Information-theoretic thresholds for community detection in sparse networks
Abstract
We give upper and lower bounds on the information-theoretic threshold for community detection in the stochastic block model. Specifically, let be the number of groups, be the average degree, the probability of edges between vertices within and between groups be and respectively, and let . We show that, when is large, and , the critical value of at which community detection becomes possible -- in physical terms, the condensation threshold -- is with tighter results in certain regimes. Above this threshold, we show that the only partitions of the nodes into groups are correlated with the ground truth, giving an exponential-time algorithm that performs better than chance -- in particular, detection is possible for in the disassortative case and for in the assortative case . (Similar upper bounds were obtained independently by Abbe and Sandon.) Below this threshold, we use recent results of Neeman and Netrapalli (who generalized arguments of Mossel, Neeman, and Sly) to show that no algorithm can label the vertices better than chance, or even distinguish the block model from an Erd\H{o}s-R\'enyi random graph with high probability. We also rely on bounds on certain functions of doubly stochastic matrices due to Achlioptas and Naor; indeed, our lower bound on is the second moment lower bound on the -colorability threshold for random graphs with a certain effective degree.
Keywords
Cite
@article{arxiv.1601.02658,
title = {Information-theoretic thresholds for community detection in sparse networks},
author = {Jess Banks and Cristopher Moore},
journal= {arXiv preprint arXiv:1601.02658},
year = {2016}
}