We present a thorough inspection of the dynamical behavior of epidemic phenomena in populations with complex and heterogeneous connectivity patterns. We show that the growth of the epidemic prevalence is virtually instantaneous in all networks characterized by diverging degree fluctuations, independently of the structure of the connectivity correlation functions characterizing the population network. By means of analytical and numerical results, we show that the outbreak time evolution follows a precise hierarchical dynamics. Once reached the most highly connected hubs, the infection pervades the network in a progressive cascade across smaller degree classes. Finally, we show the influence of the initial conditions and the relevance of stat...
In this paper, we propose a modified susceptible-infected-recovered (SIR) model, in which each node ...
We study a dynamical model of epidemic spreading on complex networks in which there are explicit cor...
Understanding the spread of diseases through complex networks is of great interest where realistic, ...
13 pages, 11 figuresWe present a thorough inspection of the dynamical behavior of epidemic phenomena...
We study the effect of the connectivity pattern of complex networks on the propagation dynamics of e...
We present a detailed analytical and numerical study for the spreading of infections with acquired i...
The dynamic nature of contact patterns creates diverse temporal structures. In particular, empirical...
The study of epidemics on static networks has revealed important effects on disease prevalence of ne...
We study by analytical methods and large scale simulations a dynamical model for the spreading of ep...
One of the famous results of network science states that networks with heterogeneous connectivity ar...
Realistic human contact networks capable of spreading infectious disease, for example studied in soc...
In many populations, the patterns of potentially infectious contacts are transients that can be desc...
Erik M. Volz is with University of Michigan, Joel C. Miller is with Harvard University and the Natio...
<div><p>The dynamic nature of contact patterns creates diverse temporal structures. In particular, e...
In this paper, we propose a modified susceptible-infected-recovered (SIR) model, in which each node ...
We study a dynamical model of epidemic spreading on complex networks in which there are explicit cor...
Understanding the spread of diseases through complex networks is of great interest where realistic, ...
13 pages, 11 figuresWe present a thorough inspection of the dynamical behavior of epidemic phenomena...
We study the effect of the connectivity pattern of complex networks on the propagation dynamics of e...
We present a detailed analytical and numerical study for the spreading of infections with acquired i...
The dynamic nature of contact patterns creates diverse temporal structures. In particular, empirical...
The study of epidemics on static networks has revealed important effects on disease prevalence of ne...
We study by analytical methods and large scale simulations a dynamical model for the spreading of ep...
One of the famous results of network science states that networks with heterogeneous connectivity ar...
Realistic human contact networks capable of spreading infectious disease, for example studied in soc...
In many populations, the patterns of potentially infectious contacts are transients that can be desc...
Erik M. Volz is with University of Michigan, Joel C. Miller is with Harvard University and the Natio...
<div><p>The dynamic nature of contact patterns creates diverse temporal structures. In particular, e...
In this paper, we propose a modified susceptible-infected-recovered (SIR) model, in which each node ...
We study a dynamical model of epidemic spreading on complex networks in which there are explicit cor...
Understanding the spread of diseases through complex networks is of great interest where realistic, ...