Structured Support Exploration for Multilayer Sparse Matrix Factorization

Quoc-Tung Le, R. Gribonval
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引用次数: 7

Abstract

Matrix factorization with sparsity constraints plays an important role in many machine learning and signal processing problems such as dictionary learning, data visualization, dimension reduction. Among the most popular tools for sparse matrix factorization are proximal algorithms, a family of algorithms based on proximal operators. In this paper, we address two problems with the application of proximal algorithms to sparse matrix factorization. On the one hand, we analyze a weakness of proximal algorithms in sparse matrix factorization: the premature convergence of the support. A remedy is also proposed to address this problem. On the other hand, we describe a new tractable proximal operator called Generalized Hungarian Method, associated to so-called k-regular matrices, which are useful for the factorization of a class of matrices associated to fast linear transforms. We further illustrate the effectiveness of our proposals by numerical experiments on the Hadamard Transform and magnetoencephalography matrix factorization.
多层稀疏矩阵分解的结构化支持探索
具有稀疏约束的矩阵分解在许多机器学习和信号处理问题中起着重要作用,如字典学习、数据可视化、降维等。在稀疏矩阵分解中最流行的工具是近端算法,这是一组基于近端算子的算法。本文讨论了在稀疏矩阵分解中应用近端算法的两个问题。一方面,我们分析了稀疏矩阵分解的近端算法的缺点:支持的过早收敛。为解决这一问题,还提出了一种补救办法。另一方面,我们描述了一种新的可处理的近邻算子,称为广义匈牙利方法,它与所谓的k正则矩阵有关,它对于一类与快速线性变换有关的矩阵的分解是有用的。我们通过对Hadamard变换和脑磁图矩阵分解的数值实验进一步证明了我们的建议的有效性。
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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