Module diversification: Fault tolerance and aging mitigation for runtime reconfigurable architectures

2013 IEEE International Test Conference (ITC) Pub Date : 2013-09-01 DOI:10.1109/TEST.2013.6651926

Hongyan Zhang, L. Bauer, M. Kochte, E. Schneider, Claus Braun, M. Imhof, H. Wunderlich, J. Henkel

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引用次数: 39

Abstract

Runtime reconfigurable architectures based on Field-Programmable Gate Arrays (FPGAs) are attractive for realizing complex applications. However, being manufactured in latest semiconductor process technologies, FPGAs are increasingly prone to aging effects, which reduce the reliability of such systems and must be tackled by aging mitigation and application of fault tolerance techniques. This paper presents module diversification, a novel design method that creates different configurations for runtime reconfigurable modules. Our method provides fault tolerance by creating the minimal number of configurations such that for any faulty Configurable Logic Block (CLB) there is at least one configuration that does not use that CLB. Additionally, we determine the fraction of time that each configuration should be used to balance the stress and to mitigate the aging process in FPGA-based runtime reconfigurable systems. The generated configurations significantly improve reliability by fault-tolerance and aging mitigation.

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模块多样化:运行时可重构架构的容错和老化缓解

基于现场可编程门阵列(fpga)的运行时可重构架构对于实现复杂应用具有很大的吸引力。然而，由于采用最新的半导体工艺技术制造，fpga越来越容易出现老化效应，这降低了系统的可靠性，必须通过老化缓解和容错技术的应用来解决。提出了一种新的模块多样化设计方法，为运行时可重构模块创建不同的配置。我们的方法通过创建最小数量的配置来提供容错性，这样对于任何有故障的可配置逻辑块(CLB)，至少有一个配置不使用该CLB。此外，我们还确定了在基于fpga的运行时可重构系统中，每种配置应该用于平衡压力和缓解老化过程的时间比例。生成的配置通过容错和老化缓解显著提高了可靠性。

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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2013 IEEE International Test Conference (ITC)

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