English

A multiscale cavity method for sublinear-rank symmetric matrix factorization

Information Theory 2026-03-20 v3 Disordered Systems and Neural Networks Mathematical Physics math.IT math.MP Statistics Theory Statistics Theory

Abstract

We consider a statistical model for symmetric matrix factorization with additive Gaussian noise in the high-dimensional regime, where the rank of the signal matrix to infer MM scales with its size NN as M=o(lnN)M=\mathrm{o}(\sqrt{\ln N}). Allowing for an NN-dependent rank offers new challenges and requires new methods. Working in the Bayes-optimal setting, we show that whenever the signal has i.i.d. entries, the limiting mutual information between signal and data is given by a variational formula involving a rank-one replica symmetric potential. In other words, from the information-theoretic perspective, the case of a (slowly) growing rank is the same as when M=1M=1 (namely, the standard spiked Wigner model). The proof is primarily based on a novel multiscale cavity method allowing for growing rank along with some information-theoretic identities on worst noise for the vector Gaussian channel. We believe that the cavity method developed here will play a role in the analysis of a broader class of inference and spin models where the degrees of freedom are large arrays instead of vectors.

Keywords

Cite

@article{arxiv.2403.07189,
  title  = {A multiscale cavity method for sublinear-rank symmetric matrix factorization},
  author = {Jean Barbier and Justin Ko and Anas A. Rahman},
  journal= {arXiv preprint arXiv:2403.07189},
  year   = {2026}
}

Comments

65 pages. Filled out proof details, improved multiscale cavity method and its proof. Equation and theorem numbering made consistent with published version

R2 v1 2026-06-28T15:16:31.566Z