Approximation of epidemic models by diffusion processes and their statistical inference
Abstract
Multidimensional continuous-time Markov jump processes on form a usual set-up for modeling -like epidemics. However, when facing incomplete epidemic data, inference based on is not easy to be achieved. Here, we start building a new framework for the estimation of key parameters of epidemic models based on statistics of diffusion processes approximating . First, \previous results on the approximation of density-dependent -like models by diffusion processes with small diffusion coefficient , where is the population size, are generalized to non-autonomous systems. Second, our previous inference results on discretely observed diffusion processes with small diffusion coefficient are extended to time-dependent diffusions. Consistent and asymptotically Gaussian estimates are obtained for a fixed number of observations, which corresponds to the epidemic context, and for . A correction term, which yields better estimates non asymptotically, is also included. Finally, performances and robustness of our estimators with respect to various parameters such as (the basic reproduction number), , are investigated on simulations. Two models, and , corresponding to single and recurrent outbreaks, respectively, are used to simulate data. The findings indicate that our estimators have good asymptotic properties and behave noticeably well for realistic numbers of observations and population sizes. This study lays the foundations of a generic inference method currently under extension to incompletely observed epidemic data. Indeed, contrary to the majority of current inference techniques for partially observed processes, which necessitates computer intensive simulations, our method being mostly an analytical approach requires only the classical optimization steps.
Cite
@article{arxiv.1305.3492,
title = {Approximation of epidemic models by diffusion processes and their statistical inference},
author = {Romain Guy and Catherine Larédo and Elisabeta Vergu},
journal= {arXiv preprint arXiv:1305.3492},
year = {2014}
}
Comments
30 pages, 10 figures