English

Differentiable Joint Pruning and Quantization for Hardware Efficiency

Machine Learning 2021-04-06 v2 Machine Learning

Abstract

We present a differentiable joint pruning and quantization (DJPQ) scheme. We frame neural network compression as a joint gradient-based optimization problem, trading off between model pruning and quantization automatically for hardware efficiency. DJPQ incorporates variational information bottleneck based structured pruning and mixed-bit precision quantization into a single differentiable loss function. In contrast to previous works which consider pruning and quantization separately, our method enables users to find the optimal trade-off between both in a single training procedure. To utilize the method for more efficient hardware inference, we extend DJPQ to integrate structured pruning with power-of-two bit-restricted quantization. We show that DJPQ significantly reduces the number of Bit-Operations (BOPs) for several networks while maintaining the top-1 accuracy of original floating-point models (e.g., 53x BOPs reduction in ResNet18 on ImageNet, 43x in MobileNetV2). Compared to the conventional two-stage approach, which optimizes pruning and quantization independently, our scheme outperforms in terms of both accuracy and BOPs. Even when considering bit-restricted quantization, DJPQ achieves larger compression ratios and better accuracy than the two-stage approach.

Keywords

Cite

@article{arxiv.2007.10463,
  title  = {Differentiable Joint Pruning and Quantization for Hardware Efficiency},
  author = {Ying Wang and Yadong Lu and Tijmen Blankevoort},
  journal= {arXiv preprint arXiv:2007.10463},
  year   = {2021}
}

Comments

Accepted to ECCV 2020

R2 v1 2026-06-23T17:15:50.953Z