A Split-Gate Positive Feedback Device With an Integrate-and-Fire Capability for a High-Density Low-Power Neuron Circuit

Choi, Kyungmin; Woo, Sung Yun; Kang, Won-Mook; Soo-Chang, Lee; Kim, Chul-Heung; Bae, Jong-Ho; Lim, Suhwan; Lee, Jong-Ho

doi:10.3389/fnins.2018.00704

Cited by 32 publications

(33 citation statements)

References 41 publications

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“…Though a high VG is applied to the PF neuron device, the ton of the PF neuron device can be delayed due to parasitic capacitors of metal pads and measuring equipment. [27]. In this case, the tons of the PF neuron device in Fig.…”

Section: Siomentioning

confidence: 99%

Low-Power and High-Density Neuron Device for Simultaneous Processing of Excitatory and Inhibitory Signals in Neuromorphic Systems

et al. 2020

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A positive-feedback (PF) neuron device capable of threshold tuning and simultaneously processing excitatory (G +) and inhibitory (G-) signals is experimentally demonstrated to replace conventional neuron circuits, for the first time. Thanks to the PF operation, the PF neuron device with steep switching characteristics can implement integrate-and-fire (IF) function of neurons with low-energy consumption. The structure of the PF neuron device efficiently merges a gated PNPN diode and a single MOSFET. Integrateand-fire (IF) operation with steep subthreshold swing (SS < 1 mV/dec) is experimentally implemented by carriers accumulated in an n floating body of the PF neuron device. The carriers accumulated in the n floating body are discharged by an inhibitory signal applied to the merged FET. Moreover, the threshold voltage (Vth) of the proposed PF neuron is controlled by using a charge storage layer. The low-energy consuming PF neuron circuit (~ 0.62 pJ/spike) consists of one PF device and only five MOSFETs for the IF and reset operation. In a high-level system simulation, a deep-spiking neural network (D-SNN) based on PF neurons with four hidden layers (1024 neurons in each layer) shows high-accuracy (98.55%) during a MNIST classification task. The PF neuron device provides a viable solution for high-density and low-energy neuromorphic systems.

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Section: Siomentioning

confidence: 99%

Low-Power and High-Density Neuron Device for Simultaneous Processing of Excitatory and Inhibitory Signals in Neuromorphic Systems

et al. 2020

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“…Therefore, the proposed neuron circuit can eliminate the accuracy degradation introduced by the process variation without any CMOS overhead. In addition, the PF device based on a gated-thyristor has a super-steep subthreshold swing (SS) [21]- [23]. Finally, we show that the proposed neuron circuit with the PF device significantly reduces the off-state current of a neuron circuit compared to a neuron circuit with the conventional MOSFET device, thanks to the super-steep SS characteristics of the PF device.…”

Section: Introductionmentioning

confidence: 90%

Low-Power Binary Neuron Circuit With Adjustable Threshold for Binary Neural Networks Using NAND Flash Memory

2020

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Recent studies have demonstrated that binary neural networks (BNN) could achieve a satisfying inference accuracy on representative image datasets. BNN conducts XNOR and bit-counting operations instead of high-precision vector-matrix multiplication (VMM), significantly reducing the memory storage. In this work, an analog bit-counting scheme is proposed to decrease the burden of neuron circuits with a synaptic architecture utilizing NAND flash memory. A novel binary neuron circuit with a double-gate positive feedback (PF) device is demonstrated to replace the sense amplifier, adder, and comparator, thereby reducing the burden of the complementary metal-oxide semiconductor (CMOS) circuits and power consumption. By using the double-gate PF device, the threshold voltage of the neuron circuits can be adaptively matched to the threshold value in the algorithms eliminating the accuracy degradation introduced by the process variation. Thanks to the super-steep SS characteristics of the PF device, the proposed neuron circuit with the PF device has an off-state current of 1 pA, representing 10 5 times improvement compared to the neuron circuit with a conventional metal-oxide-semiconductor field effect transistor (MOSFET) device. A system simulation of a hardware-based BNN shows that the lowvariance conductance distribution (8.4 %) of the synaptic device and the adjustable threshold of the neuron circuit implement a highly efficient BNN with a high inference accuracy.

