A cross-layer technology-based study of how memory errors impact system resilience

Veit B. Kleeberger; Christina Gimmler-Dumont; Christian Weis; Andreas Herkersdorf; Daniel Mueller-Gritschneder; Sani R. Nassif; Ulf Schlichtmann; Norbert Wehn

doi:10.1109/MM.2013.67

A cross-layer technology-based study of how memory errors impact system resilience

Veit B. Kleeberger, Christina Gimmler-Dumont, Christian Weis, Andreas Herkersdorf, Daniel Mueller-Gritschneder, Sani R. Nassif, Ulf Schlichtmann, Norbert Wehn

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

18 Scopus citations

Abstract

Highly scaled technologies at and beyond the 22-nm node exhibit increased sensitivity to various scaling-related problems that conspire to reduce the overall reliability of integrated circuits and systems. In prior technology nodes, the assumption was that manufacturing technology was responsible for ensuring device reliability. This basic assumption is no longer tenable. Trying to contain reliability problems purely at the technology level would cause prohibitive increases in power consumption. Thus, a cross-layer approach is required, which spreads the burden of ensuring resilience across multiple levels of the design hierarchy. This article illustrates a methodology for dealing with scaling-related problems via two case studies that link models of low-level technology-related problems to system behavior.

Original language	English
Article number	6527887
Pages (from-to)	46-55
Number of pages	10
Journal	IEEE Micro
Volume	33
Issue number	4
DOIs	https://doi.org/10.1109/MM.2013.67
State	Published - 2013

Keywords

computer architecture
cross-layer approach
design hierarchy
performance and reliability
scaled technologies
semiconductor memories
technology nodes

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10.1109/MM.2013.67

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abstract = "Highly scaled technologies at and beyond the 22-nm node exhibit increased sensitivity to various scaling-related problems that conspire to reduce the overall reliability of integrated circuits and systems. In prior technology nodes, the assumption was that manufacturing technology was responsible for ensuring device reliability. This basic assumption is no longer tenable. Trying to contain reliability problems purely at the technology level would cause prohibitive increases in power consumption. Thus, a cross-layer approach is required, which spreads the burden of ensuring resilience across multiple levels of the design hierarchy. This article illustrates a methodology for dealing with scaling-related problems via two case studies that link models of low-level technology-related problems to system behavior.",

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AU - Wehn, Norbert

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A cross-layer technology-based study of how memory errors impact system resilience

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