Nonconvex Matrix Completion
Author: Ji Chen
Publisher:
Published: 2020
Total Pages:
ISBN-13:
DOWNLOAD EBOOKTechniques of matrix completion aim to impute a large portion of missing entries in a data matrix through a small portion of observed ones, with broad machine learning applications including collaborative filtering, system identification, global positioning, etc. This dissertation aims to analyze the nonconvex matrix problem from geometric and algorithmic perspectives. The first part of the dissertation, i.e., Chapter 2 and 3, focuses on analyzing the nonconvex matrix completion problem from the geometric perspective. Geometric analysis has been conducted on various low-rank recovery problems including phase retrieval, matrix factorization and matrix completion in recent few years. Taking matrix completion as an example, with assumptions on the underlying matrix and the sampling rate, all the local minima of the nonconvex objective function were shown to be global minima, i.e., nonconvex optimization can recover the underlying matrix exactly. In Chapter 2, we propose a model-free framework for nonconvex matrix completion: We characterize how well local-minimum based low-rank factorization approximates the underlying matrix without any assumption on it. As an implication, a corollary of our main theorem improves the state-of-the-art sampling rate required for nonconvex matrix completion to rule out spurious local minima. In practice, additional structures are usually employed in order to improve the accuracy of matrix completion. Examples include subspace constraints formed by side information in collaborative filtering, and skew symmetry in pairwise ranking. Chapter 3 performs a unified geometric analysis of nonconvex matrix completion with linearly parameterized factorization, which covers the aforementioned examples as special cases. Uniform upper bounds for estimation errors are established for all local minima, provided assumptions on the sampling rate and the underlying matrix are satisfied. The second part of the dissertation (Chapter 4) focuses on algorithmic analysis of nonconvex matrix completion. Row-wise projection/regularization has become a widely adapted assumption due to its convenience for analysis, though it was observed to be unnecessary in numerical simulations. Recently the gap between theory and practice has been overcome for positive semidefinite matrix completion via so called leave-one-out analysis. In Chapter 4, we extend the leave-one-out analysis to the rectangular case, and more significantly, improve the required sampling rate for convergence guarantee.