In modeling parasitic diseases, it is natural to distinguish hosts according to the number of parasites that they carry, leading to a countably infinite type space. Proving the analogue of the deterministic equations, used in models with finitely many types as a “law of large numbers” approximation to the underlying stochastic model, has previously either been done case by case, using some special structure, or else not attempted. In this paper we prove a general theorem of this sort, and complement it with a rate of convergence in the ℓ1-norm
We study contact epidemic models for the spread of infective diseases in finite populations. The siz...
AbstractThe large population asymptotics of a spatial epidemic model is studied through the represen...
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...
When modelling metapopulation dynamics, the influence of a single patch on the metapopulation depend...
International audienceThis paper presents a law of large numbers result, as the size of the populati...
International audienceWe study epidemic models where the infectivity of each individual is a random ...
We study epidemic models where the infectivity of each individual is a random function of the infect...
We study a class of individual-based, fixed-population size epidemic models under general assumption...
Abstract. We establish law of large numbers for SIRS stochastic epi-demic processes: as the populati...
AbstractBy means of the law of large numbers and the central limit theorem, we compare the spatial e...
We study a multilayer SIR model with two levels of mixing, namely a global level which is uniformly ...
International audienceWe introduce an epidemic model with varying infectivity and general exposed an...
We introduce an epidemic model with varying infectivity and general exposed and infectious periods, ...
We study contact epidemic models for the spread of infective diseases in finite populations. The siz...
AbstractThe large population asymptotics of a spatial epidemic model is studied through the represen...
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...
When modelling metapopulation dynamics, the influence of a single patch on the metapopulation depend...
International audienceThis paper presents a law of large numbers result, as the size of the populati...
International audienceWe study epidemic models where the infectivity of each individual is a random ...
We study epidemic models where the infectivity of each individual is a random function of the infect...
We study a class of individual-based, fixed-population size epidemic models under general assumption...
Abstract. We establish law of large numbers for SIRS stochastic epi-demic processes: as the populati...
AbstractBy means of the law of large numbers and the central limit theorem, we compare the spatial e...
We study a multilayer SIR model with two levels of mixing, namely a global level which is uniformly ...
International audienceWe introduce an epidemic model with varying infectivity and general exposed an...
We introduce an epidemic model with varying infectivity and general exposed and infectious periods, ...
We study contact epidemic models for the spread of infective diseases in finite populations. The siz...
AbstractThe large population asymptotics of a spatial epidemic model is studied through the represen...
When modelling metapopulation dynamics, the influence of a single patch on the metapopula...