Bubble Razor: An architecture-independent approach to timing-error detection and correction

2012 IEEE International Solid-State Circuits Conference Pub Date : 2012-04-03 DOI:10.1109/ISSCC.2012.6177103

Matthew R. Fojtik, D. Fick, Yejoong Kim, N. Pinckney, D. Harris, D. Blaauw, D. Sylvester

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引用次数: 94

Abstract

Several methods that eliminate timing margins by detecting and correcting transient delay errors have been proposed. These Razor-style systems replace critical flip-flops with ones that detect late arriving signals, and use architectural replay to correct errors. However, none of these methods have been applied to a complete commercial processor due to their architectural invasiveness. In addition, these Razor techniques introduce significant hold time constraints that are difficult to meet given worsening timing variability. To address these two issues we propose Bubble Razor (B-Razor), which uses a novel error-detection technique based on two-phase latch timing and a local replay mechanism that can be inserted automatically in any design. The error detec tion technique breaks the dependency between minimum delay and speculation window, restoring hold-time constraints to conventional values and allowing timing speculation of up to 100% of nominal delay. The large timing specula tion makes Bubble Razor especially applicable to low-voltage designs where tim ing variation grows exponentially.

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气泡剃刀:一种独立于体系结构的时间误差检测和校正方法

提出了几种通过检测和校正暂态延迟误差来消除时间余量的方法。这些剃刀式的系统将关键的触发器替换为检测延迟到达信号的触发器，并使用架构重放来纠正错误。然而，由于这些方法的架构侵入性，它们都没有应用于完整的商业处理器。此外，这些Razor技术引入了显著的保持时间限制，在时间变异性恶化的情况下很难满足这些限制。为了解决这两个问题，我们提出了气泡剃刀(B-Razor)，它使用了一种基于两相锁锁定时和可自动插入任何设计的本地重播机制的新型错误检测技术。错误检测技术打破了最小延迟和推测窗口之间的依赖关系，将保持时间限制恢复到传统值，并允许高达100%标称延迟的时间推测。大的定时推测使得气泡剃刀特别适用于定时变化呈指数增长的低压设计。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2012 IEEE International Solid-State Circuits Conference

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