assess and Enhance the Seismic Resilience of Communities,” Earthquake Spectra, 19(4): 733–752.
Castillo A, Lopez-Almansa F and Pujades LG (2011), “Seismic Risk Analysis of Urban Non-Engineered Buildings: Application to an Informal Settlement in Mérida, Venezuela,” Natural Hazards, 59(2): 891–916.
Cheng Y and Bai GL (2017), “Basic Characteristic Parameters and Influencing Factors of Long-Period Ground Motion Records,” Journal of Vibroengineering, 19(7): 5191–5207.
Cimellaro GP, Reinhorn AM and Bruneau M (2010), “Framework for Analytical Quantification of Disaster Resilience,” Engineering Structures, 32(11): 3639–3649.
Codermatz R, Nicolich R and Slejko D (2003), “Seismic Risk Assessments and GIS Technology: Applications to Infrastructures in the Friuli-Venezia Giulia Region (NE Italy),” Earthquake Engineering and Structural Dynamics, 32(11): 1677–1690.
Cova TJ and Church RL (1997), “Modelling Community Evacuation Vulnerability Using GIS,” International Journal of Geographical Information Science, 11(8): 763–784.
Didier M, Broccardo M, Esposito S and Stojadinovic B (2018), “A Compositional Demand/Supply Framework to Quantify the Resilience of Civil Infrastructure Systems (Re-CoDeS),” Sustainable and Resilient Infrastructure, 3(2): 86–102.
Emmi PC and Horton CA (1993), “A GIS-based Assessment of Earthquake Property Damage and Casualty Risk: Salt Lake County, Utah,” Earthquake Spectra, 9(1): 11–33.
Erdik M, Aydinoglu N, Fahjan Y, Sesetyan K, Demircioglu M, Siyahi B, Durukal E, Ozbey C, Biro Y, Akman H and Yuzugullu O (2003), “Earthquake Risk Assessment for Istanbul Metropolitan Area,” Earthquake Engineering and Engineering Vibration, 2(1): 1–23.
Fallah Aliabadi S, Sarsangi A and Modiri E (2015), “The Social and Physical Vulnerability Assessment of Old Texture against Earthquake (Case Study: Fahadan District in Yazd City),” Arabian Journal of Geosciences, 8(12): 10775–10787.
Farsangi EN, Takewaki I, Yang TY, Astaneh-Asl A and Gardoni P (Eds.) (2019), Resilient Structures and Infrastructure, Springer.
Ferreira MT, Maio R and Vicente R (2017), “Analysis of the Impact of Largescale Seismic Retrofitting Strategies through the Application of a Vulnerability-Based Approach on Traditional Masonry Buildings,” Earthquake Engineering and Engineering Vibration, 16(2): 329–348.
GSI (2019), “Generate Maps and Exploratory Reports,” Geological Survey and Mineral Exploration Organization of Iran (GSI), Accessed for the last time on December 2019 on https://www.gsi.ir/en/page/3457/generate-maps-and-exploratory-reports.
Guan Y, Feng Q and Jia J (2006), “A GIS-based Earthquake and Tsunami Emergency Command System for Seaside Cities,” Journal of Ocean University of China (Oceanic and Coastal Sea Research), 5(2): 181–186.
Hashemi M, Alesheikh AA and Zolfaghari MR (2017), “A GIS-based Time-dependent Seismic Source Modeling of Northern Iran,” Earthquake Engineering and Engineering Vibration, 16(1): 33–45.
IIEES (2020), “Recent Earthquakes,” International Institute of Earthquake Engineering and Seismology (IIEES). Accessed for the last time on January 2020 via http://www.iiees.ac.ir/en/recentevents.
Kammouh O, Zamani Noori A, Taurino V, Mahin SA and Cimellaro GP (2018), “Deterministic and Fuzzy-Based Methods to Evaluate Community Resilience,” Earthquake Engineering and Engineering Vibration, 17(2): 261–275.
Kassem MM, Nazri FM and Farsangi EN (2019), “Development of Seismic Vulnerability Index Methodology for Reinforced Concrete Buildings Based on Nonlinear Parametric Analyses,” MethodsX, 6: 199–211.
Kassem MM, Nazri FM and Farsangi EN (2020), “The Efficiency of an Improved Seismic Vulnerability Index under Strong Ground Motions,” Structures, 23: 366–382.
