English

Convergence of Gradient Descent with Small Initialization for Unregularized Matrix Completion

Machine Learning 2024-02-13 v1 Optimization and Control Machine Learning

Abstract

We study the problem of symmetric matrix completion, where the goal is to reconstruct a positive semidefinite matrix XRd×d\rm{X}^\star \in \mathbb{R}^{d\times d} of rank-rr, parameterized by UU\rm{U}\rm{U}^{\top}, from only a subset of its observed entries. We show that the vanilla gradient descent (GD) with small initialization provably converges to the ground truth X\rm{X}^\star without requiring any explicit regularization. This convergence result holds true even in the over-parameterized scenario, where the true rank rr is unknown and conservatively over-estimated by a search rank rrr'\gg r. The existing results for this problem either require explicit regularization, a sufficiently accurate initial point, or exact knowledge of the true rank rr. In the over-parameterized regime where rrr'\geq r, we show that, with Ω~(dr9)\widetilde\Omega(dr^9) observations, GD with an initial point U0ϵ\|\rm{U}_0\| \leq \epsilon converges near-linearly to an ϵ\epsilon-neighborhood of X\rm{X}^\star. Consequently, smaller initial points result in increasingly accurate solutions. Surprisingly, neither the convergence rate nor the final accuracy depends on the over-parameterized search rank rr', and they are only governed by the true rank rr. In the exactly-parameterized regime where r=rr'=r, we further enhance this result by proving that GD converges at a faster rate to achieve an arbitrarily small accuracy ϵ>0\epsilon>0, provided the initial point satisfies U0=O(1/d)\|\rm{U}_0\| = O(1/d). At the crux of our method lies a novel weakly-coupled leave-one-out analysis, which allows us to establish the global convergence of GD, extending beyond what was previously possible using the classical leave-one-out analysis.

Keywords

Cite

@article{arxiv.2402.06756,
  title  = {Convergence of Gradient Descent with Small Initialization for Unregularized Matrix Completion},
  author = {Jianhao Ma and Salar Fattahi},
  journal= {arXiv preprint arXiv:2402.06756},
  year   = {2024}
}
R2 v1 2026-06-28T14:44:36.144Z