Optimal lock-down intensity: A stochastic pandemic control approach of path integral

Optimal lock-down intensity: A stochastic pandemic control approach of path integral

The aim of this article is to determine the optimal intensity of lock-down measures and vaccination rates to control the spread of coronavirus disease 2019. The study uses a stochastic susceptible-infected-recovered (SIR) model with infection dynamics. A Feynman-type path integral control approach i...

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Bibliografiska uppgifter
Huvudupphovsman: Pramanik Paramahansa
Materialtyp: Artikel
Språk:English
Publicerad: De Gruyter 2023-12-01
Serie:Computational and Mathematical Biophysics
Ämnen:
stochastic control
stochastic sir model
feynman-type path integral
disease spread networks
93e20
49k45
49l20
Länkar:https://doi.org/10.1515/cmb-2023-0110
Beskrivning
Sammanfattning:The aim of this article is to determine the optimal intensity of lock-down measures and vaccination rates to control the spread of coronavirus disease 2019. The study uses a stochastic susceptible-infected-recovered (SIR) model with infection dynamics. A Feynman-type path integral control approach is used to derive a forward Fokker-Plank-type equation for the system, which helps in performing a stochastic control analysis. The simulation study concludes that increasing the diffusion coefficients leads to a downward trend in the susceptible and recovery curves, while the infection curve becomes ergodic. Additionally, the study shows that the optimal lock-down intensity is stable around zero, and the vaccination rate increases over time.
ISSN:2544-7297

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