神经形态工程学
突触重量
小型化
晶体管
计算机科学
材料科学
冯·诺依曼建筑
动态范围
能源消耗
瓶颈
人工神经网络
纳米技术
光电子学
电气工程
嵌入式系统
人工智能
电压
电子工程
工程类
操作系统
作者
Bin Tang,Xuan Li,Jianhui Liao,Qing Chen
标识
DOI:10.1021/acsaelm.1c00970
摘要
The conventional von-Neumann architecture suffers from large power consumption, high circuitry complexity, and difficulty in miniaturization due to the physical separation of the processing and memory units. To overcome this bottleneck, neuromorphic computing has been proposed, which can work with ultralow power consumption and without any need for a bus for transferring data. Synaptic transistors are a fundamental part of the neuromorphic system, which can integrate signal processing and storage. However, a relatively poor performance of the reported synaptic devices, such as the nonlinear weight update, small dynamic range, and higher energy consumption than that of biological synapses (∼10 fJ), hinders the development of energy-efficient neuromorphic systems. Here, we demonstrate the excellent performance of a top-gated synaptic transistor based on α-In2Se3 nanosheets with a thickness of less than 10 nm. Their outstanding performances include an ultralow power consumption of 3.36 fJ per spike response, a large dynamic range of 158, and near-zero nonlinearity. In addition, a simulated neural network based on our synaptic transistor shows excellent pattern recognition accuracy. After 120 online learning cycles, the pattern recognition accuracy reaches 92.1%, which is close to the ideal accuracy of 93.2%. Such a high-performance synaptic transistor implies the great potential of two-dimensional ferroelectric semiconductors in future neuromorphic computing systems.
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