<p>Single virus epidemics over complete networks are widely explored in the literature as the fraction of infected nodes is, under appropriate microscopic modeling of the virus infection, a Markov process. With non-complete networks, this macroscopic variable is no longer Markov. In this paper, we study virus diffusion, in particular, multi-virus epidemics, over non-complete stochastic networks. We focus on multipartite networks. In companying work [1], we show that the peer-to-peer local random rules of virus infection lead, in the limit of large multipartite networks, to the emergence of structured dynamics at the macroscale. The exact fluid limit evolution of the fraction of nodes infected by each virus strain across islands obeys a set ...
Master's thesis in Mathematics and PhysicsThe spread of a virus or the outbreak of an epidemic are n...
This thesis considers stochastic epidemic models for the spread of epidemics in structured populatio...
Advances in the fields of mathematics, physics, epidemiology, and computing have led to an incredibl...
Single virus epidemics over complete networks are widely explored in the literature as the fraction ...
Epidemics in large complete networks is well established. In contrast, we consider epidemics in non-...
Epidemics in large complete networks is well established. In contrast, we consider epidemics in non-...
This Thesis studies bi-virus epidemics over large-scale networks. We set the rules of infection at t...
Abstract—Understanding the spreading dynamics of computer viruses (worms, attacks) is an important r...
We consider a Markovian SIR-type (Susceptible → Infected → Recovered) stochastic epidemic process wi...
This paper investigates the dynamics of infectious diseases with a nonexponentially distributed infe...
We study by analytical methods and large scale simulations a dynamical model for the spreading of ep...
Since a real epidemic process is not necessarily Markovian, the epidemic threshold obtained under th...
<div><p>Understanding models which represent the invasion of network-based systems by infectious age...
In this paper we extend previous work deriving dynamic equations governing infectious disease spread...
The study of epidemics on static networks has revealed important effects on disease prevalence of n...
Master's thesis in Mathematics and PhysicsThe spread of a virus or the outbreak of an epidemic are n...
This thesis considers stochastic epidemic models for the spread of epidemics in structured populatio...
Advances in the fields of mathematics, physics, epidemiology, and computing have led to an incredibl...
Single virus epidemics over complete networks are widely explored in the literature as the fraction ...
Epidemics in large complete networks is well established. In contrast, we consider epidemics in non-...
Epidemics in large complete networks is well established. In contrast, we consider epidemics in non-...
This Thesis studies bi-virus epidemics over large-scale networks. We set the rules of infection at t...
Abstract—Understanding the spreading dynamics of computer viruses (worms, attacks) is an important r...
We consider a Markovian SIR-type (Susceptible → Infected → Recovered) stochastic epidemic process wi...
This paper investigates the dynamics of infectious diseases with a nonexponentially distributed infe...
We study by analytical methods and large scale simulations a dynamical model for the spreading of ep...
Since a real epidemic process is not necessarily Markovian, the epidemic threshold obtained under th...
<div><p>Understanding models which represent the invasion of network-based systems by infectious age...
In this paper we extend previous work deriving dynamic equations governing infectious disease spread...
The study of epidemics on static networks has revealed important effects on disease prevalence of n...
Master's thesis in Mathematics and PhysicsThe spread of a virus or the outbreak of an epidemic are n...
This thesis considers stochastic epidemic models for the spread of epidemics in structured populatio...
Advances in the fields of mathematics, physics, epidemiology, and computing have led to an incredibl...