Peak-Power Aware Life-Time Reliability Improvement in Fault-Tolerant Mixed-Criticality Systems

IF 2.4 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Mozhgan Navardi;Behnaz Ranjbar;Nezam Rohbani;Alireza Ejlali;Akash Kumar
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引用次数: 2

Abstract

Mixed-Criticality Systems (MCSs) include tasks with multiple levels of criticality and different modes of operation. These systems bring benefits such as energy and resource saving while ensuring safe operation. However, management of available resources in order to achieve high utilization, low power consumption, and required reliability level is challenging in MCSs. In many cases, there is a trade-off between these goals. For instance, although using fault-tolerance techniques, such as replication, leads to improving the timing reliability, it increases power consumption and can threaten life-time reliability. In this work, we introduce an approach named ${\mathbf {L}}ife-time \,\,{\mathbf {P}}eak \,\,{\mathbf {P}}{ower~management~in}\,\,{\mathbf {M}}{ixed}-{\mathbf {C}}{riticality\,\, systems}$ (LPP-MC) to guarantee reliability, along with peak power reduction. This approach maps the tasks using a novel metric called Reliability-Power Metric (RPM). The LPP-MC approach uses this metric to balance the power consumption of different processor cores and to improve the life-time of a chip. Moreover, to guarantee the timing reliability of MCSs, a fault-tolerance technique, called task re-execution, is utilized in this approach. We evaluate the proposed approach by a real avionics task set, and various synthetic task sets. The experimental results show that the proposed approach mitigates the aging rate and reduces peak power by up to 20.6% and 17.6%, respectively, compared to state-of-the-art.
容错混合临界系统的峰值功率感知全寿命可靠性改进
混合临界系统(mcs)包括具有多个临界级别和不同运行模式的任务。这些系统在保证安全运行的同时,带来了节能、节约资源等效益。然而,管理可用资源以实现高利用率、低功耗和所需的可靠性水平对mcs来说是一个挑战。在许多情况下,这两个目标之间存在权衡。例如,尽管使用容错技术(如复制)可以提高定时可靠性,但它会增加功耗,并可能威胁到生命周期的可靠性。在这项工作中,我们引入了一种名为${\mathbf {L}} life -time \,\,{\mathbf {P}}eak \,\,{\mathbf {P}}{power ~management~ In}\,\,{\mathbf {M}}{ixed}-{\mathbf {C}}{criticality \,\, systems}$ (LPP-MC)的方法来保证可靠性,同时降低峰值功率。这种方法使用一种称为可靠性-功率度量(RPM)的新度量来映射任务。LPP-MC方法使用这个指标来平衡不同处理器内核的功耗,并提高芯片的使用寿命。此外,为了保证mcs的定时可靠性,该方法还采用了任务重执行的容错技术。我们通过一个真实的航电任务集和各种合成任务集来评估所提出的方法。实验结果表明,与现有方法相比,该方法可降低老化率20.6%,峰值功率降低17.6%。
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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