English

The All-or-Nothing Phenomenon in Sparse Tensor PCA

Statistics Theory 2020-09-08 v2 Information Theory math.IT Statistics Theory

Abstract

We study the statistical problem of estimating a rank-one sparse tensor corrupted by additive Gaussian noise, a model also known as sparse tensor PCA. We show that for Bernoulli and Bernoulli-Rademacher distributed signals and \emph{for all} sparsity levels which are sublinear in the dimension of the signal, the sparse tensor PCA model exhibits a phase transition called the \emph{all-or-nothing phenomenon}. This is the property that for some signal-to-noise ratio (SNR) SNRc\mathrm{SNR_c} and any fixed ϵ>0\epsilon>0, if the SNR of the model is below (1ϵ)SNRc\left(1-\epsilon\right)\mathrm{SNR_c}, then it is impossible to achieve any arbitrarily small constant correlation with the hidden signal, while if the SNR is above (1+ϵ)SNRc\left(1+\epsilon \right)\mathrm{SNR_c}, then it is possible to achieve almost perfect correlation with the hidden signal. The all-or-nothing phenomenon was initially established in the context of sparse linear regression, and over the last year also in the context of sparse 2-tensor (matrix) PCA, Bernoulli group testing, and generalized linear models. Our results follow from a more general result showing that for any Gaussian additive model with a discrete uniform prior, the all-or-nothing phenomenon follows as a direct outcome of an appropriately defined "near-orthogonality" property of the support of the prior distribution.

Keywords

Cite

@article{arxiv.2007.11138,
  title  = {The All-or-Nothing Phenomenon in Sparse Tensor PCA},
  author = {Jonathan Niles-Weed and Ilias Zadik},
  journal= {arXiv preprint arXiv:2007.11138},
  year   = {2020}
}

Comments

Corrected a typo in the statement of Theorem 3

R2 v1 2026-06-23T17:18:06.415Z