CrossNets: High‐Performance Neuromorphic Architectures for CMOL Circuits

Likharev, K. K.; Mayr, Andreas; Muckra, Ibrahim; Türel, Özgür

doi:10.1196/annals.1292.010

Cited by 101 publications

(92 citation statements)

References 69 publications

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“…For example, one can use the formulas to estimate conducting channel dimensions given particular I-V characteristics for unipolar and certain bipolar memristive devices. Likewise, the results can be directly applied to cells in crossbar digital memories and other circuits based on resistive switching devices [14,[20][21][22]. Fig.…”

Section: Introductionmentioning

confidence: 99%

Intrinsic constrains on thermally-assisted memristive switching

Strukov

Williams

2011

Appl. Phys. A

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We derived analytical formulas to estimate the effective thermal resistance of a metallic cylinder subjected to Joule heating, surrounded by an insulator and bounded by two constant temperature planes in order to estimate the temperature of the hottest point of the system. These solutions are especially relevant for modeling unipolar resistive switches (or memristive devices), and they provide insight into the performance tradeoffs for a thermally driven reset transition. In particular, our results indicate that a minimum current of 1 µA is required to successfully reset a unipolar switch, even under the most favorable conditions.

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Section: Introductionmentioning

confidence: 99%

Intrinsic constrains on thermally-assisted memristive switching

Strukov

Williams

2011

Appl. Phys. A

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confidence: 99%

Stochastic resonance in an ensemble of single-electron neuromorphic devices and its application to competitive neural networks

Oya

Asai

Amemiya

2007

Chaos, Solitons & Fractals

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Abstract-Neuromorphic computing based on singleelectron circuit technology is gaining prominence because of its massively increased computational efficiency and the increasing relevance of computer technology and nanotechnology [1,2]. The maximum impact of these technologies will be strongly felt when single-electron circuits based on fault-and noise-tolerant neural structures can operate at room temperature. In this paper, inspired by stochastic resonance (SR) in an ensemble of spiking neurons [3], we propose our design of a basic single-electron neural component and report how we examined its statistical results on a network.

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“…In our recent work [34] we have proved that, despite these limitations, CrossNets can be taught, by at least two different methods, to perform virtually all the major functions demonstrated earlier with usual neural networks, including the corrupted pattern restoration in the recurrent quasi-Hopfield mode and pattern classification in the feedforward MLP mode. The importance of this result is in the CrossNet's potential unparalleled density and speed [11,34]: for realistic parameters, the cell density may exceed that of cerebral cortex (above 10 7 cells per cm 2 ), while the average cell-to-cell communication delay may be as low as ~10 ns (i.e., about six orders of magnitude lower than that in the brain), at acceptable power. Even putting aside the exciting long-term prospects of creating high-speed artificial brain-like systems [34], CMOL CrossNet chips of modest size might be used for important present-day problems, e.g., online recognition of a person in a large crowd [35].…”

Section: Mixed-signal Neuromorphic Circuitsmentioning

confidence: 99%

“…32). We have explored a specific architecture of such networks, called Distributed Crossbar Networks ("CrossNets") [11,34], which are uniquely suitable for CMOL implementation.…”

Section: Mixed-signal Neuromorphic Circuitsmentioning

confidence: 99%

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CMOL: Second life for silicon?

Likharev

2008

Microelectronics Journal

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This report is a brief review of the recent work on architectures for the prospective hybrid CMOS/nanowire/ nanodevice ("CMOL") circuits including digital memories, reconfigurable Boolean-logic circuits, and mixed-signal neuromorphic networks. The basic idea of CMOL circuits is to combine the advantages of CMOS technology (including its flexibility and high fabrication yield) with the extremely high potential density of molecular-scale two-terminal nanodevices. Relatively large critical dimensions of CMOS components and the "bottom-up" approach to nanodevice fabrication may keep CMOL fabrication costs at affordable level. At the same time, the density of active devices in CMOL circuits may be as high as 10 12 cm 2 and that they may provide an unparalleled information processing performance, up to 10 20 operations per cm 2 per second, at manageable power consumption.

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CrossNets: High‐Performance Neuromorphic Architectures for CMOL Circuits

Cited by 101 publications

References 69 publications

Intrinsic constrains on thermally-assisted memristive switching

Intrinsic constrains on thermally-assisted memristive switching

Stochastic resonance in an ensemble of single-electron neuromorphic devices and its application to competitive neural networks

CMOL: Second life for silicon?

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