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Multiscale network renormalization: Scale-invariance without geometry

Elena Garuccio, Margherita Lalli, Diego Garlaschelli

2023Physical Review Research12 citationsDOIOpen Access PDF

Abstract

Systems with lattice geometry can be renormalized exploiting their coordinates in metric space, which naturally define the coarse-grained nodes. By contrast, complex networks defy the usual techniques, due to their small-world character and lack of explicit geometric embedding. Current network renormalization approaches require strong assumptions (e.g., community structure, hyperbolicity, scale-free topology), thus remaining incompatible with generic graphs and ordinary lattices. Here we introduce a graph renormalization scheme valid for any hierarchy of heterogeneous coarse-grainings, thereby allowing for the definition of ``block-nodes'' across multiple scales. This approach identifies a class of scale-invariant networks characterized by a necessary and specific dependence on additive hidden variables attached to nodes, plus optional dyadic factors. If the hidden variables are annealed, they lead to realistic scale-free networks with assortativity and finite local clustering, even in the sparse regime and in the absence of geometry. If they are quenched, they can guide the renormalization of real-world networks with node attributes and distance-dependence or communities. As an application, we derive an accurate multiscale model of the International Trade Network applicable across arbitrary geographic partitions. These results highlight a deep conceptual distinction between scale-free and scale-invariant networks, and they provide a geometry-free route to renormalization.

Topics & Concepts

RenormalizationMathematicsEmbeddingScale invarianceScale-free networkLattice (music)Topology (electrical circuits)Invariant (physics)Statistical physicsComputer scienceComplex networkTheoretical computer sciencePhysicsCombinatoricsArtificial intelligenceMathematical physicsAcousticsStatisticsComplex Network Analysis TechniquesOpinion Dynamics and Social InfluenceTheoretical and Computational Physics
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