Kassem MM, Nazri FM and Farsangi EN (2020), “The Seismic Vulnerability Assessment Methodologies: A State-of-the-Art Review,” Ain Shams Engineering Journal, In Press. https://doi.org/10.1016/j.asej.2020.04.001
Liu Y, Wei J, Xu J and Ouyang Z (2018), “Evaluation of the Moderate Earthquake Resilience of Counties in China Based on a Three-Stage DEA Model,” Natural Hazards, 91(2): 587–609.
Meshkini A, Habibi K and Alizadeh H (2013), “Using Fuzzy Logic and GIS Tools for Seismic Vulnerability of Old Fabric in Iranian Cities (Case Study: Zanjan City),” Journal of Intelligent and Fuzzy Systems, 25(4): 965–975.
Milutinovic ZV and Trendafiloski GS (2003), “Vulnerability of Current Buildings (WP4 of RISK-UE: An Advanced Approach to Earthquake Risk Scenarios with Applications to Different European Towns — Grant ID: EVK4-CT-2000-00014),” European Commission, Available online at: www.civil.ist.utl.pt/∼mlopes/conteudos/DamageStates/Risk%20UE%20WP04_Vulnerability.pdf.
Nazmfar H, Alavi S, Eshghi A and Feizizadeh B (2019), “Vulnerability Evaluation of Urban Buildings to Various Earthquake Intensities: A Case Study of the Municipal Zone 9 of Tehran,” Human and Ecological Risk Assessment, 25(1–2): 455–474.
Panahi M, Rezaie F and Meshkani SA (2014), “Seismic Vulnerability Assessment of School Buildings in Tehran City based on AHP and GIS,” Natural Hazards and Earth Systems Sciences, 14(4): 969–979.
Parsons M, Glavac S, Hastings P, Marshall G, McGregor J, McNeill J, Morley P, Reeve I and Stayner R (2016), “Top-Down Assessment of Disaster Resilience: A Conceptual Framework Using Coping and Adaptive Capacities,” International Journal of Disaster Risk Reduction, 19: 1–11.
Peek-Asa C, Ramirez MR, Shoaf K, Seligson H and Kraus JF (2000), “GIS Mapping of Earthquake-Related Deaths and Hospital Admissions from the 1994 Northridge, California, Earthquake,” Annals of Epidemiology, 10(1): 5–13.
Rashed T and Weeks J (2003), “Assessing Vulnerability to Earthquake Hazards through Spatial Multicriteria Analysis of Urban Areas,” International Journal of Geographical Information Science, 17(6): 547–576.
Saaty TL and Shih HS (2009), “Structures in Decision Making: On the Subjective Geometry of Hierarchies and Networks,” European Journal of Operational Research, 199(3): 867–872.
Sadrykia M, Delavar M and Zare M (2017), “A GIS-Based Fuzzy Decision Making Model for Seismic Vulnerability Assessment in Areas with Incomplete Data,” International Journal of Geo-Information, 6(4): 119–134.
Shakya M, Varum H, Vicente R and Costa A (2015), “Seismic Vulnerability and Loss Assessment of the Nepalese Pagoda Temples,” Bulletin of Earthquake Engineering, 13(7): 2197–2223.
Sun L, Stojadinovic B and Sansavini G (2019), “Resilience Evaluation Framework for Integrated Civil Infrastructure-Community Systems Under Seismic Hazard,” Journal of Infrastructure Systems, 25(2): 04019016.
Tang Chuan, Zhu Jing and Liang Jingtao (2009), “Emergency Assessment of Seismic Landslide Susceptibility: A Case Study of the 2008 Wenchuan Earthquake Affected Area,” Earthquake Engineering and Engineering Vibration, 8(2): 207–217.
Vicente R, Parodi S and Lagomarsino S (2011), “Seismic Vulnerability and Risk Assessment: Case Study of the Historic City Centre of Coimbra, Portugal,” Bulletin of Earthquake Engineering, 9(4): 1067–1096.
Wang Q, M’Ikiugu MM, Kinoshita I Luo Y (2016), “GIS-Based Approach for Municipal Renewable Energy Planning to Support Post-earthquake Revitalization: A Japanese Case Study,” Sustainability, 8(7): 703–722.
Yu P, Wen W, Ji D, Zhai C and Xie L (2019), “A Framework to Assess the Seismic Resilience of Urban Hospitals,” Advances in Civil Engineering, 2019: 7654683.
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Narjabadifam, P., Hoseinpour, R., Noori, M. et al. Practical seismic resilience evaluation and crisis management planning through GIS-based vulnerability assessment of buildings. Earthq. Eng. Eng. Vib. 20, 25–37 (2021). https://doi.org/10.1007/s11803-021-2003-1
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DOI: https://doi.org/10.1007/s11803-021-2003-1