Modeling and analysis of a fractional order spatio-temporal SEIR model: Stability and prediction

Q3 Mathematics Results in Control and Optimization Pub Date : 2024-05-10 DOI:10.1016/j.rico.2024.100433

El Mehdi Moumine , Sofiane Khassal , Omar Balatif , Mostafa Rachik

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Abstract

This study introduces a novel fractional-order spatio-temporal SEIR model for epidemic modeling, providing an advanced approach to understanding disease dynamics. Our model, categorizing the population into Susceptible (S), Exposed (E), Infected (I), and Recovered (R), incorporates fractional calculus to accurately reflect the complex, non-linear nature of infectious diseases. Key findings include the confirmation of the existence and uniqueness of the model’s solutions, ensuring reliability for epidemiological predictions. Through rigorous stability analysis at both disease-free and endemic equilibrium points, we identified critical parameters influencing epidemic outcomes. Numerical simulations reveal that the fractional order significantly impacts disease progression, offering valuable insights for intervention strategies.

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分数阶时空 SEIR 模型的建模与分析：稳定性和预测

本研究介绍了一种用于流行病建模的新型分数阶时空 SEIR 模型，为了解疾病动态提供了一种先进的方法。我们的模型将人群分为易感人群（S）、暴露人群（E）、感染人群（I）和康复人群（R），并结合了分数微积分，以准确反映传染病复杂的非线性性质。主要发现包括确认了模型解的存在性和唯一性，确保了流行病学预测的可靠性。通过对无疾病平衡点和流行平衡点进行严格的稳定性分析，我们确定了影响流行病结果的关键参数。数值模拟揭示了分数阶数对疾病进展的重大影响，为干预策略提供了宝贵的见解。

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