Exploration of Automatic Mixed-Precision Search for Deep Neural Networks

2019 IEEE International Conference on Artificial Intelligence Circuits and Systems (AICAS) Pub Date : 2019-03-01 DOI:10.1109/AICAS.2019.8771498

Xuyang Guo, Yuanjun Huang, Hsin-Pai Cheng, Bing Li, W. Wen, Siyuan Ma, H. Li, Yiran Chen

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引用次数: 3

Abstract

Neural networks have shown great performance in cognitive tasks. When deploying network models on mobile devices with limited computation and storage resources, the weight quantization technique has been widely adopted. In practice, 8-bit or 16-bit quantization is mostly likely to be selected in order to maintain the accuracy at the same level as the models in 32-bit floating-point precision. Binary quantization, on the contrary, aims to obtain the highest compression at the cost of much bigger accuracy drop. Applying different precision in different layers/structures can potentially produce the most efficient model. Seeking for the best precision configuration, however, is difficult. In this work, we proposed an automatic search algorithm to address the challenge. By relaxing the search space of quantization bitwidth from discrete to continuous domain, our algorithm can generate a mixed-precision quantization scheme which achieves the compression rate close to the one from the binary-weighted model while maintaining the testing accuracy similar to the original full-precision model.

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深度神经网络自动混合精度搜索的探索

神经网络在认知任务中表现优异。当在计算和存储资源有限的移动设备上部署网络模型时，权重量化技术被广泛采用。在实践中，为了保持与32位浮点精度模型相同的精度水平，最可能选择8位或16位量化。相反，二值量化的目标是以更大的精度下降为代价获得最高的压缩。在不同的层/结构中应用不同的精度可以产生最有效的模型。然而，寻找最佳精度配置是困难的。在这项工作中，我们提出了一种自动搜索算法来解决这一挑战。通过将量化位宽的搜索空间从离散域放宽到连续域，我们的算法可以生成一种混合精度量化方案，该方案的压缩率接近于二值加权模型的压缩率，同时保持与原全精度模型相似的测试精度。

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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来源期刊

2019 IEEE International Conference on Artificial Intelligence Circuits and Systems (AICAS)

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