When modelling metapopulation dynamics, the influence of a single patch on the metapopulation depends on the number of individuals in the patch. Since the population size has no natural upper limit, this leads to systems in which there are countably infinitely many possible types of individual. Analogous considerations apply in the transmission of parasitic diseases. In this paper, we prove a law of large numbers for quite general systems of this kind, together with a rather sharp bound on the rate of convergence in an appropriately chosen weighted ℓ 1 norm
International audienceWe are interested in the dynamic of a structured branching population where th...
We describe a class of one-dimensional chain binomial models of use in studying metapopulations (pop...
In this survey paper, we review the recent advances in individual based non--Markovian epidemic mode...
When modelling metapopulation dynamics, the influence of a single patch on the metapopulation depend...
When modelling metapopulation dynamics, the influence of a single patch on the metapopula...
In modeling parasitic diseases, it is natural to distinguish hosts according to the number of parasi...
Density dependent Markov population processes with countably many types can often be well approximat...
This paper presents a law of large numbers result, as the size of the population tends to infinity, ...
AbstractBy means of the law of large numbers and the central limit theorem, we compare the spatial e...
We study a class of individual-based, fixed-population size epidemic models under general assumption...
We consider a population with non-overlapping generations, whose size goes to infinity. It is descri...
International audienceWe study epidemic models where the infectivity of each individual is a random ...
The current work deals with an epidemic model on the complete graph K_n on n vertices in a non-homog...
The first chapter concerns monotype population models. We first study general birth and death proces...
International audienceWe are interested in the dynamic of a structured branching population where th...
We describe a class of one-dimensional chain binomial models of use in studying metapopulations (pop...
In this survey paper, we review the recent advances in individual based non--Markovian epidemic mode...
When modelling metapopulation dynamics, the influence of a single patch on the metapopulation depend...
When modelling metapopulation dynamics, the influence of a single patch on the metapopula...
In modeling parasitic diseases, it is natural to distinguish hosts according to the number of parasi...
Density dependent Markov population processes with countably many types can often be well approximat...
This paper presents a law of large numbers result, as the size of the population tends to infinity, ...
AbstractBy means of the law of large numbers and the central limit theorem, we compare the spatial e...
We study a class of individual-based, fixed-population size epidemic models under general assumption...
We consider a population with non-overlapping generations, whose size goes to infinity. It is descri...
International audienceWe study epidemic models where the infectivity of each individual is a random ...
The current work deals with an epidemic model on the complete graph K_n on n vertices in a non-homog...
The first chapter concerns monotype population models. We first study general birth and death proces...
International audienceWe are interested in the dynamic of a structured branching population where th...
We describe a class of one-dimensional chain binomial models of use in studying metapopulations (pop...
In this survey paper, we review the recent advances in individual based non--Markovian epidemic mode...