On the limitation of spectral methods: From the Gaussian hidden clique problem to rank one perturbations of Gaussian tensors

Abstract

We consider the following detection problem: given a realization of a symmetric matrix X of dimension n, distinguish between the hypothesis that all upper triangular variables are i.i.d. Gaussians variables with mean 0 and variance 1 and the hypothesis where X is the sum of such matrix and an independent rank-one perturbation. This setup applies to the situation where under the alternative, there is a planted principal submatrix B of size L for which all upper triangular variables are i.i.d. Gaussians with mean 1 and variance 1, whereas all other upper triangular elements of X not in B are i.i.d. Gaussians variables with mean 0 and variance 1. We refer to this as the `Gaussian hidden clique problem.' When L=(1+ε)n (ε>0), it is possible to solve this detection problem with probability 1-on(1) by computing the spectrum of X and considering the largest eigenvalue of X. We prove that this condition is tight in the following sense: when L<(1-ε)n no algorithm that examines only the eigenvalues of X can detect the existence of a hidden Gaussian clique, with error probability vanishing as n∞. We prove this result as an immediate consequence of a more general result on rank-one perturbations of k-dimensional Gaussian tensors. In this context we establish a lower bound on the critical signal-to-noise ratio below which a rank-one signal cannot be detected.