Dynamic stability and noise margins of SRAM arrays in nanoscaled technologies

Adam Teman

doi:10.1109/FTFC.2014.6828617

Dynamic stability and noise margins of SRAM arrays in nanoscaled technologies

Adam Teman

Swiss Federal Institute of Technology Lausanne

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

5 Scopus citations

Abstract

SRAM stability is one of the primary bottlenecks of current VLSI system design, and the unequivocal supply voltage scaling limiter. Static noise margin metrics have long been the de-facto standard for measuring this stability and estimating the yield of SRAM arrays. However, in modern process technologies, under scaled supply voltages and increased process variations, these traditional metrics are no longer sufficient. Recent research has analyzed the dynamic behavior and stability of SRAM circuits, leading to dynamic stability metrics and dynamic noise margin definition. This paper provides a brief overview of the limitations of static noise margin metrics and the resulting dynamic stability and noise margin concepts that have been proposed to overcome them.

Original language	English
Title of host publication	2014 IEEE Faible Tension Faible Consommation, FTFC 2014
Publisher	IEEE Computer Society
ISBN (Print)	9781479937738
DOIs	https://doi.org/10.1109/FTFC.2014.6828617
State	Published - 2014
Externally published	Yes
Event	2014 IEEE Faible Tension Faible Consommation, FTFC 2014 - Monaco, Monaco Duration: 4 May 2014 → 6 May 2014

Publication series

Name	2014 IEEE Faible Tension Faible Consommation, FTFC 2014

Conference

Conference	2014 IEEE Faible Tension Faible Consommation, FTFC 2014
Country/Territory	Monaco
City	Monaco
Period	4/05/14 → 6/05/14

Keywords

Dynamic Noise Margin
Phase Portrait
SRAM
Separatrix
Stability Analysis
Static Noise Margin

Access to Document

10.1109/FTFC.2014.6828617

Cite this

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abstract = "SRAM stability is one of the primary bottlenecks of current VLSI system design, and the unequivocal supply voltage scaling limiter. Static noise margin metrics have long been the de-facto standard for measuring this stability and estimating the yield of SRAM arrays. However, in modern process technologies, under scaled supply voltages and increased process variations, these traditional metrics are no longer sufficient. Recent research has analyzed the dynamic behavior and stability of SRAM circuits, leading to dynamic stability metrics and dynamic noise margin definition. This paper provides a brief overview of the limitations of static noise margin metrics and the resulting dynamic stability and noise margin concepts that have been proposed to overcome them.",

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booktitle = "2014 IEEE Faible Tension Faible Consommation, FTFC 2014",

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AB - SRAM stability is one of the primary bottlenecks of current VLSI system design, and the unequivocal supply voltage scaling limiter. Static noise margin metrics have long been the de-facto standard for measuring this stability and estimating the yield of SRAM arrays. However, in modern process technologies, under scaled supply voltages and increased process variations, these traditional metrics are no longer sufficient. Recent research has analyzed the dynamic behavior and stability of SRAM circuits, leading to dynamic stability metrics and dynamic noise margin definition. This paper provides a brief overview of the limitations of static noise margin metrics and the resulting dynamic stability and noise margin concepts that have been proposed to overcome them.

KW - Dynamic Noise Margin

KW - Phase Portrait

KW - SRAM

KW - Separatrix

KW - Stability Analysis

KW - Static Noise Margin

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Dynamic stability and noise margins of SRAM arrays in nanoscaled technologies

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Keywords

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