材料科学
晶体管
深度学习
卷积神经网络
卷积(计算机科学)
人工神经网络
纳米技术
计算机硬件
线性
神经形态工程学
硬件加速
光电子学
数组数据结构
人工智能
电导
特征(语言学)
航程(航空)
薄膜晶体管
逻辑门
频道(广播)
锂(药物)
电子工程
集成电路
收缩阵列
特征提取
加法器
理论(学习稳定性)
计算机科学
作者
Zezhong Yin,Dandan Hao,Ranran Ci,Guangtan Miao,Yuhui Wang,Dong Yao,Ao Liu,Fukai Shan
标识
DOI:10.1002/adfm.202425471
摘要
Abstract In‐memory computing architectures based on artificial synaptic arrays offer higher computing efficiency than traditional hardware in deep learning applications. However, the core devices within the array must be capable of achieving high linearity and symmetric conductance programming with minimal variability. In this report, solid‐state electrolyte thin films of lithium and fluorine co‐doped ZrO 2 (F:ZrLiO x ) are prepared by the sol–gel method, and electrolyte‐gated synaptic transistors (EGSTs) based on In 2 O 3 /F:ZrLiO x are fabricated. The F:ZrLiO x EGSTs demonstrate excellent synaptic performance, and show potential for large‐scale integration with silicon‐based circuits. To further verify the potential of F:ZrLiO x EGSTs for application in deep learning, a 10 × 10 synaptic transistor array is fabricated using F:ZrLiOx EGSTs. This array exhibits a large dynamic range (G max /G min = 105.71), high linearity (0.38/−0.68), and high stability (10 3 cycles) in the conductance updating process. It can also perform precise convolution operations for feature extraction from input images. As a hardware accelerator for convolutional neural networks (CNNs), the F:ZrLiO x EGST array attains a high image recognition accuracy of 96.3% based on the CIFAR‐10 dataset. These results illustrate the technological potential of the F:ZrLiO x EGST array as a cost‐efficient and high‐performance hardware accelerator for neural networks in deep learning.
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