Approximating Solution of Fabrizio-Caputo Volterra’s Model for Population Growth in a Closed System by Homotopy Analysis Method

Approximating Solution of Fabrizio-Caputo Volterra’s Model for Population Growth in a Closed System by Homotopy Analysis Method

Volterra’s model for population growth in a closed system consists in an integral term to indicate accumulated toxicity besides the usual terms of the logistic equation. Scudo in 1971 suggested the Volterra model for a population u(t) of identical individuals to show crowding and sensitivity to “tot...

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Main Authors: Tahereh Bashiri, S. Mansour Vaezpour, Juan J. Nieto
Format: Article
Language:English
Published: Hindawi Limited 2018-01-01
Series:Journal of Function Spaces
Online Access:http://dx.doi.org/10.1155/2018/3152502
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spelling doaj-f0338ae14bbe49578273c759300cccde2020-11-24T22:24:26ZengHindawi LimitedJournal of Function Spaces2314-88962314-88882018-01-01201810.1155/2018/31525023152502Approximating Solution of Fabrizio-Caputo Volterra’s Model for Population Growth in a Closed System by Homotopy Analysis MethodTahereh Bashiri0S. Mansour Vaezpour1Juan J. Nieto2Department of Mathematics and Computer Science, Amirkabir University of Technology, 424 Hafez Ave, Tehran, IranDepartment of Mathematics and Computer Science, Amirkabir University of Technology, 424 Hafez Ave, Tehran, IranInstituto de Matemáticas, Universidade de Santiago de Compostela, 15782 Santiago de Compostela, SpainVolterra’s model for population growth in a closed system consists in an integral term to indicate accumulated toxicity besides the usual terms of the logistic equation. Scudo in 1971 suggested the Volterra model for a population u(t) of identical individuals to show crowding and sensitivity to “total metabolism”: du/dt=au(t)-bu2(t)-cu(t)∫0tu(s)ds. In this paper our target is studying the existence and uniqueness as well as approximating the following Caputo-Fabrizio Volterra’s model for population growth in a closed system:  CFDαu(t)=au(t)-bu2(t)-cu(t)∫0tu(s)ds, α∈[0,1], subject to the initial condition u(0)=0. The mechanism for approximating the solution is Homotopy Analysis Method which is a semianalytical technique to solve nonlinear ordinary and partial differential equations. Furthermore, we use the same method to analyze a similar closed system by considering classical Caputo’s fractional derivative. Comparison between the results for these two factional derivatives is also included.http://dx.doi.org/10.1155/2018/3152502
collection DOAJ
language English
format Article
sources DOAJ
author Tahereh Bashiri
S. Mansour Vaezpour
Juan J. Nieto
spellingShingle Tahereh Bashiri
S. Mansour Vaezpour
Juan J. Nieto
Approximating Solution of Fabrizio-Caputo Volterra’s Model for Population Growth in a Closed System by Homotopy Analysis Method
Journal of Function Spaces
author_facet Tahereh Bashiri
S. Mansour Vaezpour
Juan J. Nieto
author_sort Tahereh Bashiri
title Approximating Solution of Fabrizio-Caputo Volterra’s Model for Population Growth in a Closed System by Homotopy Analysis Method
title_short Approximating Solution of Fabrizio-Caputo Volterra’s Model for Population Growth in a Closed System by Homotopy Analysis Method
title_full Approximating Solution of Fabrizio-Caputo Volterra’s Model for Population Growth in a Closed System by Homotopy Analysis Method
title_fullStr Approximating Solution of Fabrizio-Caputo Volterra’s Model for Population Growth in a Closed System by Homotopy Analysis Method
title_full_unstemmed Approximating Solution of Fabrizio-Caputo Volterra’s Model for Population Growth in a Closed System by Homotopy Analysis Method
title_sort approximating solution of fabrizio-caputo volterra’s model for population growth in a closed system by homotopy analysis method
publisher Hindawi Limited
series Journal of Function Spaces
issn 2314-8896
2314-8888
publishDate 2018-01-01
description Volterra’s model for population growth in a closed system consists in an integral term to indicate accumulated toxicity besides the usual terms of the logistic equation. Scudo in 1971 suggested the Volterra model for a population u(t) of identical individuals to show crowding and sensitivity to “total metabolism”: du/dt=au(t)-bu2(t)-cu(t)∫0tu(s)ds. In this paper our target is studying the existence and uniqueness as well as approximating the following Caputo-Fabrizio Volterra’s model for population growth in a closed system:  CFDαu(t)=au(t)-bu2(t)-cu(t)∫0tu(s)ds, α∈[0,1], subject to the initial condition u(0)=0. The mechanism for approximating the solution is Homotopy Analysis Method which is a semianalytical technique to solve nonlinear ordinary and partial differential equations. Furthermore, we use the same method to analyze a similar closed system by considering classical Caputo’s fractional derivative. Comparison between the results for these two factional derivatives is also included.
url http://dx.doi.org/10.1155/2018/3152502
work_keys_str_mv AT taherehbashiri approximatingsolutionoffabriziocaputovolterrasmodelforpopulationgrowthinaclosedsystembyhomotopyanalysismethod
AT smansourvaezpour approximatingsolutionoffabriziocaputovolterrasmodelforpopulationgrowthinaclosedsystembyhomotopyanalysismethod
AT juanjnieto approximatingsolutionoffabriziocaputovolterrasmodelforpopulationgrowthinaclosedsystembyhomotopyanalysismethod
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