Tractable structured natural gradient descent using local parameterizations
Abstract
Natural-gradient descent (NGD) on structured parameter spaces (e.g., low-rank covariances) is computationally challenging due to difficult Fisher-matrix computations. We address this issue by using \emph{local-parameter coordinates} to obtain a flexible and efficient NGD method that works well for a wide-variety of structured parameterizations. We show four applications where our method (1) generalizes the exponential natural evolutionary strategy, (2) recovers existing Newton-like algorithms, (3) yields new structured second-order algorithms via matrix groups, and (4) gives new algorithms to learn covariances of Gaussian and Wishart-based distributions. We show results on a range of problems from deep learning, variational inference, and evolution strategies. Our work opens a new direction for scalable structured geometric methods.
Cite
@article{arxiv.2102.07405,
title = {Tractable structured natural gradient descent using local parameterizations},
author = {Wu Lin and Frank Nielsen and Mohammad Emtiyaz Khan and Mark Schmidt},
journal= {arXiv preprint arXiv:2102.07405},
year = {2022}
}
Comments
An extended version of the ICML 2021 paper. Note: A workshop (short) paper with a focus on optimization tasks can be found at arXiv:2107.10884