Core–periphery models for graphs based on their <i>δ</i>-hyperbolicity: An example using biological networks

Alrasheed, Hend; Dragan, Feodor F.

doi:10.1177/1748301816665519

Cited by 6 publications

(1 citation statement)

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“…It has been suggested in [77], and recently formally proved in [39], that the property, observed in real-world networks, in which traffic between nodes tends to go through a relatively small core of the network, as if the shortest paths between them are curved inwards, is due to the hyperbolicity of the network. Bending property of the eccentricity function in hyperbolic graphs were used in [16,15] to identify core-periphery structures in biological networks. Small hyperbolicity in real-world graphs provides also many algorithmic advantages.…”

Section: Introductionmentioning

confidence: 99%

Fast Approximation of Centrality and Distances in Hyperbolic Graphs

Chepoi¹,

Dragan²,

Habib³

et al. 2018

Combinatorial Optimization and Applications

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We show that the eccentricities (and thus the centrality indices) of all vertices of a δhyperbolic graph G = (V, E) can be computed in linear time with an additive one-sided error of at most cδ, i.e., after a linear time preprocessing, for every vertex v of G one can compute in O(1) time an estimateê(v) of its eccentricity eccG(v) such that eccG(v) ≤ê(v) ≤ eccG(v) + cδ for a small constant c. We prove that every δ-hyperbolic graph G has a shortest path tree, constructible in linear time, such that for every vertexThese results are based on an interesting monotonicity property of the eccentricity function of hyperbolic graphs: the closer a vertex is to the center of G, the smaller its eccentricity is. We also show that the distance matrix of G with an additive one-sided error of at most c ′ δ can be computed in O(|V | 2 log 2 |V |) time, where c ′ < c is a small constant. Recent empirical studies show that many real-world graphs (including Internet application networks, web networks, collaboration networks, social networks, biological networks, and others) have small hyperbolicity. So, we analyze the performance of our algorithms for approximating centrality and distance matrix on a number of real-world networks. Our experimental results show that the obtained estimates are even better than the theoretical bounds.

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Section: Introductionmentioning

confidence: 99%