一种跨层的暂态故障在线自适应可靠性预测方法

Bahareh J. Farahani, S. Safari
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引用次数: 8

摘要

随着半导体工业向纳米领域迁移,处理器越来越容易受到瞬态故障的影响。此类故障通常源于粒子撞击引起的软错误或工艺、电压、温度和老化(PVTA)变化引起的时序违规。这些故障可以从电路级传播到应用程序级,并改变应用程序的正确执行输出。几代人以来,设计师都在构建高级的弹性,使得底层电路的细节成为可以忽略的抽象概念。本文认为,与以往只考虑架构脆弱性系数(AVF)作为指导容错技术的度量不同,应该考虑设计堆栈中从电路层到指令层和应用层的每个抽象层的脆弱性。本文提出了一种基于学习算法的在线跨层可靠性预测技术,该技术可以自适应地同时考虑较低层次和较高层次的细节来预测处理器的易感性。结果表明,该方法在SPEC2000基准测试中预测未来可靠性的平均误差为6%。与被动容错策略相比,我们的可靠性突发事件预测技术可以帮助主动容错技术更有效地维护可靠性约束。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A cross-layer approach to online adaptive reliability prediction of transient faults
As the semiconductor industry migrates into the nanometer regime, processors become increasingly susceptible to transient faults. Such faults usually stem either from soft errors due to particle strikes or timing violations due to Process, Voltage, Temperature, and Aging (PVTA) variations. These faults can propagate from circuit-level to application-level and alter the correct execution output of the application. For generations, designers build high-level resiliency such that the details of the underlying circuit are an abstraction that could be neglected. This paper argues that in contrast to the prior work, which only take into account Architectural Vulnerability Factor (AVF) as a measure to guide fault tolerant techniques, the vulnerability of each abstraction layer of design stack from circuit going up to instruction and application layers should be considered. This paper presents a novel online cross-layer reliability prediction technique based on learning algorithms which can anticipate the susceptibility of the processor considering both lower-level and higher-level details in an adaptive fashion. According to the results, the proposed technique can predict the future reliability with 6% error on average across SPEC2000 benchmarks. Our technique by forecasting the reliability emergencies can assist proactive fault tolerant techniques to maintain the reliability constraints more efficiently in comparison to reactive strategies.
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