Your search keyword '"Benjamin Ambrosio"' showing total 2 results

1. Non-Trivial Dynamics in the FizHugh–Rinzel Model and Non-Homogeneous Oscillatory-Excitable Reaction-Diffusions Systems

Author

Benjamin Ambrosio, M. A. Aziz-Alaoui, Argha Mondal, Arnab Mondal, Sanjeev K. Sharma, and Ranjit Kumar Upadhyay

Subjects

FitzHugh–Nagumo, FitzHugh–Rinzel model, fast-slow dynamics, bifurcation, canard, mixed mode oscillations, Biology (General), QH301-705.5

Abstract

This article focuses on the qualitative analysis of complex dynamics arising in a few mathematical models in neuroscience context. We first discuss the dynamics arising in the three-dimensional FitzHugh–Rinzel (FHR) model and then illustrate those arising in a class of non-homogeneous FitzHugh–Nagumo (Nh-FHN) reaction-diffusion systems. FHR and Nh-FHN models can be used to generate relevant complex dynamics and wave-propagation phenomena in neuroscience context. Such complex dynamics include canards, mixed-mode oscillations (MMOs), Hopf-bifurcations and their spatially extended counterpart. Our article highlights original methods to characterize these complex dynamics and how they emerge in ordinary differential equations and spatially extended models.

Published

2023

2. On a Coupled Time-Dependent SIR Models Fitting with New York and New-Jersey States COVID-19 Data

Author

Benjamin Ambrosio and M. A. Aziz-Alaoui

Subjects

COVID-19, New York, New Jersey, SIR models, Network, Biology (General), QH301-705.5

Abstract

This article describes a simple Susceptible Infected Recovered (SIR) model fitting with COVID-19 data for the month of March 2020 in New York (NY) state. The model is a classical SIR, but is non-autonomous; the rate of susceptible people becoming infected is adjusted over time in order to fit the available data. The death rate is also secondarily adjusted. Our fitting is made under the assumption that due to limiting number of tests, a large part of the infected population has not been tested positive. In the last part, we extend the model to take into account the daily fluxes between New Jersey (NJ) and NY states and fit the data for both states. Our simple model fits the available data, and illustrates typical dynamics of the disease: exponential increase, apex and decrease. The model highlights a decrease in the transmission rate over the period which gives a quantitative illustration about how lockdown policies reduce the spread of the pandemic. The coupled model with NY and NJ states shows a wave in NJ following the NY wave, illustrating the mechanism of spread from one attractive hot spot to its neighbor.

Published

2020