Abstract
Networks are useful representations for analyzing and modeling real-world complex systems. They are often both scale-free and dense: their degree distribution follows a power-law and their average degree grows over time. So far, it has been argued that producing such networks is difficult without externally imposing a suitable cutoff for the scale-free regime. Here, we propose a new growing network model that produces dense scale-free networks with dynamically generated cutoffs. The link formation rule is based on a weak form of preferential attachment depending only on order relations between the degrees of nodes. By this mechanism, our model yields scale-free networks whose scaling exponents can take arbitrary values greater than 1. In particular, the resulting networks are dense when scaling exponents are 2 or less. We analytically study network properties such as the degree distribution, the degree correlation function, and the local clustering coefficient. All analytical calculations are in good agreement with numerical simulations. These results show that both sparse and dense scale-free networks can emerge through the same self-organizing process.
Highlights
Complex systems in nature and society can be represented as networks[1,2,3]
A new node x is generated with virtual degree There are three nodes with degree greater than or equal to ddxx⁎⁎
The new node has enough time to examine the degree of all existing nodes before another new node is created, which is consistent with the time-scale separation between node addition and link formation
Summary
Networks are useful representations for analyzing and modeling real-world complex systems. The link formation rule is based on a weak form of preferential attachment depending only on order relations between the degrees of nodes By this mechanism, our model yields scale-free networks whose scaling exponents can take arbitrary values greater than 1. The new node has enough time to examine the degree of all existing nodes before another new node is created, which is consistent with the time-scale separation between node addition and link formation This assumption differs from that in conventional preferential attachment using the degree distribution[4] and that in copying models using local link information[11,22,23,24,25].
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