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Main Authors: He, Roxanne, Luczak, Malwina, Ross, Nathan
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2407.18446
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author He, Roxanne
Luczak, Malwina
Ross, Nathan
author_facet He, Roxanne
Luczak, Malwina
Ross, Nathan
contents We study a variant of the classical Markovian logistic SIS epidemic model on a complete graph, which has the additional feature that healthy individuals can become infected without contacting an infected member of the population. This additional ``self-infection'' is used to model situations where there is an unknown source of infection or an external disease reservoir, such as an animal carrier population. In contrast to the classical logistic SIS epidemic model, the version with self-infection has a non-degenerate stationary distribution, and we derive precise asymptotics for the time to converge to stationarity (mixing time) as the population size becomes large. It turns out that the chain exhibits the cutoff phenomenon, which is a sharp transition in time from one to zero of the total variation distance to stationarity. We obtain the exact leading constant for the cutoff time, and show the window size is constant (optimal) order. While this result is interesting in its own right, an additional contribution of our work is that the proof illustrates a recently formalised methodology of Barbour, Brightwell and Luczak, which can be used to show cutoff via a combination of concentration of measure inequalities for the trajectory of the chain, and coupling techniques.
format Preprint
id arxiv_https___arxiv_org_abs_2407_18446
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Cutoff for the logistic SIS epidemic model with self-infection
He, Roxanne
Luczak, Malwina
Ross, Nathan
Probability
We study a variant of the classical Markovian logistic SIS epidemic model on a complete graph, which has the additional feature that healthy individuals can become infected without contacting an infected member of the population. This additional ``self-infection'' is used to model situations where there is an unknown source of infection or an external disease reservoir, such as an animal carrier population. In contrast to the classical logistic SIS epidemic model, the version with self-infection has a non-degenerate stationary distribution, and we derive precise asymptotics for the time to converge to stationarity (mixing time) as the population size becomes large. It turns out that the chain exhibits the cutoff phenomenon, which is a sharp transition in time from one to zero of the total variation distance to stationarity. We obtain the exact leading constant for the cutoff time, and show the window size is constant (optimal) order. While this result is interesting in its own right, an additional contribution of our work is that the proof illustrates a recently formalised methodology of Barbour, Brightwell and Luczak, which can be used to show cutoff via a combination of concentration of measure inequalities for the trajectory of the chain, and coupling techniques.
title Cutoff for the logistic SIS epidemic model with self-infection
topic Probability
url https://arxiv.org/abs/2407.18446