An Attention-augmented Deep Architecture for Hard Drive Status Monitoring in Large-scale Storage Systems

Ji Wang, Weidong Bao, Lei Zheng, Xiaomin Zhu, Philip S. Yu
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引用次数: 12

Abstract

Data centers equipped with large-scale storage systems are critical infrastructures in the era of big data. The enormous amount of hard drives in storage systems magnify the failure probability, which may cause tremendous loss for both data service users and providers. Despite a set of reactive fault-tolerant measures such as RAID, it is still a tough issue to enhance the reliability of large-scale storage systems. Proactive prediction is an effective method to avoid possible hard-drive failures in advance. A series of models based on the SMART statistics have been proposed to predict impending hard-drive failures. Nonetheless, there remain some serious yet unsolved challenges like the lack of explainability of prediction results. To address these issues, we carefully analyze a dataset collected from a real-world large-scale storage system and then design an attention-augmented deep architecture for hard-drive health status assessment and failure prediction. The deep architecture, composed of a feature integration layer, a temporal dependency extraction layer, an attention layer, and a classification layer, cannot only monitor the status of hard drives but also assist in failure cause diagnoses. The experiments based on real-world datasets show that the proposed deep architecture is able to assess the hard-drive status and predict the impending failures accurately. In addition, the experimental results demonstrate that the attention-augmented deep architecture can reveal the degradation progression of hard drives automatically and assist administrators in tracing the cause of hard drive failures.
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大型存储系统中硬盘状态监测的注意力增强深度体系结构
配备大规模存储系统的数据中心是大数据时代的关键基础设施。由于存储系统中硬盘数量庞大,故障率大大提高,可能会给数据服务用户和数据服务提供商带来巨大的损失。尽管有诸如RAID等一系列反应性容错措施,但提高大规模存储系统的可靠性仍然是一个棘手的问题。主动预测是提前避免硬盘故障的有效方法。提出了一系列基于SMART统计的模型来预测即将发生的硬盘故障。尽管如此,仍然存在一些严重的尚未解决的挑战,如缺乏预测结果的可解释性。为了解决这些问题,我们仔细分析了从现实世界的大型存储系统收集的数据集,然后设计了一个用于硬盘健康状态评估和故障预测的注意力增强深度架构。深层架构由特征集成层、时间依赖提取层、关注层和分类层组成,不仅可以监控硬盘状态,还可以辅助故障原因诊断。基于实际数据集的实验表明,所提出的深度架构能够准确地评估硬盘状态并预测即将发生的故障。此外,实验结果表明,注意力增强深度架构可以自动揭示硬盘的退化过程,并帮助管理员跟踪硬盘故障的原因。
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