Litcius/Paper detail

Two competing simplicial irreversible epidemics on simplicial complex

Wenjie Li, Yanyi Nie, Wenyao Li, Xiaolong Chen, Sheng Su, Wei Wang

2022Chaos An Interdisciplinary Journal of Nonlinear Science25 citationsDOI

Abstract

Higher-order interactions have significant implications for the dynamics of competing epidemic spreads. In this paper, a competing spread model for two simplicial irreversible epidemics (i.e., susceptible–infected–removed epidemics) on higher-order networks is proposed. The simplicial complexes are based on synthetic (including homogeneous and heterogeneous) and real-world networks. The spread process of two epidemics is theoretically analyzed by extending the microscopic Markov chain approach. When the two epidemics have the same 2-simplex infection rate and the 1-simplex infection rate of epidemic A (λA) is fixed at zero, an increase in the 1-simplex infection rate of epidemic B (λB) causes a transition from continuous growth to sharp growth in the spread of epidemic B with λB. When λA>0, the growth of epidemic B is always continuous. With the increase of λA, the outbreak threshold of epidemic B is delayed. When the difference in 1-simplex infection rates between the two epidemics reaches approximately three times, the stronger side obviously dominates. Otherwise, the coexistence of the two epidemics is always observed. When the 1-simplex infection rates are symmetrical, the increase in competition will accelerate the spread process and expand the spread area of both epidemics; when the 1-simplex infection rates are asymmetrical, the spread area of one epidemic increases with an increase in the 1-simplex infection rate from this epidemic while the other decreases. Finally, the influence of 2-simplex infection rates on the competing spread is discussed. An increase in 2-simplex infection rates leads to sharp growth in one of the epidemics.

Topics & Concepts

Simplicial complexSimplicial homologyAbstract simplicial complexSimplicial approximation theoremSimplicial manifoldBiologyEvolutionary biologyMathematicsSimplicial setCombinatoricsPure mathematicsHomotopyHomotopy categoryComplex Network Analysis TechniquesTopological and Geometric Data AnalysisMental Health Research Topics