Risk-based models for emergency shelter and exit design in buildings

Reza Faturechi; Shabtai Isaac; Elise Miller-Hooks; Lei Feng

doi:10.1007/s10479-016-2223-3

Risk-based models for emergency shelter and exit design in buildings

Reza Faturechi, Shabtai Isaac, Elise Miller-Hooks, Lei Feng

Department of Civil and Environmental Engineering

Ben-Gurion University of the Negev

Research output: Contribution to journal › Article › peer-review

Abstract

Mathematical models are presented that support the design of shelters and exits in buildings, along with hallway fortification strategies and associated evacuation paths. The objective of these models is to optimally protect building users and prevent casualties during emergencies by minimizing the risk to which evacuees are exposed during evacuation and after reaching their destinations. The models involve stochastic programming and robust optimization concepts under both user equilibrium (selfish) and system optimal (altruistic) conditions. These approaches are compared in a case study involving a single-story building. A multi-hazard approach is utilized in which the performance of a design is tested given various possible future emergency scenarios.

Original language	American English
Pages (from-to)	185-212
Number of pages	28
Journal	Annals of Operations Research
Volume	262
Issue number	1
DOIs	https://doi.org/10.1007/s10479-016-2223-3
State	Published - 1 Mar 2018

Keywords

Building evacuation
Risk exposure
Robust optimization
Sheltering
Stochastic programming

All Science Journal Classification (ASJC) codes

General Decision Sciences
Management Science and Operations Research

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10.1007/s10479-016-2223-3

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title = "Risk-based models for emergency shelter and exit design in buildings",

abstract = "Mathematical models are presented that support the design of shelters and exits in buildings, along with hallway fortification strategies and associated evacuation paths. The objective of these models is to optimally protect building users and prevent casualties during emergencies by minimizing the risk to which evacuees are exposed during evacuation and after reaching their destinations. The models involve stochastic programming and robust optimization concepts under both user equilibrium (selfish) and system optimal (altruistic) conditions. These approaches are compared in a case study involving a single-story building. A multi-hazard approach is utilized in which the performance of a design is tested given various possible future emergency scenarios.",

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AU - Isaac, Shabtai

AU - Miller-Hooks, Elise

AU - Feng, Lei

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Y1 - 2018/3/1

N2 - Mathematical models are presented that support the design of shelters and exits in buildings, along with hallway fortification strategies and associated evacuation paths. The objective of these models is to optimally protect building users and prevent casualties during emergencies by minimizing the risk to which evacuees are exposed during evacuation and after reaching their destinations. The models involve stochastic programming and robust optimization concepts under both user equilibrium (selfish) and system optimal (altruistic) conditions. These approaches are compared in a case study involving a single-story building. A multi-hazard approach is utilized in which the performance of a design is tested given various possible future emergency scenarios.

AB - Mathematical models are presented that support the design of shelters and exits in buildings, along with hallway fortification strategies and associated evacuation paths. The objective of these models is to optimally protect building users and prevent casualties during emergencies by minimizing the risk to which evacuees are exposed during evacuation and after reaching their destinations. The models involve stochastic programming and robust optimization concepts under both user equilibrium (selfish) and system optimal (altruistic) conditions. These approaches are compared in a case study involving a single-story building. A multi-hazard approach is utilized in which the performance of a design is tested given various possible future emergency scenarios.

KW - Building evacuation

KW - Risk exposure

KW - Robust optimization

KW - Sheltering

KW - Stochastic programming

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DO - 10.1007/s10479-016-2223-3

M3 - Article

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VL - 262

SP - 185

EP - 212

JO - Annals of Operations Research

JF - Annals of Operations Research

IS - 1

ER -

Risk-based models for emergency shelter and exit design in buildings

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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