A non-linear stochastic model is presented to study the effect of time variation of transmission rates on the co-evolution of epidemics and its corresponding awareness over a two layered multiplex network. In the model, the infection transmission rate of a given node in the epidemic layer depends upon its awareness probability in the awareness layer. Similarly, the infection information transmission rate of a node in the awareness layer depends upon its infection probability in the epidemic layer. The spread of disease resulting from physical contacts is described in terms of a Susceptible Infected Susceptible process over the epidemic layer and the spread of information about the disease outbreak is described in terms of an Unaware Aware Unaware process over the virtual interaction mediated awareness layer. The time variation of the transmission rates and the resulting co-evolution of these mutually competing processes are studied in terms of a network topology dependent parameter (alpha). Using a second order linear theory, it is shown that in the continuous time limit, the co-evolution of these processes can be described in terms of damped and driven harmonic oscillator equations. From the results of a Monte-Carlo simulation, it is shown that for a suitable choice of the parameter (alpha), the two processes can either exhibit sustained oscillatory or damped dynamics. The damped dynamics corresponds to the endemic state. Furthermore, for the case of an endemic state, it is shown that the inclusion of the awareness layer significantly lowers the disease transmission rate and reduces the size of the epidemic. The infection probability of the nodes in the endemic state is found to have a dependence on both the transmission rates and on their absolute degrees in each of the network layers and on the relative differences between their degrees in the respective layers. Published by AIP Publishing.
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机译:提出了一种非线性随机模型,研究了传输速率的时间变化对分层多路复用网络的共同演化及其相同的认识。在该模型中,疫情层中给定节点的感染传输速率取决于其认识层中的意识概率。类似地,感知层中节点的感染信息传输速率取决于其流行层中的感染概率。根据敏感的感染易感过程,在疫情层上描述了物理触点产生的疾病的传播,并且根据虚拟交互介导的意识层的不知道意识到不知道的未知过程描述了关于疾病爆发的信息的传播。在网络拓扑依赖性参数(alpha)方面,研究了传输速率的时间变化和这些相互竞争过程的所得到的共同演化。使用二阶线性理论,示出了在连续时间限制中,可以在阻尼和驱动的谐振子方程方面描述这些过程的共同演变。 From the results of a Monte-Carlo simulation, it is shown that for a suitable choice of the parameter (alpha), the two processes can either exhibit sustained oscillatory or damped dynamics.阻尼动力学对应于流行状态。此外,对于地方性状态的情况,表明包含意识层显着降低了疾病传输速率并减少了流行病的大小。发现在流行状态中的节点的感染概率对传输速率和在每个网络层中的每个网络层中的绝对度和它们之间的绝对度数以及它们在各个层中的相对差异上具有依赖性。通过AIP发布发布。
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