Embedded Knowledge Distillation in Depth-Level Dynamic Neural Network
Abstract
In real applications, different computation-resource devices need different-depth networks (e.g., ResNet-18/34/50) with high-accuracy. Usually, existing methods either design multiple networks and train them independently, or construct depth-level/width-level dynamic neural networks which is hard to prove the accuracy of each sub-net. In this article, we propose an elegant Depth-Level Dynamic Neural Network (DDNN) integrated different-depth sub-nets of similar architectures. To improve the generalization of sub-nets, we design the Embedded-Knowledge-Distillation (EKD) training mechanism for the DDNN to implement knowledge transfer from the teacher (full-net) to multiple students (sub-nets). Specifically, the Kullback-Leibler (KL) divergence is introduced to constrain the posterior class probability consistency between full-net and sub-nets, and self-attention distillation on the same resolution feature of different depth is addressed to drive more abundant feature representations of sub-nets. Thus, we can obtain multiple high-accuracy sub-nets simultaneously in a DDNN via the online knowledge distillation in each training iteration without extra computation cost. Extensive experiments on CIFAR-10/100, and ImageNet datasets demonstrate that sub-nets in DDNN with EKD training achieve better performance than individually training networks while preserving the original performance of full-nets.
Cite
@article{arxiv.2103.00793,
title = {Embedded Knowledge Distillation in Depth-Level Dynamic Neural Network},
author = {Qi Zhao and Shuchang Lyu and Zhiwei Zhang and Ting-Bing Xu and Guangliang Cheng},
journal= {arXiv preprint arXiv:2103.00793},
year = {2021}
}
Comments
4 pages, 3 figures; Accepted by CVPR2021 workshop: Dynamic Neural Networks Meets Computer Vision