硬件/软件容错，多任务模块化冗余

Proceedings. IEEE Symposium on Computers and Communications Pub Date : 1995-06-27 DOI:10.1109/SCAC.1995.523663

C. Fuhrman, S. Chutani, H. Nussbaumer

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引用次数: 12

摘要

n模块冗余(NMR)和n版本编程(NVP)是两种流行的容错技术，它们利用硬件和软件冗余来掩盖故障。冗余硬件用于提高容错性，而不是吞吐量。我们介绍了一种基于NMR和NVP的软硬件容错组合方案，该方案展示了冗余如何通过对多个任务的执行进行分组来提高吞吐量。我们的方案使用具有乐观执行策略的动态任务分配算法，其中任务执行的数量保持在产生无故障结果所需的最小值附近。对于同等的硬件和软件资源，所提出的方法在吞吐量和延迟方面的效率提高了50%到100%。

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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Hardware/software fault tolerance with multiple task modular redundancy

N-modular redundancy (NMR) and N-version programming (NVP) are two popular fault tolerance techniques in which hardware and software redundancy is exploited to mask faults. Redundant hardware is used to improve fault tolerance rather than throughput. We introduce a scheme for combined hardware-software fault tolerance derived from NMR and NVP that shows how redundancy can also be used to improve throughput by grouping the execution of several tasks. Our scheme uses a dynamic task allocation algorithm with an optimistic execution policy where the number of task executions is kept close to the minimum required to produce fault-free results. For equivalent hardware and software resources, the proposed method is 50% to 100% more efficient in terms of throughput and latency.

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