高能效循环尖峰神经处理器的发射活动稀疏性与时钟门控研究

2017 IEEE/ACM International Symposium on Low Power Electronics and Design (ISLPED) Pub Date : 2017-07-24 DOI:10.1109/ISLPED.2017.8009197

Yu Liu, Yingyezhe Jin, Peng Li

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引用次数: 6

摘要

作为循环脉冲神经网络的一种模型，液态机(LSM)为模式识别和机器学习应用提供了一个强大的脑启发计算平台。虽然LSM是通过处理神经尖峰活动来操作的，但它通过探索从循环神经网络中出现的典型稀疏触发模式，以及对运行时由不同触发事件编排的计算任务的智能处理，自然地使自己成为高效的硬件实现。我们通过提出具有集成片上学习及其FPGA实现的LSM处理器架构来探索这些机会。我们的LSM处理器利用触发活动的稀疏性来实现高效的事件驱动处理和依赖于活动的时钟门控。使用TI46[1]语音识别语料库中采用的英语口语字母作为基准，我们表明，所提出的基于fpga的神经处理器系统比基线LSM处理器节能29%，并且几乎没有额外的硬件开销。

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Exploring sparsity of firing activities and clock gating for energy-efficient recurrent spiking neural processors

As a model of recurrent spiking neural networks, the Liquid State Machine (LSM) offers a powerful brain-inspired computing platform for pattern recognition and machine learning applications. While operated by processing neural spiking activities, the LSM naturally lends itself to an efficient hardware implementation via exploration of typical sparse firing patterns emerged from the recurrent neural network and smart processing of computational tasks that are orchestrated by different firing events at runtime. We explore these opportunities by presenting a LSM processor architecture with integrated on-chip learning and its FPGA implementation. Our LSM processor leverage the sparsity of firing activities to allow for efficient event-driven processing and activity-dependent clock gating. Using the spoken English letters adopted from the TI46 [1] speech recognition corpus as a benchmark, we show that the proposed FPGA-based neural processor system is up to 29% more energy efficient than a baseline LSM processor with little extra hardware overhead.

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2017 IEEE/ACM International Symposium on Low Power Electronics and Design (ISLPED)

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