Luca Meacci, Francisco J. Muñoz, Juan Carlos Nuño, Mario Primicerio
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引用次数: 0
Abstract
This paper investigates the impact of spatial factors on epidemic dynamics using a two-stage contagion model with two possible outcomes, whose probability of occurrence depends of a parameter \(q \in [0,1]\). The model considers direct contagion (\(q=1\)), where contact with an ill individual causes a susceptible individual to become infected, and indirect contagion (\(q=0\)), where a susceptible individual, in contact with an infected individual, does not become ill but, enters an exposed intermediate stage, weakening their resistance to the disease. To incorporate spatial effects, we first define a rigorous integro-differential model expressed in terms of the densities of each class into which the population can be divided. The time evolution of these variables is determined by integrals that account for the range of influence of the contagion over the susceptible classes. Under certain conditions, this integro-differential system can be reduced to a system of ordinary differential equations for the average population in each class. Nonetheless, even for low-dimensional cases, the solution to this extended system appears to evade analytical methods. Alternatively, we represent the population using a cellular automata model on a two-dimensional square grid. We demonstrate that the outcome is influenced by the neighborhood size r; in the limit of large r, the model converges to the mean field approximation, where interactions follow a law of mass action. We specifically explore the impact of the initial spatial configuration on the population’s asymptotic behavior, highlighting its significance in cases of local bistability. Additionally, we establish that oscillatory spatial behavior can emerge when considering a recovered or death class. These findings lay the groundwork for future studies on multi-stage contagion in complex networks.
本文使用一个具有两种可能结果的两阶段传染模型来研究空间因素对流行病动态的影响,其发生概率取决于一个参数(q 在 [0,1]\ 中)。该模型考虑了直接传染((q=1))和间接传染((q=0)),前者是指与患病个体接触会导致易感个体被感染,后者是指易感个体与被感染个体接触后不会患病,但会进入一个暴露的中间阶段,从而削弱其对疾病的抵抗力。为了纳入空间效应,我们首先定义了一个严格的积分微分模型,该模型以人口可分为的每个类别的密度表示。这些变量的时间演变由积分决定,积分考虑了传染病对易感人群的影响范围。在某些条件下,这个积分微分方程系统可以简化为每个类别平均人口的常微分方程系统。然而,即使在低维情况下,这个扩展系统的解似乎也无法用分析方法来解决。另外,我们在二维正方形网格上使用细胞自动机模型表示种群。我们证明,结果会受到邻域大小 r 的影响;在 r 较大的情况下,模型会趋近于平均场近似,即相互作用遵循质量作用定律。我们特别探讨了初始空间配置对种群渐近行为的影响,强调了其在局部双稳态情况下的重要性。此外,我们还发现,在考虑恢复或死亡类别时,会出现振荡空间行为。这些发现为今后研究复杂网络中的多阶段传染奠定了基础。
期刊介绍:
“Ricerche di Matematica” publishes high-quality research articles in any field of pure and applied mathematics. Articles must be original and written in English. Details about article submission can be found online.