Sparse Plus Low Rank Matrix Decomposition: A Discrete Optimization Approach
Abstract
We study the Sparse Plus Low-Rank decomposition problem (SLR), which is the problem of decomposing a corrupted data matrix into a sparse matrix of perturbations plus a low-rank matrix containing the ground truth. SLR is a fundamental problem in Operations Research and Machine Learning which arises in various applications, including data compression, latent semantic indexing, collaborative filtering, and medical imaging. We introduce a novel formulation for SLR that directly models its underlying discreteness. For this formulation, we develop an alternating minimization heuristic that computes high-quality solutions and a novel semidefinite relaxation that provides meaningful bounds for the solutions returned by our heuristic. We also develop a custom branch-and-bound algorithm that leverages our heuristic and convex relaxations to solve small instances of SLR to certifiable (near) optimality. Given an input -by- matrix, our heuristic scales to solve instances where in minutes, our relaxation scales to instances where in hours, and our branch-and-bound algorithm scales to instances where in minutes. Our numerical results demonstrate that our approach outperforms existing state-of-the-art approaches in terms of rank, sparsity, and mean-square error while maintaining a comparable runtime.
Cite
@article{arxiv.2109.12701,
title = {Sparse Plus Low Rank Matrix Decomposition: A Discrete Optimization Approach},
author = {Dimitris Bertsimas and Ryan Cory-Wright and Nicholas A. G. Johnson},
journal= {arXiv preprint arXiv:2109.12701},
year = {2023}
}