Plenty of room at the bottom? Micropower deep learning for cognitive cyber physical systems

2017 7th IEEE International Workshop on Advances in Sensors and Interfaces (IWASI) Pub Date : 2017-06-01 DOI:10.1109/IWASI.2017.7974239

L. Benini

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引用次数: 6

Abstract

Deep convolutional neural networks are being regarded today as an extremely effective and flexible approach for extracting actionable, high-level information from the wealth of raw data produced by a wide variety of sensory data sources. CNNs are however computationally demanding: today they typically run on GPU-accelerated compute servers or high-end embedded platforms. Industry and academia are racing to bring CNN inference (first) and training (next) within ever tighter power envelopes, while at the same time meeting real-time requirements. Recent results, including our PULP and ORIGAMI chips, demonstrate there is plenty of room at the bottom: pj/OP (GOPS/mW) computational efficiency, needed for deploying CNNs in the mobile/wearable scenario, is within reach. However, this is not enough: 1000x energy efficiency improvement, within a mW power envelope and with low-cost CMOS processes, is required for deploying CNNs in the most demanding CPS scenarios. The fj/OP milestone will require heterogeneous (3D) integration with ultra-efficient die-to-die communication, mixed-signal pre-processing, event-based approximate computing, while still meeting real-time requirements.

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底部有足够的空间?认知网络物理系统的微功率深度学习

如今，深度卷积神经网络被认为是一种极其有效和灵活的方法，可以从各种感官数据源产生的大量原始数据中提取可操作的高级信息。然而，cnn对计算的要求很高:今天，它们通常运行在gpu加速的计算服务器或高端嵌入式平台上。工业界和学术界都在竞相在更紧凑的功率范围内实现CNN推理(第一)和训练(第二)，同时满足实时要求。最近的结果，包括我们的PULP和ORIGAMI芯片，证明了底部有很大的空间:在移动/可穿戴场景中部署cnn所需的pj/OP (GOPS/mW)计算效率是可以达到的。然而，这还不够:要在最苛刻的CPS场景中部署cnn，需要在mW功率包络内使用低成本CMOS工艺将能效提高1000倍。fj/OP里程碑将需要异构(3D)集成与超高效模对模通信，混合信号预处理，基于事件的近似计算，同时仍然满足实时性要求。

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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2017 7th IEEE International Workshop on Advances in Sensors and Interfaces (IWASI)

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