Data-driven optimized control of the COVID-19 epidemics

Data-driven optimized control of the COVID-19 epidemics

Optimizing the impact on the economy of control strategies aiming at containing the spread of COVID-19 is a critical challenge. We use daily new case counts of COVID-19 patients reported by local health administrations from different Metropolitan Statistical Areas (MSAs) within the US to parametrize...

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Bibliographic Details
Published in:Scientific reports 2021-03, Vol.11 (1), p.6525-6525, Article 6525
Main Authors: Shirin, Afroza, Lin, Yen Ting, Sorrentino, Francesco
Format: Article
Language:eng
Subjects:
60 APPLIED LIFE SCIENCES
Applied mathematics
Biological Science
Coronaviruses
COVID-19
COVID-19 - epidemiology
COVID-19 - prevention & control
COVID-19 - transmission
COVID-19 - virology
Epidemics
Humans
Mathematics
Models, Theoretical
Physical Distancing
Quarantine
SARS-CoV-2 - isolation & purification
Scientific data
Social distancing
Statistical physics, thermodynamics and nonlinear dynamics
United States - epidemiology
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Summary:Optimizing the impact on the economy of control strategies aiming at containing the spread of COVID-19 is a critical challenge. We use daily new case counts of COVID-19 patients reported by local health administrations from different Metropolitan Statistical Areas (MSAs) within the US to parametrize a model that well describes the propagation of the disease in each area. We then introduce a time-varying control input that represents the level of social distancing imposed on the population of a given area and solve an optimal control problem with the goal of minimizing the impact of social distancing on the economy in the presence of relevant constraints, such as a desired level of suppression for the epidemics at a terminal time. We find that with the exception of the initial time and of the final time, the optimal control input is well approximated by a constant, specific to each area, which contrasts with the implemented system of reopening 'in phases'. For all the areas considered, this optimal level corresponds to stricter social distancing than the level estimated from data. Proper selection of the time period for application of the control action optimally is important: depending on the particular MSA this period should be either short or long or intermediate. We also consider the case that the transmissibility increases in time (due e.g. to increasingly colder weather), for which we find that the optimal control solution yields progressively stricter measures of social distancing. We finally compute the optimal control solution for a model modified to incorporate the effects of vaccinations on the population and we see that depending on a number of factors, social distancing measures could be optimally reduced during the period over which vaccines are administered to the population.
ISSN:2045-2322
2045-2322