Low-Temperature Fabrication of Spiking Soma Circuits Using Nanocrystalline-Silicon TFTs

Anand Subramaniam; Kurtis D. Cantley; Harvey J. Stiegler; Richard A. Chapman; Eric M. Vogel

Low-Temperature Fabrication of Spiking Soma Circuits Using Nanocrystalline-Silicon TFTs

Anand Subramaniam, Kurtis D. Cantley, Harvey J. Stiegler, Richard A. Chapman, Eric M. Vogel

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Spiking neuron circuits consisting of ambipolar nanocrystalline-silicon (nc-Si) thin-film transistors (TFTs) have been fabricated using low temperature processing conditions (maximum of 250 °C) that allow the use of flexible substrates. These circuits display behaviors commonly observed in biological neurons such as millisecond spike duration, nonlinear frequency--current relationship, and spike frequency adaptation. The maximum drive capacity of a simple soma circuit was estimated to be approximately 9200 synapses. The effect of bias stress-induced threshold voltage degradation of component nc-Si TFTs on the spike frequency of soma circuits is explored. The measured power consumption of the circuit when spiking at 100 Hz was approximately 12 nW. Finally, the power consumption of the soma circuits at different spiking conditions and its implications on a large-scale system are discussed. The fabricated circuits can be employed as part of a compact multilayer learning network.

Original language	American English
Journal	IEEE Transactions on Neural Networks and Learning Systems
Volume	PP
Issue number	99
State	Published - 30 Apr 2013
Externally published	Yes

Keywords

Frequency--current curve
nanocrystalline silicon (nc-Si)
soma circuits
thin-film transistor (TFT)

EGS Disciplines

Electrical and Computer Engineering

Cite this

@article{92750abf2e364358baaf12d604aa47f1,

title = "Low-Temperature Fabrication of Spiking Soma Circuits Using Nanocrystalline-Silicon TFTs",

abstract = " Spiking neuron circuits consisting of ambipolar nanocrystalline-silicon (nc-Si) thin-film transistors (TFTs) have been fabricated using low temperature processing conditions (maximum of 250 °C) that allow the use of flexible substrates. These circuits display behaviors commonly observed in biological neurons such as millisecond spike duration, nonlinear frequency--current relationship, and spike frequency adaptation. The maximum drive capacity of a simple soma circuit was estimated to be approximately 9200 synapses. The effect of bias stress-induced threshold voltage degradation of component nc-Si TFTs on the spike frequency of soma circuits is explored. The measured power consumption of the circuit when spiking at 100 Hz was approximately 12 nW. Finally, the power consumption of the soma circuits at different spiking conditions and its implications on a large-scale system are discussed. The fabricated circuits can be employed as part of a compact multilayer learning network.",

keywords = "Frequency--current curve, nanocrystalline silicon (nc-Si), soma circuits, thin-film transistor (TFT)",

author = "Anand Subramaniam and Cantley, {Kurtis D.} and Stiegler, {Harvey J.} and Chapman, {Richard A.} and Vogel, {Eric M.}",

year = "2013",

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day = "30",

language = "American English",

volume = "PP",

number = "99",

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TY - JOUR

T1 - Low-Temperature Fabrication of Spiking Soma Circuits Using Nanocrystalline-Silicon TFTs

AU - Subramaniam, Anand

AU - Cantley, Kurtis D.

AU - Stiegler, Harvey J.

AU - Chapman, Richard A.

AU - Vogel, Eric M.

PY - 2013/4/30

Y1 - 2013/4/30

N2 - Spiking neuron circuits consisting of ambipolar nanocrystalline-silicon (nc-Si) thin-film transistors (TFTs) have been fabricated using low temperature processing conditions (maximum of 250 °C) that allow the use of flexible substrates. These circuits display behaviors commonly observed in biological neurons such as millisecond spike duration, nonlinear frequency--current relationship, and spike frequency adaptation. The maximum drive capacity of a simple soma circuit was estimated to be approximately 9200 synapses. The effect of bias stress-induced threshold voltage degradation of component nc-Si TFTs on the spike frequency of soma circuits is explored. The measured power consumption of the circuit when spiking at 100 Hz was approximately 12 nW. Finally, the power consumption of the soma circuits at different spiking conditions and its implications on a large-scale system are discussed. The fabricated circuits can be employed as part of a compact multilayer learning network.

AB - Spiking neuron circuits consisting of ambipolar nanocrystalline-silicon (nc-Si) thin-film transistors (TFTs) have been fabricated using low temperature processing conditions (maximum of 250 °C) that allow the use of flexible substrates. These circuits display behaviors commonly observed in biological neurons such as millisecond spike duration, nonlinear frequency--current relationship, and spike frequency adaptation. The maximum drive capacity of a simple soma circuit was estimated to be approximately 9200 synapses. The effect of bias stress-induced threshold voltage degradation of component nc-Si TFTs on the spike frequency of soma circuits is explored. The measured power consumption of the circuit when spiking at 100 Hz was approximately 12 nW. Finally, the power consumption of the soma circuits at different spiking conditions and its implications on a large-scale system are discussed. The fabricated circuits can be employed as part of a compact multilayer learning network.

KW - Frequency--current curve

KW - nanocrystalline silicon (nc-Si)

KW - soma circuits

KW - thin-film transistor (TFT)

UR - http://dx.doi.org/10.1109/TNNLS.2013.2256926

M3 - Article

VL - PP

JO - IEEE Transactions on Neural Networks and Learning Systems

JF - IEEE Transactions on Neural Networks and Learning Systems

IS - 99

ER -

Low-Temperature Fabrication of Spiking Soma Circuits Using Nanocrystalline-Silicon TFTs

Abstract

Keywords

EGS Disciplines

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