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Practical Leverage-Based Sampling for Low-Rank Tensor Decomposition

Brett W. Larsen, Tamara G. Kolda

2022SIAM Journal on Matrix Analysis and Applications31 citationsDOI

Abstract

The low-rank canonical polyadic tensor decomposition is useful in data analysis and can be computed by solving a sequence of overdetermined least squares subproblems. Motivated by consideration of sparse tensors, we propose sketching each subproblem using leverage scores to select a subset of the rows, with probabilistic guarantees on the solution accuracy. We randomly sample rows proportional to leverage score upper bounds that can be efficiently computed using the special Khatri--Rao subproblem structure inherent in tensor decomposition. Crucially, for a $(d+1)$-way tensor, the number of rows in the sketched system is $O(r^d/\epsilon)$ for a decomposition of rank $r$ and $\epsilon$-accuracy in the least squares solve, independent of both the size and the number of nonzeros in the tensor. Along the way, we provide a practical solution to the generic matrix sketching problem of sampling overabundance for high-leverage-score rows, proposing to include such rows deterministically and combine repeated samples in the sketched system; we conjecture that this can lead to improved theoretical bounds. Numerical results on real-world large-scale tensors show the method is significantly faster than deterministic methods at nearly the same level of accuracy.

Topics & Concepts

Overdetermined systemMathematicsRowLeverage (statistics)Tensor (intrinsic definition)Tensor decompositionRank (graph theory)AlgorithmApplied mathematicsCombinatoricsComputer sciencePure mathematicsStatisticsDatabaseTensor decomposition and applicationsSparse and Compressive Sensing TechniquesAlgorithms and Data Compression
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