Two-Scale Network Epidemic Dynamic Model for Vector Borne Diseases

Divine Wanduku

Two-Scale Network Epidemic Dynamic Model for Vector Borne Diseases

Divine Wanduku

Mathematical Sciences

Research output: Contribution to book or proceeding › Chapter

Abstract

A SIRS delayed epidemic dynamic model for a vector-borne disease in a two-scale network structured dynamic population is presented. The distributed time delay represents the varying incubation period of the disease. The epidemic dynamic process is influenced by a two-scale network human mobility dynamic process. The global asymptotic stability results for the system and the significance of the results to the general disease dynamic process are presented. The results are exhibited in different special real life scenarios. The presented results are demonstrated by numerical simulation results

Original language	American English
Title of host publication	Proceedings of Dynamic Systems and Applications
State	Published - Jan 1 2016

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Disciplines

Education
Mathematics

Keywords

Disease
Two-scale network epidemic dynamic model
Vector borne diseases

Access to Document

https://www.researchgate.net/publication/305215722_Two-Scale_Network_Epidemic_Dynamic_Model_for_Vector_Borne_Diseases

Cite this

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title = "Two-Scale Network Epidemic Dynamic Model for Vector Borne Diseases",

abstract = " A SIRS delayed epidemic dynamic model for a vector-borne disease in a two-scale network structured dynamic population is presented. The distributed time delay represents the varying incubation period of the disease. The epidemic dynamic process is influenced by a two-scale network human mobility dynamic process. The global asymptotic stability results for the system and the significance of the results to the general disease dynamic process are presented. The results are exhibited in different special real life scenarios. The presented results are demonstrated by numerical simulation results",

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N2 - A SIRS delayed epidemic dynamic model for a vector-borne disease in a two-scale network structured dynamic population is presented. The distributed time delay represents the varying incubation period of the disease. The epidemic dynamic process is influenced by a two-scale network human mobility dynamic process. The global asymptotic stability results for the system and the significance of the results to the general disease dynamic process are presented. The results are exhibited in different special real life scenarios. The presented results are demonstrated by numerical simulation results

AB - A SIRS delayed epidemic dynamic model for a vector-borne disease in a two-scale network structured dynamic population is presented. The distributed time delay represents the varying incubation period of the disease. The epidemic dynamic process is influenced by a two-scale network human mobility dynamic process. The global asymptotic stability results for the system and the significance of the results to the general disease dynamic process are presented. The results are exhibited in different special real life scenarios. The presented results are demonstrated by numerical simulation results

KW - Disease

KW - Two-scale network epidemic dynamic model

KW - Vector borne diseases

UR - https://digitalcommons.georgiasouthern.edu/math-sci-facpubs/385

UR - https://www.researchgate.net/publication/305215722_Two-Scale_Network_Epidemic_Dynamic_Model_for_Vector_Borne_Diseases

M3 - Chapter

BT - Proceedings of Dynamic Systems and Applications

ER -

Two-Scale Network Epidemic Dynamic Model for Vector Borne Diseases

Abstract

UN SDGs

Disciplines

Keywords

Access to Document

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