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Shortest-Path Percolation on Random Networks

Minsuk Kim, Filippo Radicchi

2024Physical Review Letters13 citationsDOIOpen Access PDF

Abstract

We propose a bond-percolation model intended to describe the consumption, and eventual exhaustion, of resources in transport networks. Edges forming minimum-length paths connecting demanded origin-destination nodes are removed if below a certain budget. As pairs of nodes are demanded and edges are removed, the macroscopic connected component of the graph disappears, i.e., the graph undergoes a percolation transition. Here, we study such a shortest-path-percolation transition in homogeneous random graphs where pairs of demanded origin-destination nodes are randomly generated, and fully characterize it by means of finite-size scaling analysis. If budget is finite, the transition is identical to the one of ordinary percolation, where a single giant cluster shrinks as edges are removed from the graph; for infinite budget, the transition becomes more abrupt than the one of ordinary percolation, being characterized by the sudden fragmentation of the giant connected component into a multitude of clusters of similar size.

Topics & Concepts

Giant componentScalingPercolation (cognitive psychology)Connected componentRandom graphPercolation critical exponentsShortest path problemPercolation thresholdMathematicsCombinatoricsContinuum percolation theoryGraphCluster (spacecraft)HomogeneousStatistical physicsComputer sciencePhysicsCritical exponentGeometryComputer networkElectrical resistivity and conductivityBiologyQuantum mechanicsNeuroscienceComplex Network Analysis TechniquesStochastic processes and statistical mechanicsTheoretical and Computational Physics
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