Ultra Low Power 3D-Embedded Convolutional Neural Network Cube Based on α-IGZO Nanosheet and Bi-Layer Resistive Memory

Sunanda Thunder, Parthasarathi Pal, Yeong-Her Wang, Po-Tsang Huang
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引用次数: 4

Abstract

In this paper we propose and evaluate the performance of a 3D-embedded neuromorphic computation block based on indium gallium zinc oxide (α-IGZO) based nanosheet transistor and bi-layer resistive memory devices. We have fabricated bi-layer resistive random-access memory (RRAM) devices with Ta2O5 and Al2O3 layers. The device has been characterized and modeled. The compact models of RRAM and α-IGZO based embedded nanosheet structures have been used to evaluate the system level performance of 8 vertically stacked α-IGZO based nanosheet layers with RRAM for neuromorphic applications. The model considers the design space with uniform bit line (BL), select line (SL) and word line (WL) resistance. Finally, we have simulated the weighted sum operation with our proposed 8-layer stacked nanosheet based embedded memory and evaluated the performance for VGG-16 convolutional neural network (CNN) for Fashion-MNIST and CIFAR-10 data recognition, which yielded 92% and 75% accuracy respectively with drop out layers amid device variation.
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基于α-IGZO纳米片和双层阻性存储器的超低功耗3d嵌入式卷积神经网络立方体
在本文中,我们提出并评估了基于铟镓氧化锌(α-IGZO)纳米片晶体管和双层阻性存储器件的3d嵌入式神经形态计算块的性能。我们制作了具有Ta2O5和Al2O3层的双层电阻随机存取存储器(RRAM)器件。对该装置进行了表征和建模。利用RRAM和基于α-IGZO的嵌入式纳米片结构的紧凑模型,对8个垂直堆叠的α-IGZO纳米片层进行了系统级性能评价。该模型考虑了具有均匀位线(BL)、选择线(SL)和字线(WL)阻力的设计空间。最后,我们用我们提出的基于8层堆叠纳米片的嵌入式存储器模拟了加权和运算,并评估了VGG-16卷积神经网络(CNN)在Fashion-MNIST和CIFAR-10数据识别中的性能,在设备变化的情况下,它们分别获得了92%和75%的准确率。
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