一种新的突触编码和映射方案，用于可靠的基于reram的神经形态计算

2020 Design, Automation & Test in Europe Conference & Exhibition (DATE) Pub Date : 2020-03-01 DOI:10.23919/DATE48585.2020.9116555

Chang Ma, Yanan Sun, Weikang Qian, Ziqi Meng, Rui Yang, Li Jiang

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引用次数: 15

摘要

神经网络(NN)计算中包含大量的乘法累加(MAC)运算，这是传统冯诺依曼体系结构的速度瓶颈。基于电阻随机存取存储器(ReRAM)的交叉棒非常适合于矩阵-向量乘法。现有的基于reram的神经网络主要是基于突触权值的二进制编码。然而，由于制作工艺的不完善，加上基于丝的随机开关，导致电阻变化，这将显著影响二元突触的权重，降低神经网络的精度。此外，由于为了减少硬件开销而开发多级单元(MLCs)，由于二进制编码中的阻力变化，神经网络的精度会进一步恶化。本文提出了一种新的突触权值一元编码方法，克服了MLCs的阻力变化，实现了可靠的基于reram的神经形态计算。为了保证较高的精度，还提出了符合一元编码的优先级映射，将电阻状态较低的位映射到电阻变化较小的reram上。实验结果表明，该方法在LeNet (MNIST数据集)和VGG16 (CIFAR-10数据集)上的准确率损失分别小于0.45%和5.48%，硬件成本可接受。

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Go Unary: A Novel Synapse Coding and Mapping Scheme for Reliable ReRAM-based Neuromorphic Computing

Neural network (NN) computing contains a large number of multiply-and-accumulate (MAC) operations, which is the speed bottleneck in traditional von Neumann architecture. Resistive random access memory (ReRAM)-based crossbar is well suited for matrix-vector multiplication. Existing ReRAM-based NNs are mainly based on the binary coding for synaptic weights. However, the imperfect fabrication process combined with stochastic filament-based switching leads to resistance variations, which can significantly affect the weights in binary synapses and degrade the accuracy of NNs. Further, as multi-level cells (MLCs) are being developed for reducing hardware overhead, the NN accuracy deteriorates more due to the resistance variations in the binary coding. In this paper, a novel unary coding of synaptic weights is presented to overcome the resistance variations of MLCs and achieve reliable ReRAM-based neuromorphic computing. The priority mapping is also proposed in compliance with the unary coding to guarantee high accuracy by mapping those bits with lower resistance states to ReRAMs with smaller resistance variations. Our experimental results show that the proposed method provides less than 0.45% and 5.48% accuracy loss on LeNet (on MNIST dataset) and VGG16 (on CIFAR-10 dataset), respectively, with acceptable hardware cost.

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2020 Design, Automation & Test in Europe Conference & Exhibition (DATE)

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