Mathematical analysis of the transmission dynamics of viral infection with effective control policies via fractional derivative

It is well known that viral infections have a high impact on public health in multiple ways, including disease burden, outbreaks and pandemic, economic consequences, emergency response, strain on healthcare systems, psychological and social effects, and the importance of vaccination. Mathematical mo...

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Main Authors: Jan R., Razak N.N.A., Boulaaras S., Rehman Z.U., Bahramand S.
Other Authors: 57205596279
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Published: Walter de Gruyter GmbH 2024
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spelling my.uniten.dspace-344722024-10-14T11:20:01Z Mathematical analysis of the transmission dynamics of viral infection with effective control policies via fractional derivative Jan R. Razak N.N.A. Boulaaras S. Rehman Z.U. Bahramand S. 57205596279 37059587300 36994353700 58095489000 58725436500 differential equations dynamical behavior mathematical operators public health policies stability analysis viral dynamics Differential equations Disease control Dynamics Economic and social effects Fixed point arithmetic Mathematical operators Viruses Control policy Dynamical behaviors Fractional derivatives Input parameter Mathematical analysis Public health policies Stability analyze Transmission dynamics Viral dynamic Viral infections COVID-19 It is well known that viral infections have a high impact on public health in multiple ways, including disease burden, outbreaks and pandemic, economic consequences, emergency response, strain on healthcare systems, psychological and social effects, and the importance of vaccination. Mathematical models of viral infections help policymakers and researchers to understand how diseases can spread, predict the potential impact of interventions, and make informed decisions to control and manage outbreaks. In this work, we formulate a mathematical model for the transmission dynamics of COVID-19 in the framework of a fractional derivative. For the analysis of the recommended model, the fundamental concepts and results are presented. For the validity of the model, we have proven that the solutions of the recommended model are positive and bounded. The qualitative and quantitative analyses of the proposed dynamics have been carried out in this research work. To ensure the existence and uniqueness of the proposed COVID-19 dynamics, we employ fixed-point theorems such as Schaefer and Banach. In addition to this, we establish stability results for the system of COVID-19 infection through mathematical skills. To assess the influence of input parameters on the proposed dynamics of the infection, we analyzed the solution pathways using the Laplace Adomian decomposition approach. Moreover, we performed different simulations to conceptualize the role of input parameters on the dynamics of the infection. These simulations provide visualizations of key factors and aid public health officials in implementing effective measures to control the spread of the virus. � 2023 the author(s), published by De Gruyter. Final 2024-10-14T03:20:01Z 2024-10-14T03:20:01Z 2023 Article 10.1515/nleng-2022-0342 2-s2.0-85178063048 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85178063048&doi=10.1515%2fnleng-2022-0342&partnerID=40&md5=a48b54fb310f88f82dcafeb87d756833 https://irepository.uniten.edu.my/handle/123456789/34472 12 1 20220342 All Open Access Gold Open Access Walter de Gruyter GmbH Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic differential equations
dynamical behavior
mathematical operators
public health policies
stability analysis
viral dynamics
Differential equations
Disease control
Dynamics
Economic and social effects
Fixed point arithmetic
Mathematical operators
Viruses
Control policy
Dynamical behaviors
Fractional derivatives
Input parameter
Mathematical analysis
Public health policies
Stability analyze
Transmission dynamics
Viral dynamic
Viral infections
COVID-19
spellingShingle differential equations
dynamical behavior
mathematical operators
public health policies
stability analysis
viral dynamics
Differential equations
Disease control
Dynamics
Economic and social effects
Fixed point arithmetic
Mathematical operators
Viruses
Control policy
Dynamical behaviors
Fractional derivatives
Input parameter
Mathematical analysis
Public health policies
Stability analyze
Transmission dynamics
Viral dynamic
Viral infections
COVID-19
Jan R.
Razak N.N.A.
Boulaaras S.
Rehman Z.U.
Bahramand S.
Mathematical analysis of the transmission dynamics of viral infection with effective control policies via fractional derivative
description It is well known that viral infections have a high impact on public health in multiple ways, including disease burden, outbreaks and pandemic, economic consequences, emergency response, strain on healthcare systems, psychological and social effects, and the importance of vaccination. Mathematical models of viral infections help policymakers and researchers to understand how diseases can spread, predict the potential impact of interventions, and make informed decisions to control and manage outbreaks. In this work, we formulate a mathematical model for the transmission dynamics of COVID-19 in the framework of a fractional derivative. For the analysis of the recommended model, the fundamental concepts and results are presented. For the validity of the model, we have proven that the solutions of the recommended model are positive and bounded. The qualitative and quantitative analyses of the proposed dynamics have been carried out in this research work. To ensure the existence and uniqueness of the proposed COVID-19 dynamics, we employ fixed-point theorems such as Schaefer and Banach. In addition to this, we establish stability results for the system of COVID-19 infection through mathematical skills. To assess the influence of input parameters on the proposed dynamics of the infection, we analyzed the solution pathways using the Laplace Adomian decomposition approach. Moreover, we performed different simulations to conceptualize the role of input parameters on the dynamics of the infection. These simulations provide visualizations of key factors and aid public health officials in implementing effective measures to control the spread of the virus. � 2023 the author(s), published by De Gruyter.
author2 57205596279
author_facet 57205596279
Jan R.
Razak N.N.A.
Boulaaras S.
Rehman Z.U.
Bahramand S.
format Article
author Jan R.
Razak N.N.A.
Boulaaras S.
Rehman Z.U.
Bahramand S.
author_sort Jan R.
title Mathematical analysis of the transmission dynamics of viral infection with effective control policies via fractional derivative
title_short Mathematical analysis of the transmission dynamics of viral infection with effective control policies via fractional derivative
title_full Mathematical analysis of the transmission dynamics of viral infection with effective control policies via fractional derivative
title_fullStr Mathematical analysis of the transmission dynamics of viral infection with effective control policies via fractional derivative
title_full_unstemmed Mathematical analysis of the transmission dynamics of viral infection with effective control policies via fractional derivative
title_sort mathematical analysis of the transmission dynamics of viral infection with effective control policies via fractional derivative
publisher Walter de Gruyter GmbH
publishDate 2024
_version_ 1814061058431647744
score 13.222552