Deep Model Pruning By Parallel Pooling Attention Block

2022 IEEE/WIC/ACM International Joint Conference on Web Intelligence and Intelligent Agent Technology (WI-IAT) Pub Date : 2022-11-01 DOI:10.1109/WI-IAT55865.2022.00138

Junnan Wu, Liming Zhang

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Abstract

Deep neural network models have achieved great success in various fields, including computer vision and recommendation systems. However, deep models are usually large and computationally time-consuming. Reducing the size of deep models and speeding up the learning process without a sharp drop in accuracy becomes a promising goal, both in research and practice. The channel pruning is one of the most effective methods, which can not only compress deep model size, but also directly speed up inference. In this paper, we propose a novel channel attention block called parallel pooling attention block (PPAB) that is designed on top of the squeeze and excitation (SE) blocks. There are two optimization improvements of PPAB. First, parallel max-pooling branch is added on top of SE blocks. Second, we avoid dimensionality reduction during the excitation phase. Both of these optimizations improve the channel importance measurement capabilities of PPAB. Experiment results show that PPAB outperforms general SE blocks on the channel attention objective. The proposed pruning method could be applied efficiently both in computer vision and recommendation systems.

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基于并行池化注意力块的深度模型剪枝

深度神经网络模型在各个领域都取得了巨大的成功，包括计算机视觉和推荐系统。然而，深度模型通常很大，而且计算时间很长。无论在研究还是实践中，减小深度模型的大小，加快学习过程，同时又不大幅降低准确率，都是一个很有希望的目标。通道剪枝是其中最有效的方法之一，它不仅可以压缩深度模型的大小，而且可以直接提高推理速度。在本文中，我们提出了一种新的通道注意力块，称为并行池化注意力块(PPAB)，它被设计在挤压和激励(SE)块之上。PPAB有两个优化改进。首先，在SE块上添加并行最大池化分支。其次，我们避免了在激励阶段的维数降低。这两种优化都提高了PPAB的信道重要性测量能力。实验结果表明，PPAB在信道注意目标上优于一般SE块。所提出的剪枝方法可以有效地应用于计算机视觉和推荐系统中。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE/WIC/ACM International Joint Conference on Web Intelligence and Intelligent Agent Technology (WI-IAT)

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