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“…In Table 1 , the CMOS, floating-gate FET and FBFET neuron circuits reported by other research groups require 5–23 elements with capacitors, and more than 1–10 external bias lines which require extra peripheral circuit for generating bias voltages, causing these neuron circuits to consume high power and energy ( Indiveri et al, 2006 ; Kornijcuk et al, 2016 ; Choi et al, 2018 ; Kwon et al, 2018 ; Kim et al, 2019 ; Wang and Khan, 2019 ; Zhang and Wijekoon, 2019 ; Chavan et al, 2020 ; Woo et al, 2020 ). The FBFET neuron circuit has relatively low energy consumption compared to others except ours, but this neuron circuit requires extra peripheral circuits for generating voltage bias and controllers for the I&F operation ( Choi et al, 2018 ; Kwon et al, 2018 ; Woo et al, 2020 ). The PDSOI MOS-based neuron circuit also requires an external reset circuit applied with changeable gate voltage to reset the membrane potential ( Chavan et al, 2020 ).…”

Section: Proposed Iandf Neuron Circuitmentioning

confidence: 99%

“…Neuromorphic computing architectures mimicking the human brain have been used to perform pattern recognition, classification, and perception to overcome the crucial issue of power consumption faced by Von-Neumann computing architectures while processing complex data and information ( Chu et al, 2014 ; Merolla et al, 2014 ; Srinivasan et al, 2017 ). Despite their advantages over Von-Neumann computing architectures in terms of energy efficiency, neuron circuits, driven by spiking neural networks (SNNs), still need more power for their integrate-and-fire (I&F) operations than biological neurons ( Choi et al, 2018 ). For most neuron circuits, particularly those using complementary metal-oxide semiconductor (CMOS), feedback field-effect-transistor (FBFET), and floating gate FET (FGFET) ( Indiveri et al, 2006 ; Kornijcuk et al, 2016 ; Choi et al, 2018 ; Kwon et al, 2018 ; Kim et al, 2019 ; Wang and Khan, 2019 ; Zhang and Wijekoon, 2019 ; Chavan et al, 2020 ; Woo et al, 2020 ), the presence of numerous transistors and external bias lines result in relatively high power consumption for the I&F operations.…”

Section: Introductionmentioning

confidence: 99%

“…Despite their advantages over Von-Neumann computing architectures in terms of energy efficiency, neuron circuits, driven by spiking neural networks (SNNs), still need more power for their integrate-and-fire (I&F) operations than biological neurons ( Choi et al, 2018 ). For most neuron circuits, particularly those using complementary metal-oxide semiconductor (CMOS), feedback field-effect-transistor (FBFET), and floating gate FET (FGFET) ( Indiveri et al, 2006 ; Kornijcuk et al, 2016 ; Choi et al, 2018 ; Kwon et al, 2018 ; Kim et al, 2019 ; Wang and Khan, 2019 ; Zhang and Wijekoon, 2019 ; Chavan et al, 2020 ; Woo et al, 2020 ), the presence of numerous transistors and external bias lines result in relatively high power consumption for the I&F operations. Thus, for energy-efficient neuron circuits, suppression in numbers of transistors, absence of external bias lines, and use of steep switching devices with extremely low subthreshold swings ( SS s) are needed ( Abbott, 1999 ; Izhikevich, 2003 ; Cheung, 2010 ); the steep switching devices are crucially necessary for a substantial reduction in power consumption of neuron circuits.…”

Section: Introductionmentioning

confidence: 99%

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Integrate-and-Fire Neuron Circuit Without External Bias Voltages

et al. 2021

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In this study, we propose an integrate-and-fire (I&F) neuron circuit using a p-n-p-n diode that utilizes a latch-up phenomenon and investigate the I&F operation without external bias voltages using mixed-mode technology computer-aided design (TCAD) simulations. The neuron circuit composed of one p-n-p-n diode, three MOSFETs, and a capacitor operates with no external bias lines, and its I&F operation has an energy consumption of 0.59 fJ with an energy efficiency of 96.3% per spike. The presented neuron circuit is superior in terms of structural simplicity, number of external bias lines, and energy efficiency in comparison with that constructed with only MOSFETs. Moreover, the neuron circuit exhibits the features of controlling the firing frequency through the amplitude and time width of the synaptic pulse despite of the reduced number of the components and no external bias lines.

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A Split-Gate Positive Feedback Device With an Integrate-and-Fire Capability for a High-Density Low-Power Neuron Circuit

Cited by 32 publications

References 41 publications

Low-Power and High-Density Neuron Device for Simultaneous Processing of Excitatory and Inhibitory Signals in Neuromorphic Systems

Low-Power and High-Density Neuron Device for Simultaneous Processing of Excitatory and Inhibitory Signals in Neuromorphic Systems

Low-Power Binary Neuron Circuit With Adjustable Threshold for Binary Neural Networks Using NAND Flash Memory

Integrate-and-Fire Neuron Circuit Without External Bias Voltages

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