Ensemble dependent matrix methodology for probabilistic-based fault-tolerant nanoscale circuit design

Huifei Rao; Jie Chen; Changhong Yu; Woon Tiong Ang; I. Chyn Wey; An Yeu Wu; Hong Zhao

doi:10.1109/iscas.2007.378023

Ensemble dependent matrix methodology for probabilistic-based fault-tolerant nanoscale circuit design

Huifei Rao^*, Jie Chen, Changhong Yu, Woon Tiong Ang, I. Chyn Wey, An Yeu Wu, Hong Zhao

^*Corresponding author for this work

Research output: Contribution to journal › Conference article › peer-review

7 Scopus citations

Abstract

Two probabilistic-based models, namely the Ensemble-Dependent Matrix model [1][3] and the Markov Random Field model [2], have been proposed to deal with faults in nanoscale system. The MRF design can provide excellent noise tolerance in nanoscale circuit design. However, it is complicated to be applied to model circuit behavior at system level. Ensemble dependent matrix methodology is more effective and suitable for CAD tools development and to optimize nanoscale circuit and system design. In this paper, we show that the ensemble-dependent matrices describe the actual circuit performances when signal errors are present. We then propose a new criterion to compare circuit error-tolerance capability. We also prove that the Matrix model and the Markov model converge when signals are digital

Original language	English
Article number	4253010
Pages (from-to)	1803-1806
Number of pages	4
Journal	Proceedings - IEEE International Symposium on Circuits and Systems
DOIs	https://doi.org/10.1109/iscas.2007.378023
State	Published - 2007
Externally published	Yes
Event	2007 IEEE International Symposium on Circuits and Systems, ISCAS 2007 - New Orleans, LA, United States Duration: 27 05 2007 → 30 05 2007

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title = "Ensemble dependent matrix methodology for probabilistic-based fault-tolerant nanoscale circuit design",

abstract = "Two probabilistic-based models, namely the Ensemble-Dependent Matrix model [1][3] and the Markov Random Field model [2], have been proposed to deal with faults in nanoscale system. The MRF design can provide excellent noise tolerance in nanoscale circuit design. However, it is complicated to be applied to model circuit behavior at system level. Ensemble dependent matrix methodology is more effective and suitable for CAD tools development and to optimize nanoscale circuit and system design. In this paper, we show that the ensemble-dependent matrices describe the actual circuit performances when signal errors are present. We then propose a new criterion to compare circuit error-tolerance capability. We also prove that the Matrix model and the Markov model converge when signals are digital",

author = "Huifei Rao and Jie Chen and Changhong Yu and Ang, {Woon Tiong} and Wey, {I. Chyn} and Wu, {An Yeu} and Hong Zhao",

year = "2007",

doi = "10.1109/iscas.2007.378023",

language = "英语",

pages = "1803--1806",

journal = "Proceedings - IEEE International Symposium on Circuits and Systems",

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note = "2007 IEEE International Symposium on Circuits and Systems, ISCAS 2007 ; Conference date: 27-05-2007 Through 30-05-2007",

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T1 - Ensemble dependent matrix methodology for probabilistic-based fault-tolerant nanoscale circuit design

AU - Rao, Huifei

AU - Chen, Jie

AU - Yu, Changhong

AU - Ang, Woon Tiong

AU - Wey, I. Chyn

AU - Wu, An Yeu

AU - Zhao, Hong

PY - 2007

Y1 - 2007

N2 - Two probabilistic-based models, namely the Ensemble-Dependent Matrix model [1][3] and the Markov Random Field model [2], have been proposed to deal with faults in nanoscale system. The MRF design can provide excellent noise tolerance in nanoscale circuit design. However, it is complicated to be applied to model circuit behavior at system level. Ensemble dependent matrix methodology is more effective and suitable for CAD tools development and to optimize nanoscale circuit and system design. In this paper, we show that the ensemble-dependent matrices describe the actual circuit performances when signal errors are present. We then propose a new criterion to compare circuit error-tolerance capability. We also prove that the Matrix model and the Markov model converge when signals are digital

AB - Two probabilistic-based models, namely the Ensemble-Dependent Matrix model [1][3] and the Markov Random Field model [2], have been proposed to deal with faults in nanoscale system. The MRF design can provide excellent noise tolerance in nanoscale circuit design. However, it is complicated to be applied to model circuit behavior at system level. Ensemble dependent matrix methodology is more effective and suitable for CAD tools development and to optimize nanoscale circuit and system design. In this paper, we show that the ensemble-dependent matrices describe the actual circuit performances when signal errors are present. We then propose a new criterion to compare circuit error-tolerance capability. We also prove that the Matrix model and the Markov model converge when signals are digital

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SP - 1803

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JO - Proceedings - IEEE International Symposium on Circuits and Systems

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ER -

Ensemble dependent matrix methodology for probabilistic-based fault-tolerant nanoscale circuit design

Abstract

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