Date of this Version
The Annals of Statistics
Community detection, which aims to cluster NN nodes in a given graph into rr distinct groups based on the observed undirected edges, is an important problem in network data analysis. In this paper, the popular stochastic block model (SBM) is extended to the generalized stochastic block model (GSBM) that allows for adversarial outlier nodes, which are connected with the other nodes in the graph in an arbitrary way. Under this model, we introduce a procedure using convex optimization followed by k-means algorithm with k=r. Both theoretical and numerical properties of the method are analyzed. A theoretical guarantee is given for the procedure to accurately detect the communities with small misclassification rate under the setting where the number of clusters can grow with N. This theoretical result admits to the best-known result in the literature of computationally feasible community detection in SBM without outliers. Numerical results show that our method is both computationally fast and robust to different kinds of outliers, while some popular computationally fast community detection algorithms, such as spectral clustering applied to adjacency matrices or graph Laplacians, may fail to retrieve the major clusters due to a small portion of outliers. We apply a slight modification of our method to a political blogs data set, showing that our method is competent in practice and comparable to existing computationally feasible methods in the literature. To the best of the authors’ knowledge, our result is the first in the literature in terms of clustering communities with fast growing numbers under the GSBM where a portion of arbitrary outlier nodes exist.
The original and published work is available at: https://projecteuclid.org/euclid.aos/1431695637#abstract
Robust community detection, SDP relaxation, dual certificate, k-means clustering
Cai, T., & Li, X. (2015). Robust and Computationally Feasible Community Detection in the Presence of Arbitrary Outlier Nodes. The Annals of Statistics, 43 (3), 1027-1059. http://dx.doi.org/10.1214/14-AOS1290
Date Posted: 27 November 2017
This document has been peer reviewed.