2017
NIPS
NeurIPS 2017
On Tensor Train Rank Minimization : Statistical Efficiency and Scalable Algorithm
Abstract
Tensor train (TT) decomposition provides a space-efficient representation for higher-order tensors. Despite its advantage, we face two crucial limitations when we apply the TT decomposition to machine learning problems: the lack of statistical theory and of scalable algorithms. In this paper, we address the limitations. First, we introduce a convex relaxation of the TT decomposition problem and derive its error bound for the tensor completion task. Next, we develop a randomized optimization method, in which the time complexity is as efficient as the space complexity is. In experiments, we numerically confirm the derived bounds and empirically demonstrate the performance of our method with a real higher-order tensor.
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Interdisciplinary Bridge
— Machine Learning and Mathematics & Optimization
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Keyword Pioneer
— higher-order tensor
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Cross-Pollinator
— Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Interdisciplinary, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning
Authors
Topics
Machine Learning > Core Methods > Representation Learning
Machine Learning > Optimization & Theory > Statistical Learning
Mathematics & Optimization > Mathematics > Linear Algebra
Mathematics & Optimization > Optimization > Continuous Optimization
Mathematics & Optimization > Optimization > Stochastic Methods
Machine Learning > Optimization & Theory > Statistics
Machine Learning > Core Methods > Matrix Factorization
Mathematics & Optimization > Optimization > Sparse Optimization