We consider an SIS-type epidemic process that evolves on a known graph. We assume that a fixed curing budget can be allocated at each instant to the nodes of the graph, towards the objective of minimizing the expected extinction time of the epidemic. We provide a lower bound on the optimal expected extinction time as a function of the available budget, the epidemic parameters, the maximum degree, and the CutWidth of the graph. For graphs with large CutWidth (close to the largest possible), and under a budget which is sublinear in the number of nodes, our lower bound scales exponentially with the size of the graph.United States. Army Research Office (Grant W911NF-12-1-0509)National Science Foundation (U.S.) (Grant CMMI-1234062
abstract: This thesis discusses three recent optimization problems that seek to reduce disease sprea...
We consider a Markovian SIR-type (Susceptible → Infected → Recovered) stochastic epidemic process wi...
In the Susceptible–Infectious–Recovered (SIR) model of disease spreading, the time to extinction of ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...
We consider the propagation of a contagion process (“epidemic”) on a network and study the problem o...
The design of an efficient curing policy, able to stem an epidemic process at an affordable cost, ha...
The survival time T is the longest time that a virus, a meme, or a failure can propagate in a networ...
In previous modelling efforts to understand the spreading process on networks, each node can infect ...
Local interactions on a graph will lead to global dynamic behaviour. In this thesis we focus on two ...
We consider the contact process on finite and connected graphs and study the behavior of the extinct...
In this paper we quantify the total cost of an epidemic spreading through a social network, accounti...
The effect of virus spreading in a telecommunication network, where a certain curing strategy is dep...
In this paper, we introduce the class of priority planning strategies for suppressing SIS epidemics ...
Abstract—The effect of virus spreading in a telecommunication network, where a certain curing strate...
We consider the extinction time of the contact process on increasing sequences of finite graphs obta...
abstract: This thesis discusses three recent optimization problems that seek to reduce disease sprea...
We consider a Markovian SIR-type (Susceptible → Infected → Recovered) stochastic epidemic process wi...
In the Susceptible–Infectious–Recovered (SIR) model of disease spreading, the time to extinction of ...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Electrical Engineering and Comp...
We consider the propagation of a contagion process (“epidemic”) on a network and study the problem o...
The design of an efficient curing policy, able to stem an epidemic process at an affordable cost, ha...
The survival time T is the longest time that a virus, a meme, or a failure can propagate in a networ...
In previous modelling efforts to understand the spreading process on networks, each node can infect ...
Local interactions on a graph will lead to global dynamic behaviour. In this thesis we focus on two ...
We consider the contact process on finite and connected graphs and study the behavior of the extinct...
In this paper we quantify the total cost of an epidemic spreading through a social network, accounti...
The effect of virus spreading in a telecommunication network, where a certain curing strategy is dep...
In this paper, we introduce the class of priority planning strategies for suppressing SIS epidemics ...
Abstract—The effect of virus spreading in a telecommunication network, where a certain curing strate...
We consider the extinction time of the contact process on increasing sequences of finite graphs obta...
abstract: This thesis discusses three recent optimization problems that seek to reduce disease sprea...
We consider a Markovian SIR-type (Susceptible → Infected → Recovered) stochastic epidemic process wi...
In the Susceptible–Infectious–Recovered (SIR) model of disease spreading, the time to extinction of ...