2009
DOI: 10.3141/2091-10
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Approach to Modeling Demand and Supply for a Short-Notice Evacuation

Abstract: than 24 or 48 h, as in the case of a hurricane evacuation). When the time to evacuate is considerably less, people may need to be evacuated directly from their current locations. The timing and magnitude of certain types of disasters may require faster reactions. People may receive short notice about the emergency and their need to evacuate, providing little or no time to return home before evacuating. In addition, for some disasters, the spatial extent of the evacuated area may change over time. This problem … Show more

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Cited by 34 publications
(18 citation statements)
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“…More recently, a large number of evacuation studies are conducted using well-established dynamic traffic simulation models developed for regular day-to-day traffic applications, including both microscopic models, such as PARAMICS (Cova and Johnson 2003), CORSIM (Williams et al 2007), VISSIM (Han and Yuan 2005), and INTEGRA-TION (Mitchell and Radwan 2006), and mesoscopic or macroscopic models, such as DYNASMART (Murray-Tuite 2007), DynaMIT (Balakrishna et al 2008), DynusT (Noh et al 2009), TransCAD (Wang et al 2010), and INDY (Klunder et al 2009). In a number of studies using microscopic models, model parameters describing driving behaviour (such as headway, acceleration, reaction time) have been adjusted for the case of emergency evacuation (e.g., Tu et al 2010).…”
Section: Past and Current Evacuation Traffic Simulation Modelsmentioning
confidence: 99%
“…More recently, a large number of evacuation studies are conducted using well-established dynamic traffic simulation models developed for regular day-to-day traffic applications, including both microscopic models, such as PARAMICS (Cova and Johnson 2003), CORSIM (Williams et al 2007), VISSIM (Han and Yuan 2005), and INTEGRA-TION (Mitchell and Radwan 2006), and mesoscopic or macroscopic models, such as DYNASMART (Murray-Tuite 2007), DynaMIT (Balakrishna et al 2008), DynusT (Noh et al 2009), TransCAD (Wang et al 2010), and INDY (Klunder et al 2009). In a number of studies using microscopic models, model parameters describing driving behaviour (such as headway, acceleration, reaction time) have been adjusted for the case of emergency evacuation (e.g., Tu et al 2010).…”
Section: Past and Current Evacuation Traffic Simulation Modelsmentioning
confidence: 99%
“…The benefit of the model is to capture the wave propagation effects through the ratio of the backward wave speed to the free-flow speed 8. For details of the CTM and CTM-based SO-DTA problem see Daganzo (1) and Ziliaskopoulos (2).…”
Section: Assigning Routes For Evacuees From Safe Zones To Final Destimentioning
confidence: 99%
“…Most descriptive models generate a priori what-if scenario-based evacuation plans (8)(9)(10)(11). When a need for evacuation arises, the best-fit plan is selected.…”
Section: Literature Reviewmentioning
confidence: 99%
“…In these cases, persons may need to be evacuated directly from their current location. For some disasters, the spatial extent of the evacuated area may change over time (Noh et al 2009). In another study, the evacuation scheduling problem was formulated as a mathematical programming model to minimize the total travel time by controlling demand (Chiu 2004).…”
Section: Introductionmentioning
confidence: 99%