Saved in:
Bibliographic Details
Main Authors: Bongarti, Marcelo, Parkinson, Christian, Wang, Weinan
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.17298
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916605339893760
author Bongarti, Marcelo
Parkinson, Christian
Wang, Weinan
author_facet Bongarti, Marcelo
Parkinson, Christian
Wang, Weinan
contents In this paper, we consider an optimal distributed control problem for a reaction-diffusion-based SIR epidemic model with human behavioral effects. We develop a model wherein non-pharmaceutical intervention methods are implemented, but a portion of the population does not comply with them, and this noncompliance affects the spread of the disease. Drawing from social contagion theory, our model allows for the spread of noncompliance parallel to the spread of the disease. The quantities of interest for control are the reduction in infection rate among the compliant population, the rate of spread of noncompliance, and the rate at which non-compliant individuals become compliant after, e.g., receiving more or better information about the underlying disease. We prove the existence of global-in-time solutions for fixed controls and study the regularity properties of the resulting control-to-state map. The existence of optimal control is then established in an abstract framework for a fairly general class of objective functions. Necessary first--order optimality conditions are obtained via a Lagrangian based stationarity system. We conclude with a discussion regarding minimization of the size of infected and non-compliant populations and present simulations with various parameters values to demonstrate the behavior of the model.
format Preprint
id arxiv_https___arxiv_org_abs_2407_17298
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Optimal Control of a Reaction-Diffusion Epidemic Model with Noncompliance
Bongarti, Marcelo
Parkinson, Christian
Wang, Weinan
Analysis of PDEs
Optimization and Control
35K55, 35K57, 92D30, 49M41, 49N90
In this paper, we consider an optimal distributed control problem for a reaction-diffusion-based SIR epidemic model with human behavioral effects. We develop a model wherein non-pharmaceutical intervention methods are implemented, but a portion of the population does not comply with them, and this noncompliance affects the spread of the disease. Drawing from social contagion theory, our model allows for the spread of noncompliance parallel to the spread of the disease. The quantities of interest for control are the reduction in infection rate among the compliant population, the rate of spread of noncompliance, and the rate at which non-compliant individuals become compliant after, e.g., receiving more or better information about the underlying disease. We prove the existence of global-in-time solutions for fixed controls and study the regularity properties of the resulting control-to-state map. The existence of optimal control is then established in an abstract framework for a fairly general class of objective functions. Necessary first--order optimality conditions are obtained via a Lagrangian based stationarity system. We conclude with a discussion regarding minimization of the size of infected and non-compliant populations and present simulations with various parameters values to demonstrate the behavior of the model.
title Optimal Control of a Reaction-Diffusion Epidemic Model with Noncompliance
topic Analysis of PDEs
Optimization and Control
35K55, 35K57, 92D30, 49M41, 49N90
url https://arxiv.org/abs/2407.17298