Abdul-Aziz Yakubu, Howard University

Abstract

We use a general autonomous discrete-time infectious disease model to extend the next generation matrix approach for calculating the basic reproduction number, R₀, to account for populations with locally asymptotically stable period k cycles in the disease-free systems, where k≥1.When R₀<1 and the demographic equation (in the absence of the disease) has a locally asymptotically stable period k population cycle, we prove the local asymptotic stability of the disease-free period k cycle. That is, the disease goes extinct whenever R₀<1. Under the same period k demographic assumption but with R₀>1, we prove that the disease-free period k population cycle is unstable and the disease persists. Using the Ricker recruitment function, we apply our results to discrete-time infectious disease models that are formulated for SIR infections with and without vaccination, and ISAv infections in a salmon population. When R₀>1, our simulations show that the disease-free period k cycle dynamics drives the SIR disease dynamics, but not the ISAv disease dynamics (This is joint work with P. van den Driessche).