Containing Epidemic Outbreaks by Message-Passing Techniques

The problem of targeted network immunization can be defined as the one of finding a subset of nodes in a network to immunize or vaccinate in order to minimize a tradeoff between the cost of vaccination and the final (stationary) expected infection under a given epidemic model. Although computing the...

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Main Authors: F. Altarelli, A. Braunstein, L. Dall’Asta, J. R. Wakeling, R. Zecchina
Format: Article
Language:English
Published: American Physical Society 2014-05-01
Series:Physical Review X
Online Access:http://doi.org/10.1103/PhysRevX.4.021024
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spelling doaj-6f09cdc1088d4e268493531acc0e3c432020-11-25T00:09:27ZengAmerican Physical SocietyPhysical Review X2160-33082014-05-014202102410.1103/PhysRevX.4.021024Containing Epidemic Outbreaks by Message-Passing TechniquesF. AltarelliA. BraunsteinL. Dall’AstaJ. R. WakelingR. ZecchinaThe problem of targeted network immunization can be defined as the one of finding a subset of nodes in a network to immunize or vaccinate in order to minimize a tradeoff between the cost of vaccination and the final (stationary) expected infection under a given epidemic model. Although computing the expected infection is a hard computational problem, simple and efficient mean-field approximations have been put forward in the literature in recent years. The optimization problem can be recast into a constrained one in which the constraints enforce local mean-field equations describing the average stationary state of the epidemic process. For a wide class of epidemic models, including the susceptible-infected-removed and the susceptible-infected-susceptible models, we define a message-passing approach to network immunization that allows us to study the statistical properties of epidemic outbreaks in the presence of immunized nodes as well as to find (nearly) optimal immunization sets for a given choice of parameters and costs. The algorithm scales linearly with the size of the graph, and it can be made efficient even on large networks. We compare its performance with topologically based heuristics, greedy methods, and simulated annealing on both random graphs and real-world networks.http://doi.org/10.1103/PhysRevX.4.021024
collection DOAJ
language English
format Article
sources DOAJ
author F. Altarelli
A. Braunstein
L. Dall’Asta
J. R. Wakeling
R. Zecchina
spellingShingle F. Altarelli
A. Braunstein
L. Dall’Asta
J. R. Wakeling
R. Zecchina
Containing Epidemic Outbreaks by Message-Passing Techniques
Physical Review X
author_facet F. Altarelli
A. Braunstein
L. Dall’Asta
J. R. Wakeling
R. Zecchina
author_sort F. Altarelli
title Containing Epidemic Outbreaks by Message-Passing Techniques
title_short Containing Epidemic Outbreaks by Message-Passing Techniques
title_full Containing Epidemic Outbreaks by Message-Passing Techniques
title_fullStr Containing Epidemic Outbreaks by Message-Passing Techniques
title_full_unstemmed Containing Epidemic Outbreaks by Message-Passing Techniques
title_sort containing epidemic outbreaks by message-passing techniques
publisher American Physical Society
series Physical Review X
issn 2160-3308
publishDate 2014-05-01
description The problem of targeted network immunization can be defined as the one of finding a subset of nodes in a network to immunize or vaccinate in order to minimize a tradeoff between the cost of vaccination and the final (stationary) expected infection under a given epidemic model. Although computing the expected infection is a hard computational problem, simple and efficient mean-field approximations have been put forward in the literature in recent years. The optimization problem can be recast into a constrained one in which the constraints enforce local mean-field equations describing the average stationary state of the epidemic process. For a wide class of epidemic models, including the susceptible-infected-removed and the susceptible-infected-susceptible models, we define a message-passing approach to network immunization that allows us to study the statistical properties of epidemic outbreaks in the presence of immunized nodes as well as to find (nearly) optimal immunization sets for a given choice of parameters and costs. The algorithm scales linearly with the size of the graph, and it can be made efficient even on large networks. We compare its performance with topologically based heuristics, greedy methods, and simulated annealing on both random graphs and real-world networks.
url http://doi.org/10.1103/PhysRevX.4.021024
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