A non-iterative continuous model for switching window computation with crosstalk noise

J. M. Wang; P. Chen; K. K. Muchherla; S. Yanamanamanda; O. Hafiz

doi:10.1016/j.mee.2006.02.013

A non-iterative continuous model for switching window computation with crosstalk noise

J. M. Wang, P. Chen, K. K. Muchherla, S. Yanamanamanda, O. Hafiz

Electrical and Computer Engineering

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

Abstract

Proper modeling of switching windows leads to a better estimate of the noise-induced delay variations. In this paper, we propose a new non-iterative continuous switching model. The proposed new model employs an ordering technique combined with the principle of superposition of linear circuits. The principle of superposition considers the impact of aggressors one after the other. The ordering technique avoids convergence and multiple solution issues in many practical cases. Our model surpasses the accuracy of the traditional discrete model and the speed of fixed point iteration method.

Original language	English (US)
Pages (from-to)	288-299
Number of pages	12
Journal	Microelectronic Engineering
Volume	84
Issue number	2
DOIs	https://doi.org/10.1016/j.mee.2006.02.013
State	Published - Feb 2007

Keywords

Crosstalk noise
Deep submicron
Non-iterative
Switch window

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Atomic and Molecular Physics, and Optics
Condensed Matter Physics
Surfaces, Coatings and Films
Electrical and Electronic Engineering

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10.1016/j.mee.2006.02.013

Cite this

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title = "A non-iterative continuous model for switching window computation with crosstalk noise",

abstract = "Proper modeling of switching windows leads to a better estimate of the noise-induced delay variations. In this paper, we propose a new non-iterative continuous switching model. The proposed new model employs an ordering technique combined with the principle of superposition of linear circuits. The principle of superposition considers the impact of aggressors one after the other. The ordering technique avoids convergence and multiple solution issues in many practical cases. Our model surpasses the accuracy of the traditional discrete model and the speed of fixed point iteration method.",

keywords = "Crosstalk noise, Deep submicron, Non-iterative, Switch window",

author = "Wang, {J. M.} and P. Chen and Muchherla, {K. K.} and S. Yanamanamanda and O. Hafiz",

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AU - Wang, J. M.

AU - Chen, P.

AU - Muchherla, K. K.

AU - Yanamanamanda, S.

AU - Hafiz, O.

PY - 2007/2

Y1 - 2007/2

N2 - Proper modeling of switching windows leads to a better estimate of the noise-induced delay variations. In this paper, we propose a new non-iterative continuous switching model. The proposed new model employs an ordering technique combined with the principle of superposition of linear circuits. The principle of superposition considers the impact of aggressors one after the other. The ordering technique avoids convergence and multiple solution issues in many practical cases. Our model surpasses the accuracy of the traditional discrete model and the speed of fixed point iteration method.

AB - Proper modeling of switching windows leads to a better estimate of the noise-induced delay variations. In this paper, we propose a new non-iterative continuous switching model. The proposed new model employs an ordering technique combined with the principle of superposition of linear circuits. The principle of superposition considers the impact of aggressors one after the other. The ordering technique avoids convergence and multiple solution issues in many practical cases. Our model surpasses the accuracy of the traditional discrete model and the speed of fixed point iteration method.

KW - Crosstalk noise

KW - Deep submicron

KW - Non-iterative

KW - Switch window

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JO - Microelectronic Engineering

JF - Microelectronic Engineering

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ER -

A non-iterative continuous model for switching window computation with crosstalk noise

Abstract

Keywords

ASJC Scopus subject areas

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