Canonical Polyadic Decomposition: From 3-way to N-Way

2012 Eighth International Conference on Computational Intelligence and Security Pub Date : 2012-11-17 DOI:10.1109/CIS.2012.94

Guoxu Zhou, Zhaoshui He, Yu Zhang, Qibin Zhao, A. Cichocki

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引用次数: 8

Abstract

Canonical Polyadic (or CANDECOMP/PARAFAC, CP) decompositions are widely applied to analyze high order data, i.e. N-way tensors. Existing CP decomposition methods use alternating least square (ALS) iterations and hence need to compute the inverse of matrices and unfold tensors frequently, which are very time consuming for large-scale data and when N is large. Fortunately, once at least one factor has been correctly estimated, all the remaining factors can be computed efficiently and uniquely by using a series of rank-one approximations. Motivated by this fact, to perform a full N-way CP decomposition, we run 3-way CP decompositions on a sub-tensor to estimate two factors first. Then the remaining factors are estimated via an efficient Khatri-Rao product recovering procedure. In this way the whole ALS iterations with respect to each mode are avoided and the efficiency can be significantly improved. Simulations show that, compared with ALS based CP decomposition methods, the proposed method is more efficient and is easier to escape from local solutions for high order tensors.

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正则多元分解:从3-way到N-Way

规范多元分解(或CANDECOMP/PARAFAC, CP)被广泛应用于分析高阶数据，即n路张量。现有的CP分解方法使用交替最小二乘迭代，因此需要频繁地计算矩阵逆和展开张量，这对于大规模数据和N较大时非常耗时。幸运的是，一旦至少有一个因素被正确估计，所有剩下的因素都可以通过使用一系列排名第一的近似来有效和唯一地计算出来。基于这一事实，为了执行完整的n向CP分解，我们在子张量上运行3向CP分解，首先估计两个因子。然后通过有效的Khatri-Rao产品回收程序估计剩余因素。这样可以避免对每个模式进行整个ALS迭代，并且可以显着提高效率。仿真结果表明，与基于渐近渐近函数的CP分解方法相比，该方法效率更高，且更容易摆脱高阶张量的局部解。

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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2012 Eighth International Conference on Computational Intelligence and Security

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