Estimation of epidemiological parameters for COVID-19 cases using a stochastic SEIRS epidemic model with vital dynamics

We estimate and analyze the time-dependent parameters: transmission rate, symptomatic recovery rate, immunity rate, infection noise intensities, and the effective reproduction number for the United States COVID-19 cases for the period 01/22/2020-02/25/2021 using an innovative generalized method of m...

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Main Author: Olusegun M. Otunuga
Format: Article
Language:English
Published: Elsevier 2021-09-01
Series:Results in Physics
Subjects:
Online Access:http://www.sciencedirect.com/science/article/pii/S221137972100749X
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spelling doaj-7220ee49d1604eab9a3f7caedc5820572021-08-28T04:44:16ZengElsevierResults in Physics2211-37972021-09-0128104664Estimation of epidemiological parameters for COVID-19 cases using a stochastic SEIRS epidemic model with vital dynamicsOlusegun M. Otunuga0Department of Mathematics, Augusta University, 1120 15th Street, GE-3018 Augusta, GA 30912, USAWe estimate and analyze the time-dependent parameters: transmission rate, symptomatic recovery rate, immunity rate, infection noise intensities, and the effective reproduction number for the United States COVID-19 cases for the period 01/22/2020-02/25/2021 using an innovative generalized method of moments estimation scheme. We assume the disease-dynamic is described by a stochastic susceptible–exposed–infected–recovered–susceptible (SEIRS) epidemic model, where the infected class is divided into the asymptomatic infected, and symptomatic infectious classes. Stochasticity appears in the model due to fluctuations in the disease’s transmission and recovery rates. The disease eradication threshold is derived from the reproduction number. The estimated parameters are used to model the disease outbreak’s possible trajectories. Our analysis reveals that current interventions are having positive effects on the transmission and recovery rates. The analysis is demonstrated using the daily United States COVID-19 infection and recovered cases for the period: 01/22/2020-02/25/2021.http://www.sciencedirect.com/science/article/pii/S221137972100749XCompartment disease modelStochastic disease modelLocal lagged adaptive generalized method of momentsCovid-19Reproduction numberDELPHI model
collection DOAJ
language English
format Article
sources DOAJ
author Olusegun M. Otunuga
spellingShingle Olusegun M. Otunuga
Estimation of epidemiological parameters for COVID-19 cases using a stochastic SEIRS epidemic model with vital dynamics
Results in Physics
Compartment disease model
Stochastic disease model
Local lagged adaptive generalized method of moments
Covid-19
Reproduction number
DELPHI model
author_facet Olusegun M. Otunuga
author_sort Olusegun M. Otunuga
title Estimation of epidemiological parameters for COVID-19 cases using a stochastic SEIRS epidemic model with vital dynamics
title_short Estimation of epidemiological parameters for COVID-19 cases using a stochastic SEIRS epidemic model with vital dynamics
title_full Estimation of epidemiological parameters for COVID-19 cases using a stochastic SEIRS epidemic model with vital dynamics
title_fullStr Estimation of epidemiological parameters for COVID-19 cases using a stochastic SEIRS epidemic model with vital dynamics
title_full_unstemmed Estimation of epidemiological parameters for COVID-19 cases using a stochastic SEIRS epidemic model with vital dynamics
title_sort estimation of epidemiological parameters for covid-19 cases using a stochastic seirs epidemic model with vital dynamics
publisher Elsevier
series Results in Physics
issn 2211-3797
publishDate 2021-09-01
description We estimate and analyze the time-dependent parameters: transmission rate, symptomatic recovery rate, immunity rate, infection noise intensities, and the effective reproduction number for the United States COVID-19 cases for the period 01/22/2020-02/25/2021 using an innovative generalized method of moments estimation scheme. We assume the disease-dynamic is described by a stochastic susceptible–exposed–infected–recovered–susceptible (SEIRS) epidemic model, where the infected class is divided into the asymptomatic infected, and symptomatic infectious classes. Stochasticity appears in the model due to fluctuations in the disease’s transmission and recovery rates. The disease eradication threshold is derived from the reproduction number. The estimated parameters are used to model the disease outbreak’s possible trajectories. Our analysis reveals that current interventions are having positive effects on the transmission and recovery rates. The analysis is demonstrated using the daily United States COVID-19 infection and recovered cases for the period: 01/22/2020-02/25/2021.
topic Compartment disease model
Stochastic disease model
Local lagged adaptive generalized method of moments
Covid-19
Reproduction number
DELPHI model
url http://www.sciencedirect.com/science/article/pii/S221137972100749X
work_keys_str_mv AT olusegunmotunuga estimationofepidemiologicalparametersforcovid19casesusingastochasticseirsepidemicmodelwithvitaldynamics
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