Part of Advances in Neural Information Processing Systems 27 (NIPS 2014)

*Emile Richard, Andrea Montanari*

We consider the Principal Component Analysis problem for large tensors of arbitrary order k under a single-spike (or rank-one plus noise) model. On the one hand, we use information theory, and recent results in probability theory to establish necessary and sufficient conditions under which the principal component can be estimated using unbounded computational resources. It turns out that this is possible as soon as the signal-to-noise ratio beta becomes larger than C\sqrt{k log k} (and in particular beta can remain bounded has the problem dimensions increase). On the other hand, we analyze several polynomial-time estimation algorithms, based on tensor unfolding, power iteration and message passing ideas from graphical models. We show that, unless the signal-to-noise ratio diverges in the system dimensions, none of these approaches succeeds. This is possibly related to a fundamental limitation of computationally tractable estimators for this problem. For moderate dimensions, we propose an hybrid approach that uses unfolding together with power iteration, and show that it outperforms significantly baseline methods. Finally, we consider the case in which additional side information is available about the unknown signal. We characterize the amount of side information that allow the iterative algorithms to converge to a good estimate.

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