<?xml version="1.0" encoding="UTF-8"?>
<rdf:RDF xmlns="http://purl.org/rss/1.0/" xmlns:rdf="http://www.w3.org/1999/02/22-rdf-syntax-ns#" xmlns:dc="http://purl.org/dc/elements/1.1/">
<channel rdf:about="https://repository.auw.edu.bd/handle/123456789/3363">
<title>2026</title>
<link>https://repository.auw.edu.bd/handle/123456789/3363</link>
<description/>
<items>
<rdf:Seq>
<rdf:li rdf:resource="https://repository.auw.edu.bd/handle/123456789/3364"/>
</rdf:Seq>
</items>
<dc:date>2026-07-14T16:03:07Z</dc:date>
</channel>
<item rdf:about="https://repository.auw.edu.bd/handle/123456789/3364">
<title>Stochastic Control of Influenza Spread: A Lévy-Driven SDE and Branching Process Approach</title>
<link>https://repository.auw.edu.bd/handle/123456789/3364</link>
<description>Stochastic Control of Influenza Spread: A Lévy-Driven SDE and Branching Process Approach
Mohammad, Kazi Mehedi; Khan, Taufiquar; Kamrujjaman, Md.
Background&#13;
Forecasting influenza outbreaks remains a significant challenge due to the complexity of dis&#13;
ease transmission and the influence of environmental and behavioral factors. Traditional&#13;
models based solely on the basic reproduction number (R0) often fall short in capturing the&#13;
full scope of outbreak dynamics.&#13;
Methods&#13;
In this study, we employ a seasonally adjusted SEIRT model incorporating stochastic differ&#13;
ential equations (SDEs), including Brownian motion and L´evy jump processes, to simulate&#13;
random and abrupt fluctuations in transmission. A branching process approximation is used&#13;
to evaluate the probability of an epidemic under the influence of seasonal variability and&#13;
stochastic perturbations. The model is calibrated using weekly influenza case data from&#13;
Mexico, with noise components estimated from publicly available CDC [1] and WHO [2]&#13;
surveillance data.&#13;
Results&#13;
Simulation results show that the inclusion of stochastic effects and periodic transmission&#13;
rates significantly enhances the model’s accuracy in reflecting real-world epidemic dynamics.&#13;
Numerical comparisons between deterministic, Brownian-based, and L´evy-based scenarios&#13;
reveal that both the initial state of the exposed or infectious subpopulation and the seasonal&#13;
transmission patterns are critical to determining outbreak probabilities. Results indicate that&#13;
seasonal transmission rates and stochastic effects significantly alter epidemic probabilities,&#13;
with L´evy processes capturing abrupt outbreak dynamics more accurately than deterministic&#13;
models.&#13;
Conclusions&#13;
The findings underscore that deterministic models may underestimate epidemic risk when&#13;
they overlook random and sudden changes in contact rates or disease introduction. The&#13;
proposed stochastic modeling framework yields a deeper understanding of influenza transmis&#13;
sion dynamics by incorporating uncertainty and seasonal variability, thereby supporting more&#13;
informed and effective public health decision-making.
</description>
<dc:date>2026-01-13T00:00:00Z</dc:date>
</item>
</rdf:RDF>
