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Journals & Magazines >IEEE Transactions on Circuits... >Volume: 70 Issue: 3

RRAM-Based Energy Efficient Scalable Integrate and Fire Neuron With Built-In Reset Circuit

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Ashvinikumar Dongre; Gaurav Trivedi
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Abstract:

In this brief, we propose a Resistive Random Access Memory (RRAM) based self-resetting Integrate and Fire ( \text{I}\&\text{F} ) neuron. The proposed neuron circuit doe...Show More

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Abstract:

In this brief, we propose a Resistive Random Access Memory (RRAM) based self-resetting Integrate and Fire ( \text{I}\&\text{F} ) neuron. The proposed neuron circuit does not require any external bias voltage and the integration of control unit required to reset RRAM into neuron circuit optimizes its overall power consumption. The neuron circuit proposed in this brief consists of two RRAMs for integrate and fire operations, whereas, pulse propogation and reset circuit consists of 22 CMOS transistors. It consumes 1.5~fJ per spike, which is 48% and 53% less than the recent neurons designed using, nanoscale FBFET and PDSOI-MOSFET, respectively. The operating frequency of proposed neuron ranges from 277~KHz to 03~MHz , which is at least 7.5% and 10% higher than the operating frequencies of above mentioned recent neurons, respectively. The inclusion of reset circuit into RRAM based neuron circuit enables the implementation of large scale spiking neural network (SNN), which makes it superior in terms of power and energy consumption.
Published in: IEEE Transactions on Circuits and Systems II: Express Briefs ( Volume: 70, Issue: 3, March 2023)
Page(s): 909 - 913
Date of Publication: 03 November 2022

ISSN Information:

DOI: 10.1109/TCSII.2022.3219203
Citations are not available for this document.
Contents

I. Introduction

A human brain is capable of performing compute intensive tasks, such as multi object recognition, reasoning and decision making etc., while consuming only of power [1]. A CPU recognising 1000 different objects consumes around of power [1]. As we know, in a human brain, there are around 1011 neurons, which are interconnected through approximately 1015 synapses [2]. Even with the latest technological advancements, Von-Neumann architecture based processor are getting limited to further optimize speed and power. This motivated researchers to explore other paradigms, such as neuromorphic computing, in which key algorithmic and computational features of the brain are emulated in silicon based hardware [2] to improve performance at the minimal power.

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Cites in Papers - IEEE (3)

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1.
SeyedMohamadJavad Motaman, Sarah Safura Sharifi, Yaser Michael Banad, "Enhancing Neuromorphic Computing: A High-Speed, Low-Power Integrate-and-Fire Neuron Circuit Utilizing Nanoscale Side-Contacted Field Effect Diode Technology", 2024 IEEE 67th International Midwest Symposium on Circuits and Systems (MWSCAS), pp.557-561, 2024.
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2.
Shafin Bin Hamid, Asir Intisar Khan, Huairuo Zhang, Albert V. Davydov, Eric Pop, "Low-Energy Spiking Neural Network Using Ge4Sb6Te7 Phase Change Memory Synapses", IEEE Electron Device Letters, vol.45, no.10, pp.1819-1822, 2024.
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Trung-Khanh Le, Trong-Tu Bui, Duc-Hung Le, "Modeling and Designing of an All-Digital Resonate-and-Fire Neuron Circuit", IEEE Access, vol.11, pp.62318-62336, 2023.
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Cites in Papers - Other Publishers (2)

1.
Xiaoqian Wu, Huaxiao Liu, Peng Wang, Lei Liu, Zhenxue He, "A Power Optimization Approach for Large-scale RM-TB Dual Logic Circuits Based on an Adaptive Multi-Task Intelligent Algorithm", ACM Transactions on Design Automation of Electronic Systems, 2024.
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BingJin Chen, Minggang Zeng, Khoong Hong Khoo, Debasis Das, Xuanyao Fong, Shunsuke Fukami, Sai Li, Weisheng Zhao, Stuart S.P. Parkin, S.N. Piramanayagam, Sze Ter Lim, "Spintronic devices for high-density memory and neuromorphic computing ? A review", Materials Today, 2023.
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