English

Model Preserving Compression for Neural Networks

Machine Learning 2022-10-18 v2

Abstract

After training complex deep learning models, a common task is to compress the model to reduce compute and storage demands. When compressing, it is desirable to preserve the original model's per-example decisions (e.g., to go beyond top-1 accuracy or preserve robustness), maintain the network's structure, automatically determine per-layer compression levels, and eliminate the need for fine tuning. No existing compression methods simultaneously satisfy these criteria \unicodex2014\unicode{x2014} we introduce a principled approach that does by leveraging interpolative decompositions. Our approach simultaneously selects and eliminates channels (analogously, neurons), then constructs an interpolation matrix that propagates a correction into the next layer, preserving the network's structure. Consequently, our method achieves good performance even without fine tuning and admits theoretical analysis. Our theoretical generalization bound for a one layer network lends itself naturally to a heuristic that allows our method to automatically choose per-layer sizes for deep networks. We demonstrate the efficacy of our approach with strong empirical performance on a variety of tasks, models, and datasets \unicodex2014\unicode{x2014} from simple one-hidden-layer networks to deep networks on ImageNet.

Keywords

Cite

@article{arxiv.2108.00065,
  title  = {Model Preserving Compression for Neural Networks},
  author = {Jerry Chee and Megan Renz and Anil Damle and Christopher De Sa},
  journal= {arXiv preprint arXiv:2108.00065},
  year   = {2022}
}

Comments

26 pages, 15 figures. To be published in Advances in Neural Information Processing Systems 35

R2 v1 2026-06-24T04:42:15.495Z