The diameter of KPKVB random graphs

Abstract We consider a random graph model that was recently proposed as a model for complex networks by Krioukov et al. (2010). In this model, nodes are chosen randomly inside a disk in the hyperbolic plane and two nodes are connected if they are at most a certain hyperbolic distance from each other. It has previously been shown that this model has various properties associated with complex networks, including a power-law degree distribution and a strictly positive clustering coefficient. The model is specified using three parameters: the number of nodes N, which we think of as going to infinity, and $\alpha, \nu > 0$, which we think of as constant. Roughly speaking, $\alpha$ controls the power-law exponent of the degree sequence and $\nu$ the average degree. Earlier work of Kiwi and Mitsche (2015) has shown that, when $\alpha \lt 1$ (which corresponds to the exponent of the power law degree sequence being $\lt 3$), the diameter of the largest component is asymptotically almost surely (a.a.s.) at most polylogarithmic in N. Friedrich and Krohmer (2015) showed it was a.a.s. $\Omega(\log N)$ and improved the exponent of the polynomial in $\log N$ in the upper bound. Here we show the maximum diameter over all components is a.a.s. $O(\log N),$ thus giving a bound that is tight up to a multiplicative constant.

[1]  Luca Gugelmann,et al.  Random Hyperbolic Graphs: Degree Sequence and Clustering - (Extended Abstract) , 2012, ICALP.

[2]  Nikolaos Fountoulakis,et al.  The probability of connectivity in a hyperbolic model of complex networks , 2016, Random Struct. Algorithms.

[3]  M. R. Leadbetter Poisson Processes , 2011, International Encyclopedia of Statistical Science.

[4]  Dieter Mitsche,et al.  A Bound for the Diameter of Random Hyperbolic Graphs , 2015, ANALCO.

[5]  Amin Vahdat,et al.  Hyperbolic Geometry of Complex Networks , 2010, Physical review. E, Statistical, nonlinear, and soft matter physics.

[6]  Tobias Friedrich,et al.  Hyperbolic Random Graphs: Separators and Treewidth , 2016, ESA.

[7]  Marián Boguñá,et al.  Sustaining the Internet with Hyperbolic Mapping , 2010, Nature communications.

[8]  Nikolaos Fountoulakis,et al.  Law of large numbers for the largest component in a hyperbolic model of complex networks , 2016 .

[9]  Tobias Friedrich,et al.  Efficient Embedding of Scale-Free Graphs in the Hyperbolic Plane , 2018, IEEE/ACM Transactions on Networking.

[10]  H. Kesten Percolation theory for mathematicians , 1982 .

[11]  Tobias Friedrich,et al.  Efficient Embedding of Scale-Free Graphs in the Hyperbolic Plane , 2018, IEEE/ACM Transactions on Networking.

[12]  Nikolaos Fountoulakis,et al.  On the Largest Component of a Hyperbolic Model of Complex Networks , 2015, Electron. J. Comb..

[13]  J. Stillwell Geometry of surfaces , 1992 .

[14]  W. Hager,et al.  and s , 2019, Shallow Water Hydraulics.

[15]  Marcos Kiwi,et al.  Spectral Gap of Random Hyperbolic Graphs and Related Parameters , 2016 .

[16]  Luca Gugelmann,et al.  Random Hyperbolic Graphs: Degree Sequence and Clustering , 2012, ArXiv.

[17]  R. Sarpong,et al.  Bio-inspired synthesis of xishacorenes A, B, and C, and a new congener from fuscol† †Electronic supplementary information (ESI) available. See DOI: 10.1039/c9sc02572c , 2019, Chemical science.

[18]  Tobias Friedrich,et al.  Cliques in hyperbolic random graphs , 2015, INFOCOM.

[19]  Tobias Friedrich,et al.  On the Diameter of Hyperbolic Random Graphs , 2015, ICALP.

[20]  Nikolaos Fountoulakis,et al.  Typical distances in a geometric model for complex networks , 2015, Internet Math..