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Network bypasses sustain complexity

Ernesto Estrada, Jesús Gómez‐Gardeñes, Lucas Lacasa

2023Proceedings of the National Academy of Sciences12 citationsDOIOpen Access PDF

Abstract

Real-world networks are neither regular nor random, a fact elegantly explained by mechanisms such as the Watts-Strogatz or the Barabási-Albert models, among others. Both mechanisms naturally create shortcuts and hubs, which while enhancing the network's connectivity, also might yield several undesired navigational effects: They tend to be overused during geodesic navigational processes-making the networks fragile-and provide suboptimal routes for diffusive-like navigation. Why, then, networks with complex topologies are ubiquitous? Here, we unveil that these models also entropically generate network bypasses: alternative routes to shortest paths which are topologically longer but easier to navigate. We develop a mathematical theory that elucidates the emergence and consolidation of network bypasses and measure their navigability gain. We apply our theory to a wide range of real-world networks and find that they sustain complexity by different amounts of network bypasses. At the top of this complexity ranking we found the human brain, which points out the importance of these results to understand the plasticity of complex systems.

Topics & Concepts

NavigabilityComputer scienceNetwork topologyComplex networkGeodesicTheoretical computer scienceRanking (information retrieval)Complex systemNetwork theoryArtificial intelligenceRange (aeronautics)MathematicsComputer networkWorld Wide WebCartographyMaterials scienceComposite materialGeographyStatisticsMathematical analysisComplex Network Analysis TechniquesNeural dynamics and brain functionTopological and Geometric Data Analysis
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