Transfinite fractal dimension of trees and hierarchical scale-free graphs. (English) Zbl 1469.05157
Summary: In this article, we introduce a new concept: the transfinite fractal dimension of graph sequences motivated by the notion of fractality of complex networks proposed by C. Song, S. Havlin and H. A. Makse [“Self-similarity of complex networks”, Preprint, arXiv:cond-mat/0503078]. We show that the definition of fractality cannot be applied to networks with ‘tree-like’ structure and exponential growth rate of neighbourhoods. However, we show that the definition of fractal dimension could be modified in a way that takes into account the exponential growth, and with the modified definition, the fractal dimension becomes a proper parameter of graph sequences. We find that this parameter is related to the growth rate of trees. We also generalize the concept of box dimension further and introduce the transfinite Cesaro fractal dimension. Using rigorous proofs, we determine the optimal box-covering and transfinite fractal dimension of various models: the hierarchical graph sequence model introduced by Komjáthy and Simon, Song-Havlin-Makse model, spherically symmetric trees and supercritical Galton-Watson trees.
MSC:
05C82 | Small world graphs, complex networks (graph-theoretic aspects) |
05C05 | Trees |
90B10 | Deterministic network models in operations research |
90B15 | Stochastic network models in operations research |
91D30 | Social networks; opinion dynamics |
60J80 | Branching processes (Galton-Watson, birth-and-death, etc.) |