Estimates of Solutions for Integro-Differential Equations in Epidemiological Modeling

A. Domoshnitsky; I. Volinsky; S. Biton; V. Steindorf

doi:10.1002/mma.10900

Estimates of Solutions for Integro-Differential Equations in Epidemiological Modeling

A. Domoshnitsky, I. Volinsky, S. Biton, V. Steindorf

Department of Mathematics

Research output: Contribution to journal › Article › peer-review

Abstract

Integro-differential equations (IDE) have been applied in a variety of areas of research, including epidemiology. Recently, IDE systems were applied to study dengue fever transmission dynamics at the population level. In this study, we extend the approach presented in a previous study for describing the epidemiological model of dengue fever. In this paper, we find the exact solutions of the corresponding linearized system model by constructing the Cauchy and Green's matrices. Furthermore, we extend our investigation towards estimating the solutions of a closely related nonlinear system. Given that the coefficients of the model are only known approximately, we address the problem of the stability of a system with uncertain coefficients. Furthermore, we estimate the influence of errors in the coefficient determination on solution behavior.

Original language	English
Journal	Mathematical Methods in the Applied Sciences
DOIs	https://doi.org/10.1002/mma.10900
State	Accepted/In press - 2025

Keywords

Cauchy matrix
cross-protection
fundamental matrix
Green's matrix of periodic problem
integro-differential equations
stability

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10.1002/mma.10900

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title = "Estimates of Solutions for Integro-Differential Equations in Epidemiological Modeling",

abstract = "Integro-differential equations (IDE) have been applied in a variety of areas of research, including epidemiology. Recently, IDE systems were applied to study dengue fever transmission dynamics at the population level. In this study, we extend the approach presented in a previous study for describing the epidemiological model of dengue fever. In this paper, we find the exact solutions of the corresponding linearized system model by constructing the Cauchy and Green's matrices. Furthermore, we extend our investigation towards estimating the solutions of a closely related nonlinear system. Given that the coefficients of the model are only known approximately, we address the problem of the stability of a system with uncertain coefficients. Furthermore, we estimate the influence of errors in the coefficient determination on solution behavior.",

keywords = "Cauchy matrix, cross-protection, fundamental matrix, Green's matrix of periodic problem, integro-differential equations, stability",

author = "A. Domoshnitsky and I. Volinsky and S. Biton and V. Steindorf",

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year = "2025",

doi = "10.1002/mma.10900",

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T1 - Estimates of Solutions for Integro-Differential Equations in Epidemiological Modeling

AU - Domoshnitsky, A.

AU - Volinsky, I.

AU - Biton, S.

AU - Steindorf, V.

PY - 2025

Y1 - 2025

N2 - Integro-differential equations (IDE) have been applied in a variety of areas of research, including epidemiology. Recently, IDE systems were applied to study dengue fever transmission dynamics at the population level. In this study, we extend the approach presented in a previous study for describing the epidemiological model of dengue fever. In this paper, we find the exact solutions of the corresponding linearized system model by constructing the Cauchy and Green's matrices. Furthermore, we extend our investigation towards estimating the solutions of a closely related nonlinear system. Given that the coefficients of the model are only known approximately, we address the problem of the stability of a system with uncertain coefficients. Furthermore, we estimate the influence of errors in the coefficient determination on solution behavior.

AB - Integro-differential equations (IDE) have been applied in a variety of areas of research, including epidemiology. Recently, IDE systems were applied to study dengue fever transmission dynamics at the population level. In this study, we extend the approach presented in a previous study for describing the epidemiological model of dengue fever. In this paper, we find the exact solutions of the corresponding linearized system model by constructing the Cauchy and Green's matrices. Furthermore, we extend our investigation towards estimating the solutions of a closely related nonlinear system. Given that the coefficients of the model are only known approximately, we address the problem of the stability of a system with uncertain coefficients. Furthermore, we estimate the influence of errors in the coefficient determination on solution behavior.

KW - Cauchy matrix

KW - cross-protection

KW - fundamental matrix

KW - Green's matrix of periodic problem

KW - integro-differential equations

KW - stability

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Estimates of Solutions for Integro-Differential Equations in Epidemiological Modeling

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Keywords

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