Bayesian Compression for Deep Learning
Abstract
Compression and computational efficiency in deep learning have become a problem of great significance. In this work, we argue that the most principled and effective way to attack this problem is by adopting a Bayesian point of view, where through sparsity inducing priors we prune large parts of the network. We introduce two novelties in this paper: 1) we use hierarchical priors to prune nodes instead of individual weights, and 2) we use the posterior uncertainties to determine the optimal fixed point precision to encode the weights. Both factors significantly contribute to achieving the state of the art in terms of compression rates, while still staying competitive with methods designed to optimize for speed or energy efficiency.
Cite
Text
Louizos et al. "Bayesian Compression for Deep Learning." Neural Information Processing Systems, 2017.Markdown
[Louizos et al. "Bayesian Compression for Deep Learning." Neural Information Processing Systems, 2017.](https://mlanthology.org/neurips/2017/louizos2017neurips-bayesian/)BibTeX
@inproceedings{louizos2017neurips-bayesian,
title = {{Bayesian Compression for Deep Learning}},
author = {Louizos, Christos and Ullrich, Karen and Welling, Max},
booktitle = {Neural Information Processing Systems},
year = {2017},
pages = {3288-3298},
url = {https://mlanthology.org/neurips/2017/louizos2017neurips-bayesian/}
}