Dataflow-Based Joint Quantization for Deep Neural Networks

2019 Data Compression Conference (DCC) Pub Date : 2019-03-26 DOI:10.1109/DCC.2019.00086

Xue Geng, Jie Fu, Bin Zhao, Jie Lin, M. Aly, C. Pal, V. Chandrasekhar

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引用次数: 3

Abstract

This paper addresses a challenging problem – how to reduce energy consumption without incurring performance drop when deploying deep neural networks (DNNs) at the inference stage. In order to alleviate the computation and storage burdens, we propose a novel dataflow-based joint quantization approach with the hypothesis that a fewer number of quantization operations would incur less information loss and thus improve the final performance. It first introduces a quantization scheme with efficient bit-shifting and rounding operations to represent network parameters and activations in low precision. Then it re-structures the network architectures to form unified modules for optimization on the quantized model. Extensive experiments on ImageNet and KITTI validate the effectiveness of our model, demonstrating that state-of-the-art results for various tasks can be achieved by this quantized model. Besides, we designed and synthesized an RTL model to measure the hardware costs among various quantization methods. For each quantization operation, it reduces area cost by about 15 times and energy consumption by about 9 times, compared to a strong baseline.

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基于数据流的深度神经网络联合量化

本文解决了在推理阶段部署深度神经网络(dnn)时如何在不导致性能下降的情况下降低能耗的问题。为了减轻计算和存储负担，我们提出了一种新的基于数据流的联合量化方法，假设量化操作次数越少，信息丢失越少，从而提高最终性能。首先介绍了一种量化方案，采用高效的位移和舍入运算来表示低精度的网络参数和激活。然后对网络结构进行重构，形成统一的模块，对量化模型进行优化。在ImageNet和KITTI上进行的大量实验验证了我们模型的有效性，表明通过这种量化模型可以实现各种任务的最新结果。此外，我们设计并综合了一个RTL模型来衡量各种量化方法中的硬件成本。与强基线相比，每次量化操作可将面积成本降低约15倍，能耗降低约9倍。

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 Data Compression Conference (DCC)

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