Hidden Integrality and Semirandom Robustness of SDP Relaxation for Sub-Gaussian Mixture Model

Article; Early Access

Fei, Yingjie; Chen, Yudong

Cornell University; University of Wisconsin System; University of Wisconsin Madison

MATHEMATICS OF OPERATIONS RESEARCH

0364-765X

10.1287/moor.2021.1216

2022

We consider the problem of estimating the discrete clustering structures under the sub-Gaussian mixture model. Our main results establish a hidden integrality property of a semidefinite programming (SDP) relaxation for this problem: while the optimal solution to the SDP is not integer-valued in general, its estimation error can be upper bounded by that of an idealized integer program. The error of the integer program, and hence that of the SDP, are further shown to decay exponentially in the signal-to-noise ratio. In addition, we show that the SDP relaxation is robust under the semirandom setting in which an adversary can modify the data generated from the mixture model. In particular, we generalize the hidden integrality property to the semirandom model and thereby show that SDP achieves the optimal error bound in this setting. These results together highlight the global-to-local mechanism that drives the performance of the SDP relaxation. To the best of our knowledge, our result is the first exponentially decaying error bound for convex relaxations of mixture models. A corollary of our results shows that in certain regimes, the SDP solutions are in fact integral and exact. More generally, our results establish sufficient conditions for the SDP to correctly recover the cluster memberships of (1 - delta) fraction of the points for any delta is an element of (0,1). As a special case, we show that under the d-dimensional stochastic ball model, SDP achieves nontrivial (sometimes exact) recovery when the center separation is as small as root 1/d, which improves upon previous exact recovery results that require constant separation.