A four compartment epidemic model with retarded transition rates

TL;DR

This paper introduces a four-compartment epidemic model with memory effects via fractional derivatives, analyzing equilibrium, stability, and oscillations, and validates results through microscopic simulations of random walkers.

Contribution

It develops a novel epidemic model incorporating memory through fractional derivatives and connects macroscopic equations with microscopic random walk simulations.

Findings

Derived conditions for endemic equilibrium existence.

Analyzed stability and oscillatory behavior of equilibria.

Validated macroscopic model with microscopic random walk simulations.

Abstract

We study an epidemic model for a constant population by taking into account four compartments of the individuals characterizing their states of health. Each individual is in one of the compartments susceptible (S); incubated - infected yet not infectious (C), infected and infectious (I), and recovered - immune (R). An infection is 'visible' only when an individual is in state I. Upon infection, an individual performs the transition pathway S to C to I to R to S remaining in each compartments C, I, and R for certain random waiting times, respectively. The waiting times for each compartment are independent and drawn from specific probability density functions (PDFs) introducing memory into the model. We derive memory evolution equations involving convolutions (time derivatives of general fractional type). We obtain formulae for the endemic equilibrium and a condition of its existence for cases when the waiting time PDFs have existing means. We analyze the stability of healthy and endemic equilibria and derive conditions for which the endemic state becomes oscillatory (Hopf) unstable. We implement a simple multiple random walker's approach (microscopic model of Brownian motion of Z independent walkers) with random SCIRS waiting times into computer simulations. Infections occur with a certain probability by collisions of walkers in compartments I and S. We compare the endemic states predicted in the macroscopic model with the numerical results of the simulations and find accordance of high accuracy. We conclude that a simple random walker's approach offers an appropriate microscopic description for the macroscopic model.