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Monolithically Integrated Complementary Ferroelectric FET XNOR Synapse for the Binary Neural Network

Authors
Hwang, JunghyeonJoh, HongraeKim, ChaeheonAhn, JinhoJeon, Sanghun
Issue Date
Jan-2024
Publisher
American Chemical Society
Keywords
binary neural network; complementary ferroelectric field-effect transistor; computing-in-memory; focused microwave annealing; monolithic 3-dimension integration
Citation
ACS Applied Materials & Interfaces, v.16, no.2, pp 2467 - 2476
Pages
10
Indexed
SCIE
SCOPUS
Journal Title
ACS Applied Materials & Interfaces
Volume
16
Number
2
Start Page
2467
End Page
2476
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/196602
DOI
10.1021/acsami.3c13945
ISSN
1944-8244
1944-8252
Abstract
Neuromorphic computing, which mimics the structure and principles of the human brain, has the potential to facilitate the hardware implementation of next-generation artificial intelligence systems and process large amounts of data with very low power consumption. Among them, the XNOR synapse-based Binary Neural Network (BNN) has been attracting attention due to its compact neural network parameter size and low hardware cost. The previous XNOR synapse has drawbacks, such as a trade-off between cell density and accuracy. In this work, we show nonvolatile XNOR synapses with high density and accuracy using a monolithically stacked complementary ferroelectric field-effect transistor (C-FeFET) composed of a p-type Si MFMIS-FeFET at the bottom and a 3D stackable n-type Al:IZTO MFS-FeTFT, achieving 60F2 per cell (2C-FeFET). For adjusting the threshold voltage and improving the switching speed (100 ns) of n-type ferroelectric TFT, we employed a dual-gate configuration and a unique operation scheme, making it comparable to those of Si-based FeFETs. We performed array-level simulation with a 512 × 512 subarray size and a 3-bit flash ADC, demonstrating that the image recognition accuracies using the MNIST and CIFAR-10 data sets were increased by 3.17 and 14.07%, respectively, in comparison to other nonvolatile XNOR synapses. In addition, we performed system-level analysis on a 512 × 512 XNOR C-FeFET, exhibiting an outstanding throughput of 717.37 GOPS and an energy efficiency of 196.7 TOPS/W. We expect that our approach would contribute to the high-density memory systems, logic-in-memory technology, and hardware implementation of neural networks.
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