Coupling dynamics of Nb/Nb2O5 relaxation oscillators

Shuai Li; Xinjun Liu; Sanjoy Kumar Nandi; Dinesh Kumar Venkatachalam; Robert Glen Elliman

doi:10.1088/1361-6528/aa5de0

Coupling dynamics of Nb/Nb₂O₅ relaxation oscillators

Shuai Li, Xinjun Liu, Sanjoy Kumar Nandi, Dinesh Kumar Venkatachalam, Robert Glen Elliman

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

33 Citations (Scopus)

Abstract

The coupling dynamics of capacitively coupled Nb/Nb₂O₅ relaxation oscillators are shown to exhibit rich collective behaviour depending on the negative differential resistance response of the individual devices, the operating voltage and the coupling capacitance. These coupled oscillators are shown to exhibit stable frequency and phase locking states at source voltages as low as 2.2 V, with frequency control in the range from 0.85 to 16.2 MHz and frequency tunability of ∼8 MHz V^-1. The experimental realisation of such compact, scalable and low power coupled-oscillator systems is of particular significance for the development and implementation of large oscillator networks in non-Boolean computing architectures.

Original language	English
Article number	125201
Journal	Nanotechnology
Volume	28
Issue number	12
DOIs	https://doi.org/10.1088/1361-6528/aa5de0
Publication status	Published - 20 Feb 2017

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title = "Coupling dynamics of Nb/Nb2O5 relaxation oscillators",

abstract = "The coupling dynamics of capacitively coupled Nb/Nb2O5 relaxation oscillators are shown to exhibit rich collective behaviour depending on the negative differential resistance response of the individual devices, the operating voltage and the coupling capacitance. These coupled oscillators are shown to exhibit stable frequency and phase locking states at source voltages as low as 2.2 V, with frequency control in the range from 0.85 to 16.2 MHz and frequency tunability of ∼8 MHz V-1. The experimental realisation of such compact, scalable and low power coupled-oscillator systems is of particular significance for the development and implementation of large oscillator networks in non-Boolean computing architectures.",

keywords = "coupled oscillators, negative differential resistance, neuromorphic computing, niobium oxide, synchronisation, threshold switching",

author = "Shuai Li and Xinjun Liu and Nandi, {Sanjoy Kumar} and Venkatachalam, {Dinesh Kumar} and Elliman, {Robert Glen}",

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AU - Li, Shuai

AU - Liu, Xinjun

AU - Nandi, Sanjoy Kumar

AU - Venkatachalam, Dinesh Kumar

AU - Elliman, Robert Glen

PY - 2017/2/20

Y1 - 2017/2/20

N2 - The coupling dynamics of capacitively coupled Nb/Nb2O5 relaxation oscillators are shown to exhibit rich collective behaviour depending on the negative differential resistance response of the individual devices, the operating voltage and the coupling capacitance. These coupled oscillators are shown to exhibit stable frequency and phase locking states at source voltages as low as 2.2 V, with frequency control in the range from 0.85 to 16.2 MHz and frequency tunability of ∼8 MHz V-1. The experimental realisation of such compact, scalable and low power coupled-oscillator systems is of particular significance for the development and implementation of large oscillator networks in non-Boolean computing architectures.

AB - The coupling dynamics of capacitively coupled Nb/Nb2O5 relaxation oscillators are shown to exhibit rich collective behaviour depending on the negative differential resistance response of the individual devices, the operating voltage and the coupling capacitance. These coupled oscillators are shown to exhibit stable frequency and phase locking states at source voltages as low as 2.2 V, with frequency control in the range from 0.85 to 16.2 MHz and frequency tunability of ∼8 MHz V-1. The experimental realisation of such compact, scalable and low power coupled-oscillator systems is of particular significance for the development and implementation of large oscillator networks in non-Boolean computing architectures.

KW - coupled oscillators

KW - negative differential resistance

KW - neuromorphic computing

KW - niobium oxide

KW - synchronisation

KW - threshold switching

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VL - 28

JO - Nanotechnology

JF - Nanotechnology

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ER -

Coupling dynamics of Nb/Nb₂O₅ relaxation oscillators

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