We present a bond percolation model for community clustered networks with an arbitrarily specified joint degree distribution. Our model is based on the Probability Generating Function (PGF) method for multitype networks, but incorporate the free-excess degree distribution, which makes it applicable for clustered networks. In the context of contact network epidemiology, our model serves as a special case of community clustered networks which are more appropriate for modelling the disease transmission in community networks with clustering effects. Beyond the percolation threshold, we are able to obtain the probability that a randomly chosen community-$i$ node leads to the giant component. The probability refers to the probability that an indi...
This dissertation contributes to a methodology and a better understanding that can be used to study ...
© 2018 Elsevier Inc. A large number of real world networks exhibit community structure, and differen...
International audienceMotivated by the analysis of social networks, we study a model of random netwo...
Human contact networks exhibit the community structure. Understanding how such commu-nity structure ...
Networks provide a mathematically rich framework to represent social contacts sufficient for the tra...
Many real-world networks display a community structure. We study two random graph models that create...
It is now well appreciated that population structure can have a major impact on disease dynamics, ou...
In this dissertation, we present research on several topics in networks including community detectio...
Realistic human contact networks capable of spreading infectious disease, for example studied in soc...
This paper presents a compact pairwise model that describes the spread of multi-stage epidemics on n...
In this paper we introduce a description of the equilibrium state of a bond percolation process on r...
We investigate the effects of heterogeneous and clustered contact patterns on the timescale and fina...
We consider a model for the diffusion of epidemics in a population that is partitioned into local co...
Erik M. Volz is with University of Michigan, Joel C. Miller is with Harvard University and the Natio...
Clustering is the propensity of nodes that share a common neighbour to be connected. It is ubiquitou...
This dissertation contributes to a methodology and a better understanding that can be used to study ...
© 2018 Elsevier Inc. A large number of real world networks exhibit community structure, and differen...
International audienceMotivated by the analysis of social networks, we study a model of random netwo...
Human contact networks exhibit the community structure. Understanding how such commu-nity structure ...
Networks provide a mathematically rich framework to represent social contacts sufficient for the tra...
Many real-world networks display a community structure. We study two random graph models that create...
It is now well appreciated that population structure can have a major impact on disease dynamics, ou...
In this dissertation, we present research on several topics in networks including community detectio...
Realistic human contact networks capable of spreading infectious disease, for example studied in soc...
This paper presents a compact pairwise model that describes the spread of multi-stage epidemics on n...
In this paper we introduce a description of the equilibrium state of a bond percolation process on r...
We investigate the effects of heterogeneous and clustered contact patterns on the timescale and fina...
We consider a model for the diffusion of epidemics in a population that is partitioned into local co...
Erik M. Volz is with University of Michigan, Joel C. Miller is with Harvard University and the Natio...
Clustering is the propensity of nodes that share a common neighbour to be connected. It is ubiquitou...
This dissertation contributes to a methodology and a better understanding that can be used to study ...
© 2018 Elsevier Inc. A large number of real world networks exhibit community structure, and differen...
International audienceMotivated by the analysis of social networks, we study a model of random netwo...