Fast Tucker Rank Reduction for Non-Negative Tensors Using Mean-Field Approximation
Abstract
We present an efficient low-rank approximation algorithm for non-negative tensors. The algorithm is derived from our two findings: First, we show that rank-1 approximation for tensors can be viewed as a mean-field approximation by treating each tensor as a probability distribution. Second, we theoretically provide a sufficient condition for distribution parameters to reduce Tucker ranks of tensors; interestingly, this sufficient condition can be achieved by iterative application of the mean-field approximation. Since the mean-field approximation is always given as a closed formula, our findings lead to a fast low-rank approximation algorithm without using a gradient method. We empirically demonstrate that our algorithm is faster than the existing non-negative Tucker rank reduction methods and achieves competitive or better approximation of given tensors.
Cite
Text
Ghalamkari and Sugiyama. "Fast Tucker Rank Reduction for Non-Negative Tensors Using Mean-Field Approximation." Neural Information Processing Systems, 2021.Markdown
[Ghalamkari and Sugiyama. "Fast Tucker Rank Reduction for Non-Negative Tensors Using Mean-Field Approximation." Neural Information Processing Systems, 2021.](https://mlanthology.org/neurips/2021/ghalamkari2021neurips-fast/)BibTeX
@inproceedings{ghalamkari2021neurips-fast,
title = {{Fast Tucker Rank Reduction for Non-Negative Tensors Using Mean-Field Approximation}},
author = {Ghalamkari, Kazu and Sugiyama, Mahito},
booktitle = {Neural Information Processing Systems},
year = {2021},
url = {https://mlanthology.org/neurips/2021/ghalamkari2021neurips-fast/}
}