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Main Authors: Balderrama, Rocío, Prieto, Mariana Inés, de la Vega, Constanza Sánchez, Vazquez, Federico
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2406.06770
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author Balderrama, Rocío
Prieto, Mariana Inés
de la Vega, Constanza Sánchez
Vazquez, Federico
author_facet Balderrama, Rocío
Prieto, Mariana Inés
de la Vega, Constanza Sánchez
Vazquez, Federico
contents This paper analyses the optimal control of infectious disease propagation using a classic susceptible-infected-recovered (SIR) model characterised by permanent immunity and the absence of available vaccines. The control is performed over a time-dependent mean reproduction number, in order to minimise the cumulative number of ever-infected individuals (recovered), under different constraints. We consider constraints on isolation measures ranging from partial lockdown to non-intervention, as well as the social and economic costs associated with such isolation, and the capacity limitations of intensive care units that limits the number of infected individuals to a maximum allowed value. We rigorously derive an optimal quarantine strategy based on necessary optimality conditions. The obtained optimal strategy is of a boundary-bang type, comprising three phases: an initial phase with no intervention, a second phase maintaining the infected population at its maximum possible value, and a final phase of partial lockdown applied over a single interval. The optimal policy is further refined by optimising the transition times between these phases. We show that these results are in excellent agreement with the numerical solution of the problem.
format Preprint
id arxiv_https___arxiv_org_abs_2406_06770
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Optimal control for a SIR model with limited hospitalised patients
Balderrama, Rocío
Prieto, Mariana Inés
de la Vega, Constanza Sánchez
Vazquez, Federico
Optimization and Control
Physics and Society
This paper analyses the optimal control of infectious disease propagation using a classic susceptible-infected-recovered (SIR) model characterised by permanent immunity and the absence of available vaccines. The control is performed over a time-dependent mean reproduction number, in order to minimise the cumulative number of ever-infected individuals (recovered), under different constraints. We consider constraints on isolation measures ranging from partial lockdown to non-intervention, as well as the social and economic costs associated with such isolation, and the capacity limitations of intensive care units that limits the number of infected individuals to a maximum allowed value. We rigorously derive an optimal quarantine strategy based on necessary optimality conditions. The obtained optimal strategy is of a boundary-bang type, comprising three phases: an initial phase with no intervention, a second phase maintaining the infected population at its maximum possible value, and a final phase of partial lockdown applied over a single interval. The optimal policy is further refined by optimising the transition times between these phases. We show that these results are in excellent agreement with the numerical solution of the problem.
title Optimal control for a SIR model with limited hospitalised patients
topic Optimization and Control
Physics and Society
url https://arxiv.org/abs/2406.06770