In this article, we consider the discretized classical Susceptible-Infected-Recovered (SIR) forced epidemic model to investigate the consequences of the introduction of different transmission rates and the effect of a constant vaccination strategy, providing new numerical and topological insights into the complex dynamics of recurrent diseases. Starting with a constant contact (or transmission) rate, the computation of the spectrum of Lyapunov exponents allows us to identify different chaotic regimes. Studying the evolution of the dynamical variables, a family of unimodal-type iterated maps with a striking biological meaning is detected among those dynamical regimes of the densities of the susceptibles. Using the theory of symbolic dynamics...
The impact of seasonal effects on the time course of an infectious disease can be dramatic. Seasonal...
In spite of their complex behaviour the dynamics of some ecological systems may be explained by dete...
Modeling insights for epidemiological scenarios characterized by chaotic dynamics have been largely ...
In this article, we consider the discretized classical Susceptible-Infected-Recovered (SIR) forced e...
In this article, we consider the discretized classical Susceptible-Infected-Recovered (SIR) forced e...
In this article, we consider the discretized classical Susceptible-Infected-Recovered (SIR) forced e...
Despite numerous studies of epidemiological systems, the role of seasonality in the recurrent epidem...
Despite numerous studies of epidemiological systems, the role of seasonality in the recurrent epide...
The study of epidemiological systems has generated deep interest in exploring the dynamical complexi...
The study of epidemiological systems has generated deep interest in exploring the dynamical complexi...
The study of epidemiological systems has generated deep interest in exploring the dynamical complexi...
BACKGROUND: Highly successful strategies to make populations more resilient to infectious diseases, ...
BACKGROUND: Highly successful strategies to make populations more resilient to infectious diseases, ...
Seasonality is a complex force in nature that affects multiple processes in wild animal populations....
The impact of seasonal effects on the time course of an infectious disease can be dramatic. Seasonal...
The impact of seasonal effects on the time course of an infectious disease can be dramatic. Seasonal...
In spite of their complex behaviour the dynamics of some ecological systems may be explained by dete...
Modeling insights for epidemiological scenarios characterized by chaotic dynamics have been largely ...
In this article, we consider the discretized classical Susceptible-Infected-Recovered (SIR) forced e...
In this article, we consider the discretized classical Susceptible-Infected-Recovered (SIR) forced e...
In this article, we consider the discretized classical Susceptible-Infected-Recovered (SIR) forced e...
Despite numerous studies of epidemiological systems, the role of seasonality in the recurrent epidem...
Despite numerous studies of epidemiological systems, the role of seasonality in the recurrent epide...
The study of epidemiological systems has generated deep interest in exploring the dynamical complexi...
The study of epidemiological systems has generated deep interest in exploring the dynamical complexi...
The study of epidemiological systems has generated deep interest in exploring the dynamical complexi...
BACKGROUND: Highly successful strategies to make populations more resilient to infectious diseases, ...
BACKGROUND: Highly successful strategies to make populations more resilient to infectious diseases, ...
Seasonality is a complex force in nature that affects multiple processes in wild animal populations....
The impact of seasonal effects on the time course of an infectious disease can be dramatic. Seasonal...
The impact of seasonal effects on the time course of an infectious disease can be dramatic. Seasonal...
In spite of their complex behaviour the dynamics of some ecological systems may be explained by dete...
Modeling insights for epidemiological scenarios characterized by chaotic dynamics have been largely ...