Binary image classification using a neurosynaptic processor: A trade-off analysis

2016 IEEE International Symposium on Circuits and Systems (ISCAS) Pub Date : 2016-05-22 DOI:10.1109/ISCAS.2016.7527497

William E. Murphy, Megan Renz, Qing Wu

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引用次数: 3

Abstract

This paper examines the performance of two power efficient hardware implementations using deep neural networks to perform a simple image classification task. We provide the first ever examination of the accuracy-energy trade-offs of deep neural networks running on both an embedded GPU, and a neuromorphic processor. IBM's TrueNorth is a brain-inspired event-driven neuromorphic processor. It was designed to be scalable and to consume extremely low amounts of power. NVIDIA's Tegra K1 SoC is a mobile processor also designed with low power and a small footprint in mind. While these two chips were designed with similar constraints, the resulting architectures and performance trade-offs achieved are significantly different. On our simple image classification task Convolutional Neural Networks utilizing the Tegra K1 SoC achieve up to 89 % accuracy with a normalized accuracy per active energy, ||Acc||/EA, score of up to 24.22 on our test dataset, while Tea Networks running on the TrueNorth processor achieve less accuracy at 82%, but a better accuracy-energy trade-off with a ||Acc||/EA score of up to 158.49.

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使用神经突触处理器的二值图像分类:权衡分析

本文研究了使用深度神经网络执行简单图像分类任务的两种低功耗硬件实现的性能。我们提供了在嵌入式GPU和神经形态处理器上运行的深度神经网络的精度-能量权衡的首次检查。IBM的TrueNorth是一个受大脑启发的事件驱动的神经形态处理器。它的设计是可扩展的，并且消耗极低的能量。NVIDIA的Tegra K1 SoC是一款移动处理器，在设计时也考虑到低功耗和小体积。虽然这两种芯片的设计约束相似，但最终的架构和实现的性能权衡却有很大不同。在我们的简单图像分类任务中，使用Tegra K1 SoC的卷积神经网络在我们的测试数据集中实现了高达89%的准确率，每有效能量的归一化准确率为||Acc||/EA，得分高达24.22，而在TrueNorth处理器上运行的Tea网络的准确率为82%，但精度-能量平衡更好，||Acc||/EA得分高达158.49。

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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2016 IEEE International Symposium on Circuits and Systems (ISCAS)

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