B. W. Ku, Yu Liu, Yingyezhe Jin, S. Samal, Peng Li, S. Lim
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引用次数: 9
Abstract
A liquid state machine (LSM) is a powerful recurrent spiking neural network shown to be effective in various learning tasks including speech recognition. In this work, we investigate design and architectural co-optimization to further improve the area-energy efficiency of LSM-based speech recognition processors with monolithic 3D IC (M3D) technology. We conduct fine-grained tier partitioning, where individual neurons are folded, and explore the impact of shared memory architecture and synaptic model complexity on the power-performance-area-accuracy (PPA) benefit of M3D LSM-based speech recognition. In training and classification tasks using spoken English letters, we obtain up to 70.0% PPAA savings over 2D ICs.
液态机(LSM)是一种强大的循环尖峰神经网络,在包括语音识别在内的各种学习任务中表现出有效的效果。在这项工作中,我们研究了设计和架构的协同优化,以进一步提高基于lsm的单片3D IC (M3D)技术的语音识别处理器的面积能源效率。我们进行了细粒度的层划分,其中单个神经元折叠,并探讨了共享内存架构和突触模型复杂性对基于M3D lsm的语音识别功率-性能-面积-精度(PPA)效益的影响。在使用英语口语字母的训练和分类任务中,我们比2D ic节省了高达70.0%的PPAA。
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