Reliability-aware energy management for hybrid storage systems

2011 IEEE 27th Symposium on Mass Storage Systems and Technologies (MSST) Pub Date : 2011-05-23 DOI:10.1109/MSST.2011.5937221

Wes Felter, A. Hylick, J. Carter

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引用次数: 13

Abstract

Modern disk-based storage systems are not energy proportional, because disks consume almost as much power when idle (but spinning) as they do when actively accessing data. We combine a power-aware, solid-state (flash) cache and a reliability-aware disk spindown mechanism to significantly improve storage energy proportionality without hurting disk reliability, data integrity, or performance. We evaluated the resulting power- and reliability-aware hybrid flash-disk RAID storage array and found that it reduces energy consumption by 85% compared to a similar-cost, similar-performance typical configuration of all SAS drives that are never spun down. Our design also achieves almost 50% energy savings compared to hybrid flash-disk systems tuned for performance or that do not take full advantage of opportunities for safe spindown. Further, unlike most previous work that exploits spindown to save energy, we limit the rate at which disks are spun down to avoid premature mechanical failures, whereas reliability-unaware spindown algorithms can exceed manufacturer waranteed lifetime spindown limits in as little as one year.

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基于可靠性的混合存储系统能量管理

现代基于磁盘的存储系统不是按能量比例计算的，因为磁盘在空闲(但旋转)时消耗的能量几乎与主动访问数据时消耗的能量一样多。我们结合了电源感知、固态(闪存)缓存和可靠性感知的磁盘休眠机制，在不损害磁盘可靠性、数据完整性或性能的情况下显著提高了存储能量的比例。我们对由此产生的具有功耗和可靠性意识的混合闪存盘RAID存储阵列进行了评估，发现与所有SAS驱动器的类似成本、类似性能的典型配置相比，它将能耗降低了85%。与混合闪存盘系统相比，我们的设计还实现了近50%的节能，这些系统对性能进行了调整，或者没有充分利用安全停机的机会。此外，与之前大多数利用自旋降来节省能源的工作不同，我们限制了磁盘的自旋降速率，以避免过早的机械故障，而不知道可靠性的自旋降算法可以在短短一年内超过制造商保证的寿命自旋降极限。

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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2011 IEEE 27th Symposium on Mass Storage Systems and Technologies (MSST)

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