English

Branching process and homogeneization for epidemics on spatial random graphs

Probability 2023-04-05 v2

Abstract

Consider a graph where the sites are distributed in space according to a Poisson point process on Rn\mathbb R^n. We study a population evolving on this network, with individuals jumping between sites with a rate which decreases exponentially in the distance. Individuals give also birth (infection) and die (recovery) at constant rate on each site. First, we construct the process, showing that it is well-posed even when starting from non-bounded initial conditions. Secondly, we prove hydrodynamic limits in a diffusive scaling. The limiting process follows a deterministic reaction diffusion equation. We use stochastic homogenization to characterize its diffusion coefficient as the solution of a variational principle. The proof involves in particular the extension of a classic Kipnis-Varadhan estimate to cope with the non-reversiblity of the process, due to births and deaths. This work is motivated by the approximation of epidemics on large networks and the results are extended to more complex graphs including percolation of edges.

Keywords

Cite

@article{arxiv.2301.04890,
  title  = {Branching process and homogeneization for epidemics on spatial random graphs},
  author = {Vincent Bansaye and Michele Salvi},
  journal= {arXiv preprint arXiv:2301.04890},
  year   = {2023}
}

Comments

are welcome! 37 pages

R2 v1 2026-06-28T08:10:03.031Z