自愈异步电路的优化概念

T. Panhofer, W. Friesenbichler, M. Delvai
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引用次数: 11

摘要

减小特征尺寸和降低电源电压导致集成电路在生产和运行期间更容易出错。同时,对高可靠性的要求也越来越高。特别是对于任务时间长且无法修复的应用,需要复杂的容错机制,从而导致设计和系统成本的急剧增加。运行时重新配置似乎是获得能够处理这些挑战的电路的一种有前途的方法。在之前的论文中,我们提出了一种基于异步四态逻辑(FSL)和使用可重构电路元件(称为自愈细胞(SHCs))的自愈方法。这些shc允许绕过缺陷资源并从多个永久故障中恢复。虽然组合逻辑可以通过这种方式轻松地重新配置,但在异步管道中应用shc需要对握手信号进行特殊处理。在本文中,我们提出了一种自修复管道体系结构,并分析了不同的SHC体系结构在资源占用、容错和重构速度方面的特点。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Optimization concepts for self-healing asynchronous circuits
Decreasing feature size and lower supply voltage cause integrated circuits to be more error-prone, during production as well as during runtime. At the same time the demand for higher reliability is increasing. In particular for applications with long mission times and where no repair is possible, complex fault tolerance mechanisms are required, leading to a dramatic increase of design and system costs. Runtime reconfiguration seems to be a promising way to obtain a circuit which is able to handle these challenges. In previous papers we presented a self-healing approach based on asynchronous Four-State Logic (FSL) and using reconfigurable circuit elements, called Self-Healing Cells (SHCs). These SHCs allow to bypass defect resources and to recover from multiple permanent faults. While the combinational logic can be easily reconfigured this way, the application of SHCs in an asynchronous pipeline requires special treatment of the handshake signals. In this paper we present a self-healing pipeline architecture and analyse different SHC architectures with respect to resource occupation, fault tolerance and reconfiguration speed.
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