Design of Artificial Spiking Neuron with SiO2 Memristive Synapse to Demonstrate Neuron-Level Spike Timing Dependent Plasticity

机译：SiO 2 忆阻突触的人工加标神经元的设计，以证明神经元水平的穗定时依赖于可塑性

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In this paper, we report on the Design-Technology Co-optimization (DTCO) of an artificial spiking neuron utilizing a leaky-integrated-and-fire (LIF) circuit with a SiO₂ based sub-1.2V analog resistive random-access memory (ReRAM). The memristor integrated artificial neuron is capable of spike-timing-dependent plasticity (STDP), necessary for the implementation of Spiking Neural Networks (SNNs). In addition, for the first time, we designed and demonstrated a STDP circuit in conjunction with the SiO₂-based ReRAM that is capable of generating forward- and back-propagation signals. This allows for self-modulation of the synaptic weights through the Long-term potentiation (LTP) and Long-term depression (LTD) effect.

机译：在本文中，我们报告了利用带有SiO \ n _{2 \ n基于1.2V以下的模拟电阻式随机存取存储器（ReRAM）。忆阻器集成的人工神经元具有依赖于尖峰时序的可塑性（STDP），这对于实施尖峰神经网络（SNN）是必不可少的。此外，我们首次设计并演示了与SiO \ n _{2 \ n为基础的ReRAM，能够生成正向和反向传播信号。这允许通过长期增强（LTP）和长期抑制（LTD）效应对突触权重进行自我调节。}}

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来源
《2019 International Conference on IC Design and Technology》|2019年|1-3|共3页
会议地点 SuZhou(CN)
作者
Jessie Xuhua Niu; Hasita Veluri; Yida Li; Umesh Chand; Jin Feng Leong; Evgeny Zamburg; Maheswari Sivan; Aaron Voon-Yew Thean;
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作者单位

Department of Electrical and Computer Engineering, National University of Singapore, Singapore;

Department of Electrical and Computer Engineering, National University of Singapore, Singapore;

Department of Electrical and Computer Engineering, National University of Singapore, Singapore;

Department of Electrical and Computer Engineering, National University of Singapore, Singapore;

Department of Electrical and Computer Engineering, National University of Singapore, Singapore;

Department of Electrical and Computer Engineering, National University of Singapore, Singapore;

Department of Electrical and Computer Engineering, National University of Singapore, Singapore;

Department of Electrical and Computer Engineering, National University of Singapore, Singapore;

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原文格式 PDF
正文语种 eng
中图分类
关键词
Neurons; Synapses; Switches; Resistance; Neuromorphics; Firing; Timing;

机译：神经元;突触;开关;电阻;神经形态;射击;定时;;

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1. Spike-Timing-Dependent and Spike-Shape-Independent Plasticities with Dopamine-Like Modulation in Nanocomposite Memristive Synapses [J] . Kristina E. Nikiruy, Igor A. Surazhevsky, Vyacheslav A. Demin, Physica status solidi . 2020,第18期

机译：峰值定时依赖性和穗状形状无关的塑性，具有多巴胺样膜的多巴胺样调制膜
2. Artificial neuron operations and spike-timing-dependent plasticity using memristive devices for brain-inspired computing [J] . Marukame Takao, Nishi Yoshifumi, Yasuda Shin-ichi, Japanese journal of applied physics . 2018,第4S期

机译：使用忆阻器进行人工神经元运算和依赖于峰定时的可塑性，用于大脑启发式计算
3. A VLSI array of low-power spiking neurons and bistable synapses with spike-timing dependent plasticity [J] . Indiveri G., Chicca E., Douglas R. IEEE Transactions on Neural Networks . 2006,第1期

机译：低功率尖峰神经元和双稳态突触的VLSI阵列，具有依赖于尖峰时序的可塑性
4. Design of Artificial Spiking Neuron with SiO2 Memristive Synapse to Demonstrate Neuron-Level Spike Timing Dependent Plasticity [C] . Jessie Xuhua Niu, Hasita Veluri, Yida Li, International Conference on IC Design and Technology . 2019

机译：用SiO 2 膜突触的人工尖峰神经元设计展示神经元级尖峰定时依赖性可塑性
5. Analog Spiking Neural Network Implementing Spike Timing-Dependent Plasticity on 65 nm CMOS [D] . Vincent, Luke. 2021

机译：模拟尖峰神经网络在65nm CMOS上实施尖刺时序依赖性可塑性
6. Prostaglandin Signaling Governs Spike Timing-Dependent Plasticity at Sensory Synapses onto Mouse Spinal Projection Neurons [O] . Jie Li, Elizabeth Serafin, Mark L. Baccei 2018

机译：前列腺素信号传导在小鼠脊髓投射神经元的感觉突触上控制穗时间依赖的可塑性。
7. A VLSI array of low-power spiking neurons and bistable synapses with spike-timing dependent plasticity [O] . Indiveri G., Chicca Elisabetta, Douglas R. J. 2006

机译：低功率尖峰神经元和双稳态突触的VLSI阵列，具有依赖于尖峰时序的可塑性

Design of Artificial Spiking Neuron with SiO2 Memristive Synapse to Demonstrate Neuron-Level Spike Timing Dependent Plasticity

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