We consider the problem of estimating overlapping community memberships. Existing provable algorithms for this problem either make strong assumptions about the population [33,16], or are too computationally expensive [3,15]. We work under the popular Mixed Membership Stochastic Blockmodel (MMSB) [2]. Using the inherent geometry of this model, we link the inference of overlapping communities to the problem of finding corners in a noisy rotated and scaled simplex, for which consistent algorithms exist [12]. We use this as a building block for our algorithm to infer the community memberships of each node. Furthermore, we prove that each node's soft membership vector converges to its population counterpart. To our knowledge, this is the first work to obtain rate of convergence for community membership vectors of each node, in contrast to previous work which obtain convergence results for memberships of all nodes as a whole. As a byproduct of our analysis, we derive sharp row-wise eigenvector deviation bounds, and provide a cleaning step that improves the performance significantly for sparse networks. We also propose both necessary and sufficient conditions for identifiability of the model, while existing methods typically present sufficient conditions. The empirical performance of our method is shown using simulated and real datasets scaling up to 100,000 nodes.
Identifiability:We present both necessary and sufficient conditions for identifiability of the MMSB model in Section 2. Specifically, if each of the K communities has at least one "pure" node, then a full-rank B is sufficient for identifiability. Surprisingly, even a B of rank K − 1 can be sufficient, as long as no row of B is an affine combination of the other rows of B. On the other hand, if the entries of ρB are strictly between 0 and 1, then pure nodes are necessary for identifiability. Our sufficient condition is more general than that in [33]. To our knowledge, we are the first to report both necessary and sufficient conditions for identifiability under the MMSB model.
Recovery algorithm:It is not hard to see that for the MMSB model, the population eigenvectors (i.e., eigenvectors of the matrix P) form a rotated and scaled simplex. We present an algorithm called SPACL, which re-purposes an existing algorithm [12] for detecting corners in a rotated and scaled simplex to find pure nodes, and then uses these to infer the parameters Θ and B. It also includes a novel preprocessing step that improves performance in sparse settings. The main compute-intensive parts of the algorithm are a) top-K eigen-decomposition of A, b) calculating k-nearest neighbors of a point for preprocessing. There are highly optimized algorithms and data structures for both of these steps [8,24,9].
