A new tool to assess the resilience of an urban environment under an earthquake scenario

G.P. Cimellaro; S. Marasco; A. Zamani Noori; O. Kammouh; S. Mahin

A new tool to assess the resilience of an urban environment under an earthquake scenario

G.P. Cimellaro
, S. Marasco
, A. Zamani Noori
, O. Kammouh
, S. Mahin

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

Abstract

This paper presents a new methodology to predict the potential damage and physical impacts of an earthquake on the built environment. A new methodology to the urbanized systems and large-scale simulations within a seismic scenario are explored, by evaluating multipurpose codes for numerical simulation. A 3-D building shape of a standard virtual city is developed for evaluating the seismic effects at increasing intensities. Once the buildings are integrated into the city, parallel simulations are applied to compute the global behavior of buildings after a disruptive scenario. Monte Carlo Simulations (MCS) are applied to take into account the epistemic uncertainties associated with geometry and mechanical properties within the range of observations. For each set of buildings' data, the nonlinear dynamic analysis is performed through SAP2000 Application Programming Interface (API) in order to assess the dynamic response of the buildings in an organized and automatic fashion. Accordingly, the city is mapped into different zones representative to the possibility of having different levels of damage (complete, extensive, moderate, and slight). This tool supports decision-makers to explore how their community will respond to a disruptive event, to develop different strategies for monitoring and control the emergency in urbanized areas.

Original language	English
Title of host publication	11th National Conference on Earthquake Engineering 2018, NCEE 2018
Subtitle of host publication	Integrating Science, Engineering, and Policy
Publisher	Earthquake Engineering Research Institute
Pages	5606-5617
Number of pages	12
Volume	9
ISBN (Electronic)	9781510873254
Publication status	Published - 2018
Externally published	Yes
Event	11th National Conference on Earthquake Engineering 2018: Integrating Science, Engineering, and Policy, NCEE 2018 - Los Angeles, United States Duration: 25 Jun 2018 → 29 Jun 2018

Conference

Conference	11th National Conference on Earthquake Engineering 2018: Integrating Science, Engineering, and Policy, NCEE 2018
Country/Territory	United States
City	Los Angeles
Period	25/06/18 → 29/06/18

Funding

The research leading to these results has received funding from the European Research Council under the Grant Agreement n° ERC_IDEAL RESCUE_637842 of the project IDEAL RESCUE—Integrated Design and Control of Sustainable Communities during Emergencies.

Access to Document

http://www.proceedings.com/41655.html

Cite this

Cimellaro, G. P., Marasco, S., Zamani Noori, A., Kammouh, O., & Mahin, S. (2018). A new tool to assess the resilience of an urban environment under an earthquake scenario. In 11th National Conference on Earthquake Engineering 2018, NCEE 2018: Integrating Science, Engineering, and Policy (Vol. 9, pp. 5606-5617). Earthquake Engineering Research Institute. http://www.proceedings.com/41655.html

@inproceedings{e8609f82d88149b0b1bfd5dcd182041c,

title = "A new tool to assess the resilience of an urban environment under an earthquake scenario",

abstract = "This paper presents a new methodology to predict the potential damage and physical impacts of an earthquake on the built environment. A new methodology to the urbanized systems and large-scale simulations within a seismic scenario are explored, by evaluating multipurpose codes for numerical simulation. A 3-D building shape of a standard virtual city is developed for evaluating the seismic effects at increasing intensities. Once the buildings are integrated into the city, parallel simulations are applied to compute the global behavior of buildings after a disruptive scenario. Monte Carlo Simulations (MCS) are applied to take into account the epistemic uncertainties associated with geometry and mechanical properties within the range of observations. For each set of buildings' data, the nonlinear dynamic analysis is performed through SAP2000 Application Programming Interface (API) in order to assess the dynamic response of the buildings in an organized and automatic fashion. Accordingly, the city is mapped into different zones representative to the possibility of having different levels of damage (complete, extensive, moderate, and slight). This tool supports decision-makers to explore how their community will respond to a disruptive event, to develop different strategies for monitoring and control the emergency in urbanized areas.",

author = "G.P. Cimellaro and S. Marasco and \{Zamani Noori\}, A. and O. Kammouh and S. Mahin",

