English

Implicit Regularization in Matrix Sensing via Mirror Descent

Machine Learning 2021-10-28 v2 Machine Learning

Abstract

We study discrete-time mirror descent applied to the unregularized empirical risk in matrix sensing. In both the general case of rectangular matrices and the particular case of positive semidefinite matrices, a simple potential-based analysis in terms of the Bregman divergence allows us to establish convergence of mirror descent -- with different choices of the mirror maps -- to a matrix that, among all global minimizers of the empirical risk, minimizes a quantity explicitly related to the nuclear norm, the Frobenius norm, and the von Neumann entropy. In both cases, this characterization implies that mirror descent, a first-order algorithm minimizing the unregularized empirical risk, recovers low-rank matrices under the same set of assumptions that are sufficient to guarantee recovery for nuclear-norm minimization. When the sensing matrices are symmetric and commute, we show that gradient descent with full-rank factorized parametrization is a first-order approximation to mirror descent, in which case we obtain an explicit characterization of the implicit bias of gradient flow as a by-product.

Keywords

Cite

@article{arxiv.2105.13831,
  title  = {Implicit Regularization in Matrix Sensing via Mirror Descent},
  author = {Fan Wu and Patrick Rebeschini},
  journal= {arXiv preprint arXiv:2105.13831},
  year   = {2021}
}
R2 v1 2026-06-24T02:34:21.679Z