Modeling airport congestion contagion by heterogeneous SIS epidemic spreading on airline networks

In this work, we explore the possibility of using a heterogeneous Susceptible- Infected-Susceptible SIS spreading process on an airline network to model airport congestion contagion with the objective to reproduce airport vulnerability. We derive the vulnerability of each airport from the US Airport...

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Veröffentlicht in:	PloS one 2021-01, Vol.16 (1), p.e0245043-e0245043
Hauptverfasser:	Ceria, Alberto, Köstler, Klemens, Gobardhan, Rommy, Wang, Huijuan
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Schlagworte:	Aerospace engineering Aircraft Airlines Airports Cerium oxides Computer and Information Sciences Computer engineering Computer science Datasets Disease susceptibility Disease transmission Editing Electric contacts Electrical engineering Engineering and Technology Epidemics Epidemics - prevention & control Health aspects Humans Infections Mathematical analysis Mathematics Medical research Medicine, Experimental Methodology Models, Theoretical Networks Physical Sciences Probability Schedules Social organization Social sciences Technology Traffic congestion Transportation
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creator	Ceria, Alberto Köstler, Klemens Gobardhan, Rommy Wang, Huijuan
description	In this work, we explore the possibility of using a heterogeneous Susceptible- Infected-Susceptible SIS spreading process on an airline network to model airport congestion contagion with the objective to reproduce airport vulnerability. We derive the vulnerability of each airport from the US Airport Network data as the congestion probability of each airport. In order to capture diverse flight features between airports, e.g. frequency and duration, we construct three types of airline networks. The infection rate of each link in the SIS spreading process is proportional to its corresponding weight in the underlying airline network constructed. The recovery rate of each node is also heterogeneous, dependent on its node strength in the underlying airline network, which is the total weight of the links incident to the node. Such heterogeneous recovery rate is motivated by the fact that large airports may recover fast from congestion due to their well-equipped infrastructures. The nodal infection probability in the meta-stable state is used as a prediction of the vulnerability of the corresponding airport. We illustrate that our model could reproduce the distribution of nodal vulnerability and rank the airports in vulnerability evidently better than the SIS model whose recovery rate is homogeneous. The vulnerability is the largest at airports whose strength in the airline network is neither too large nor too small. This phenomenon can be captured by our heterogeneous model, but not the homogeneous model where a node with a larger strength has a higher infection probability. This explains partially the out-performance of the heterogeneous model. This proposed congestion contagion model may shed lights on the development of strategies to identify vulnerable airports and to mitigate global congestion by e.g. congestion reduction at selected airports.
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one</jtitle><addtitle>PLoS One</addtitle><date>2021-01-22</date><risdate>2021</risdate><volume>16</volume><issue>1</issue><spage>e0245043</spage><epage>e0245043</epage><pages>e0245043-e0245043</pages><issn>1932-6203</issn><eissn>1932-6203</eissn><abstract>In this work, we explore the possibility of using a heterogeneous Susceptible- Infected-Susceptible SIS spreading process on an airline network to model airport congestion contagion with the objective to reproduce airport vulnerability. We derive the vulnerability of each airport from the US Airport Network data as the congestion probability of each airport. In order to capture diverse flight features between airports, e.g. frequency and duration, we construct three types of airline networks. The infection rate of each link in the SIS spreading process is proportional to its corresponding weight in the underlying airline network constructed. The recovery rate of each node is also heterogeneous, dependent on its node strength in the underlying airline network, which is the total weight of the links incident to the node. Such heterogeneous recovery rate is motivated by the fact that large airports may recover fast from congestion due to their well-equipped infrastructures. The nodal infection probability in the meta-stable state is used as a prediction of the vulnerability of the corresponding airport. We illustrate that our model could reproduce the distribution of nodal vulnerability and rank the airports in vulnerability evidently better than the SIS model whose recovery rate is homogeneous. The vulnerability is the largest at airports whose strength in the airline network is neither too large nor too small. This phenomenon can be captured by our heterogeneous model, but not the homogeneous model where a node with a larger strength has a higher infection probability. This explains partially the out-performance of the heterogeneous model. This proposed congestion contagion model may shed lights on the development of strategies to identify vulnerable airports and to mitigate global congestion by e.g. congestion reduction at selected airports.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>33481799</pmid><doi>10.1371/journal.pone.0245043</doi><tpages>e0245043</tpages><orcidid>https://orcid.org/0000-0003-2684-4407</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Aerospace engineering Aircraft Airlines Airports Cerium oxides Computer and Information Sciences Computer engineering Computer science Datasets Disease susceptibility Disease transmission Editing Electric contacts Electrical engineering Engineering and Technology Epidemics Epidemics - prevention & control Health aspects Humans Infections Mathematical analysis Mathematics Medical research Medicine, Experimental Methodology Models, Theoretical Networks Physical Sciences Probability Schedules Social organization Social sciences Technology Traffic congestion Transportation
title	Modeling airport congestion contagion by heterogeneous SIS epidemic spreading on airline networks
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