Multi-competitive time-varying networked SIS model with an infrastructure network

IF 1.8 Q3 AUTOMATION & CONTROL SYSTEMS IFAC Journal of Systems and Control Pub Date : 2024-03-01 DOI:10.1016/j.ifacsc.2024.100254
Sebin Gracy , José I. Caiza , Philip E. Paré , César A. Uribe
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Abstract

The paper studies the problem of the spread of multi-competitive viruses across a (time-varying) population network and an infrastructure network. To this end, we devise a variant of the classic (networked) susceptible–infected-susceptible (SIS) model called the multi-competitive time-varying networked susceptible-infected-water-susceptible (SIWS) model. We establish a sufficient condition for exponentially fast eradication of a virus when a) the graph structure does not change over time; b) the graph structure possibly changes with time, interactions between individuals are symmetric, and all individuals have the same healing and infection rate; and c) the graph is directed and is slowly-varying, and not all individuals necessarily have the same healing and infection rates. We also show that the aforementioned conditions for eradication of a virus are robust to variations in the graph structure of the population network provided the variations are not too large. For the case of time-invariant graphs, we give a lower bound on the number of equilibria that our system possesses. Finally, we provide an in-depth set of simulations that not only illustrate the theoretical findings of this paper but also provide insights into the endemic behavior for the case of time-varying graphs.

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具有基础设施网络的多竞争时变网络化 SIS 模型
本文研究了多重竞争性病毒在(时变)人口网络和基础设施网络中的传播问题。为此,我们设计了一个经典(网络化)易感-感染-易感(SIS)模型的变体,称为多竞争时变网络化易感-感染-水-易感(SIWS)模型。我们建立了以下情况下以指数级速度消灭病毒的充分条件:a) 图结构不随时间变化;b) 图结构可能随时间变化,个体间的相互作用是对称的,且所有个体具有相同的愈合率和感染率;c) 图是有向的,且缓慢变化,并非所有个体都一定具有相同的愈合率和感染率。我们还证明,上述根除病毒的条件对种群网络图结构的变化是稳健的,前提是变化不太大。对于时间不变图的情况,我们给出了我们的系统所拥有的均衡点数量的下限。最后,我们提供了一组深入的模拟,不仅说明了本文的理论发现,还为时变型图的流行行为提供了见解。
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来源期刊
IFAC Journal of Systems and Control
IFAC Journal of Systems and Control AUTOMATION & CONTROL SYSTEMS-
CiteScore
3.70
自引率
5.30%
发文量
17
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