note = "Publisher Copyright: Copyright {\textcopyright} NCEE 2018: Integrating Science, Engineering, and Policy.All rights reserved.; 11th National Conference on Earthquake Engineering 2018: Integrating Science, Engineering, and Policy, NCEE 2018 ; Conference date: 25-06-2018 Through 29-06-2018",

year = "2018",

language = "English",

volume = "9",

pages = "5606--5617",

booktitle = "11th National Conference on Earthquake Engineering 2018, NCEE 2018",

publisher = "Earthquake Engineering Research Institute",

address = "United States",

}

Cimellaro, GP, Marasco, S, Zamani Noori, A, Kammouh, O & Mahin, S 2018, A new tool to assess the resilience of an urban environment under an earthquake scenario. in 11th National Conference on Earthquake Engineering 2018, NCEE 2018: Integrating Science, Engineering, and Policy. vol. 9, Earthquake Engineering Research Institute, pp. 5606-5617, 11th National Conference on Earthquake Engineering 2018: Integrating Science, Engineering, and Policy, NCEE 2018, Los Angeles, United States, 25/06/18. <http://www.proceedings.com/41655.html>

A new tool to assess the resilience of an urban environment under an earthquake scenario. / Cimellaro, G.P.; Marasco, S.; Zamani Noori, A. et al.
11th National Conference on Earthquake Engineering 2018, NCEE 2018: Integrating Science, Engineering, and Policy. Vol. 9 Earthquake Engineering Research Institute, 2018. p. 5606-5617.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

TY - GEN

T1 - A new tool to assess the resilience of an urban environment under an earthquake scenario

AU - Cimellaro, G.P.

AU - Marasco, S.

AU - Zamani Noori, A.

AU - Kammouh, O.

AU - Mahin, S.

PY - 2018

Y1 - 2018

N2 - This paper presents a new methodology to predict the potential damage and physical impacts of an earthquake on the built environment. A new methodology to the urbanized systems and large-scale simulations within a seismic scenario are explored, by evaluating multipurpose codes for numerical simulation. A 3-D building shape of a standard virtual city is developed for evaluating the seismic effects at increasing intensities. Once the buildings are integrated into the city, parallel simulations are applied to compute the global behavior of buildings after a disruptive scenario. Monte Carlo Simulations (MCS) are applied to take into account the epistemic uncertainties associated with geometry and mechanical properties within the range of observations. For each set of buildings' data, the nonlinear dynamic analysis is performed through SAP2000 Application Programming Interface (API) in order to assess the dynamic response of the buildings in an organized and automatic fashion. Accordingly, the city is mapped into different zones representative to the possibility of having different levels of damage (complete, extensive, moderate, and slight). This tool supports decision-makers to explore how their community will respond to a disruptive event, to develop different strategies for monitoring and control the emergency in urbanized areas.

AB - This paper presents a new methodology to predict the potential damage and physical impacts of an earthquake on the built environment. A new methodology to the urbanized systems and large-scale simulations within a seismic scenario are explored, by evaluating multipurpose codes for numerical simulation. A 3-D building shape of a standard virtual city is developed for evaluating the seismic effects at increasing intensities. Once the buildings are integrated into the city, parallel simulations are applied to compute the global behavior of buildings after a disruptive scenario. Monte Carlo Simulations (MCS) are applied to take into account the epistemic uncertainties associated with geometry and mechanical properties within the range of observations. For each set of buildings' data, the nonlinear dynamic analysis is performed through SAP2000 Application Programming Interface (API) in order to assess the dynamic response of the buildings in an organized and automatic fashion. Accordingly, the city is mapped into different zones representative to the possibility of having different levels of damage (complete, extensive, moderate, and slight). This tool supports decision-makers to explore how their community will respond to a disruptive event, to develop different strategies for monitoring and control the emergency in urbanized areas.

UR - https://www.scopus.com/pages/publications/85085502519

UR - http://toc.proceedings.com/41655webtoc.pdf

M3 - Conference contribution

AN - SCOPUS:85085502519

VL - 9

SP - 5606

EP - 5617

BT - 11th National Conference on Earthquake Engineering 2018, NCEE 2018

PB - Earthquake Engineering Research Institute

T2 - 11th National Conference on Earthquake Engineering 2018: Integrating Science, Engineering, and Policy, NCEE 2018

Y2 - 25 June 2018 through 29 June 2018

ER -

A new tool to assess the resilience of an urban environment under an earthquake scenario

Abstract

Conference

Funding

Access to Document

Other files and links

Fingerprint

Cite this