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Main Authors: López-de-la-Cruz, Javier, Oliveira-Sousa, Alexandre N.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2404.12776
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author López-de-la-Cruz, Javier
Oliveira-Sousa, Alexandre N.
author_facet López-de-la-Cruz, Javier
Oliveira-Sousa, Alexandre N.
contents We investigate SIR models with vital dynamics, reinfection, and randomness at the transmission coefficient and recruitment rate. Initially, we conduct an extensive analysis of the autonomous scenario, covering aspects such as local and global well-posedness, the existence and internal structure of attractors, and the presence of gradient dynamics. Subsequently, we explore the implications of small nonautonomous random perturbations, establishing the continuity of attractors and ensuring their topological structural stability. Additionally, we study scenarios in which both the transmission coefficient and the recruitment rate exhibit time-dependent or random behavior. For each scenario, we establish the existence of attractors and delineate conditions that determine whether the disease is eradicated or reaches an endemic state. Finally, we depict numerical simulations to illustrate the theoretical results.
format Preprint
id arxiv_https___arxiv_org_abs_2404_12776
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle SIR models with vital dynamics, reinfection and randomness to investigate the spread of infectious diseases
López-de-la-Cruz, Javier
Oliveira-Sousa, Alexandre N.
Dynamical Systems
We investigate SIR models with vital dynamics, reinfection, and randomness at the transmission coefficient and recruitment rate. Initially, we conduct an extensive analysis of the autonomous scenario, covering aspects such as local and global well-posedness, the existence and internal structure of attractors, and the presence of gradient dynamics. Subsequently, we explore the implications of small nonautonomous random perturbations, establishing the continuity of attractors and ensuring their topological structural stability. Additionally, we study scenarios in which both the transmission coefficient and the recruitment rate exhibit time-dependent or random behavior. For each scenario, we establish the existence of attractors and delineate conditions that determine whether the disease is eradicated or reaches an endemic state. Finally, we depict numerical simulations to illustrate the theoretical results.
title SIR models with vital dynamics, reinfection and randomness to investigate the spread of infectious diseases
topic Dynamical Systems
url https://arxiv.org/abs/2404.12776