Litcius/Paper detail

Multitype branching process method for modeling complex contagion on clustered networks

Leah A. Keating, James P. Gleeson, David J. P. O’Sullivan

2022Physical review. E21 citationsDOIOpen Access PDF

Abstract

Complex contagion adoption dynamics are characterized by a node being more likely to adopt after multiple network neighbors have adopted. We show how to construct multitype branching processes to approximate complex contagion adoption dynamics on networks with clique-based clustering. This involves tracking the evolution of a cascade via different classes of clique motifs that account for the different numbers of active, inactive, and removed nodes. This discrete-time model assumes that active nodes become immediately and certainly removed in the next time step. This description allows for extensive Monte Carlo simulations (which are faster than network-based simulations), accurate analytical calculation of cascade sizes, determination of critical behavior, and other quantities of interest.

Topics & Concepts

CascadeComputer scienceComplex networkMonte Carlo methodCliqueStatistical physicsBranching processCluster analysisConstruct (python library)Process (computing)Cluster (spacecraft)Branching (polymer chemistry)Node (physics)Cascading failureNetwork dynamicsTheoretical computer scienceMathematicsArtificial intelligencePhysicsEngineeringComputer networkCombinatoricsStatisticsPower (physics)Materials scienceQuantum mechanicsWorld Wide WebElectric power systemComposite materialChemical engineeringOperating systemComplex Network Analysis TechniquesOpinion Dynamics and Social InfluencePeer-to-Peer Network Technologies