Mathematical Investigation for Two-Bacteria Competition in Presence of a Pathogen With Leachate Recirculation

We propose a mathematical model for the Zika virus (ZIKV) spread under the influence of a seasonal environment. The basic reproduction number R0 was calculated for both cases, the fixed and seasonal environment permitting the characterisation of the extinction and the persistence of the disease for both cases. We proved that the virus-free steady state is globally asymptotically stable if R0≤1, while the disease will be persist if R0>1. Finally, extensive numerical simulations are given to confirm the theoretical findings.

“…It can be easily shown that W 0 = {E 0 } . Applying LaSalle's invariance principle [33] (see [34] for other applications), we deduce that E 0 is GAS when R 0 ≤ 1.…”

Section: Global Properties Of Steady Statesmentioning

confidence: 92%

Mathematical Analysis for a Zika Virus Dynamics in a Seasonal Environment

Al Najim

2024

“…We apply the next-generation matrix method introduced by Diekmann [23,24] to calculate the basic reproduction number for our system (3.2). See [25][26][27][28][29][30] for other applications. Let us define the matrices F and V by…”

Section: Numerical Examplesmentioning

confidence: 99%

Impact of Infection on Honeybee Population Dynamics in a Seasonal Environment

El Hajji,

Alzahrani,

Mdimagh

2024

We studied a non-autonomous model for the spread of disease within a bee colony under the influence of seasonality where we consider time-dependent parameters to integrate the impact of the periodicity of weather on the Honeybee population dynamics. We proved that the system admits a unique bounded positive solution, and also a global attractor set. The basic reproduction number, R0, was defined as the spectral radius of a linear integral operator. We proved that the global dynamics is determined by this threshold parameter: If R0≤1, then the disease-free periodic solution is globally asymptotically stable, while if R0>1, then the disease persists. We confirmed the theoretical results trough an extensive numerical simulations.

“…The basic reproduction number was approximated by using the next generation matrix method [29][30][31]. See [2,[32][33][34][35][36] for other applications. Let us consider the matrices…”

Section: Numerical Simulationsmentioning

confidence: 99%

Mathematical Analysis for the Influence of Seasonality on Chikungunya Virus Dynamics

Almuashi

2024

In this article, we discuss a mathematical system modelling Chikungunya virus dynamics in a seasonal environment with general incidence rates. We establish the existence, uniqueness, positivity and boundedness of a periodic orbit. We show that the global dynamics is determined using the basic reproduction number denoted by R0 and calculated using the spectral radius of a linear integral operator. We show the global stability of the disease free periodic solution if R0<1 and we show also the persistence of the disease if R0>1 where the trajectories converge to a periodic orbit. Finally, we display some numerical examples confirming the theoretical findings.