Matrix Completion and Related Problems via Strong Duality

J. Mach. Learn. Res. Pub Date : 2017-04-27 DOI:10.4230/LIPIcs.ITCS.2018.5

Maria-Florina Balcan, Yingyu Liang, David P. Woodruff, Hongyang Zhang

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引用次数: 20

Abstract

This work studies the strong duality of non-convex matrix factorization problems: we show that under certain dual conditions, these problems and its dual have the same optimum. This has been well understood for convex optimization, but little was known for non-convex problems. We propose a novel analytical framework and show that under certain dual conditions, the optimal solution of the matrix factorization program is the same as its bi-dual and thus the global optimality of the non-convex program can be achieved by solving its bi-dual which is convex. These dual conditions are satisfied by a wide class of matrix factorization problems, although matrix factorization problems are hard to solve in full generality. This analytical framework may be of independent interest to non-convex optimization more broadly. We apply our framework to two prototypical matrix factorization problems: matrix completion and robust Principal Component Analysis (PCA). These are examples of efficiently recovering a hidden matrix given limited reliable observations of it. Our framework shows that exact recoverability and strong duality hold with nearly-optimal sample complexity guarantees for matrix completion and robust PCA.

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强对偶矩阵补全及相关问题

本文研究了非凸矩阵分解问题的强对偶性，证明了在一定的对偶条件下，这些问题与其对偶具有相同的最优解。对于凸优化，这一点已经得到了很好的理解，但对于非凸问题，这一点却知之甚少。提出了一种新的解析框架，证明了在一定对偶条件下，矩阵分解规划的最优解与其双对偶相同，从而通过求解其双对偶实现非凸规划的全局最优性。尽管矩阵分解问题很难得到完全的一般解，但许多矩阵分解问题都满足这些对偶条件。这种分析框架可能对更广泛的非凸优化具有独立的兴趣。我们将我们的框架应用于两个典型的矩阵分解问题:矩阵补全和鲁棒主成分分析(PCA)。这些都是在给定有限的可靠观测值的情况下有效地恢复隐藏矩阵的例子。我们的框架表明，精确的可恢复性和强对偶性对矩阵补全和鲁棒主成分分析具有几乎最优的样本复杂度保证。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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