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稀疏线性表示中用于字典学习的正交普罗克汝斯分析

Orthogonal Procrustes Analysis for Dictionary Learning in Sparse Linear Representation.

作者信息

Grossi Giuliano, Lanzarotti Raffaella, Lin Jianyi

机构信息

Department of Computer Science, University of Milan, Via Comelico 39, 20135 Milan, Italy.

Department of Applied Mathematics and Sciences, Khalifa University, Al Saada St., PO Box 127788, Abu Dhabi, United Arab Emirates.

出版信息

PLoS One. 2017 Jan 19;12(1):e0169663. doi: 10.1371/journal.pone.0169663. eCollection 2017.

DOI:10.1371/journal.pone.0169663
PMID:28103283
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5245881/
Abstract

In the sparse representation model, the design of overcomplete dictionaries plays a key role for the effectiveness and applicability in different domains. Recent research has produced several dictionary learning approaches, being proven that dictionaries learnt by data examples significantly outperform structured ones, e.g. wavelet transforms. In this context, learning consists in adapting the dictionary atoms to a set of training signals in order to promote a sparse representation that minimizes the reconstruction error. Finding the best fitting dictionary remains a very difficult task, leaving the question still open. A well-established heuristic method for tackling this problem is an iterative alternating scheme, adopted for instance in the well-known K-SVD algorithm. Essentially, it consists in repeating two stages; the former promotes sparse coding of the training set and the latter adapts the dictionary to reduce the error. In this paper we present R-SVD, a new method that, while maintaining the alternating scheme, adopts the Orthogonal Procrustes analysis to update the dictionary atoms suitably arranged into groups. Comparative experiments on synthetic data prove the effectiveness of R-SVD with respect to well known dictionary learning algorithms such as K-SVD, ILS-DLA and the online method OSDL. Moreover, experiments on natural data such as ECG compression, EEG sparse representation, and image modeling confirm R-SVD's robustness and wide applicability.

摘要

在稀疏表示模型中,超完备字典的设计对于其在不同领域的有效性和适用性起着关键作用。最近的研究提出了几种字典学习方法,事实证明,通过数据示例学习的字典明显优于结构化字典,例如小波变换。在此背景下,学习在于使字典原子适应一组训练信号,以促进稀疏表示,从而使重构误差最小化。找到最佳拟合字典仍然是一项非常艰巨的任务,该问题仍然悬而未决。一种成熟的解决此问题的启发式方法是迭代交替方案,例如在著名的K-SVD算法中采用。本质上,它包括重复两个阶段;前者促进训练集的稀疏编码,后者调整字典以减少误差。在本文中,我们提出了R-SVD,这是一种新方法,在保持交替方案的同时,采用正交Procrustes分析来更新适当分组排列的字典原子。在合成数据上的对比实验证明了R-SVD相对于著名的字典学习算法(如K-SVD、ILS-DLA和在线方法OSDL)的有效性。此外,在自然数据上的实验,如心电图压缩、脑电图稀疏表示和图像建模,证实了R-SVD的鲁棒性和广泛适用性。

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