English

Beyond Alternating Updates for Matrix Factorization with Inertial Bregman Proximal Gradient Algorithms

Optimization and Control 2019-12-09 v2 Computer Vision and Pattern Recognition Information Retrieval Machine Learning

Abstract

Matrix Factorization is a popular non-convex optimization problem, for which alternating minimization schemes are mostly used. They usually suffer from the major drawback that the solution is biased towards one of the optimization variables. A remedy is non-alternating schemes. However, due to a lack of Lipschitz continuity of the gradient in matrix factorization problems, convergence cannot be guaranteed. A recently developed approach relies on the concept of Bregman distances, which generalizes the standard Euclidean distance. We exploit this theory by proposing a novel Bregman distance for matrix factorization problems, which, at the same time, allows for simple/closed form update steps. Therefore, for non-alternating schemes, such as the recently introduced Bregman Proximal Gradient (BPG) method and an inertial variant Convex--Concave Inertial BPG (CoCaIn BPG), convergence of the whole sequence to a stationary point is proved for Matrix Factorization. In several experiments, we observe a superior performance of our non-alternating schemes in terms of speed and objective value at the limit point.

Keywords

Cite

@article{arxiv.1905.09050,
  title  = {Beyond Alternating Updates for Matrix Factorization with Inertial Bregman Proximal Gradient Algorithms},
  author = {Mahesh Chandra Mukkamala and Peter Ochs},
  journal= {arXiv preprint arXiv:1905.09050},
  year   = {2019}
}

Comments

Accepted at NeuRIPS 2019. Paper url: http://papers.nips.cc/paper/8679-beyond-alternating-updates-for-matrix-factorization-with-inertial-bregman-proximal-gradient-algorithms

R2 v1 2026-06-23T09:17:13.637Z