高缺陷密度技术中存储器内置自修复技术的评价

10th IEEE Pacific Rim International Symposium on Dependable Computing, 2004. Proceedings. Pub Date : 2004-03-03 DOI:10.1109/PRDC.2004.1276581

L. Anghel, Nadir Achouri, M. Nicolaidis

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引用次数: 10

摘要

近年来，内置自我修复记忆(BISR)越来越受到重视。新的容错方法是必须的，以应对日益增加的缺陷水平，影响当前和即将到来的纳米CMOS工艺生产的存储器。这一问题将随着纳米技术的发展而加剧，纳米技术的缺陷密度预计将达到比当前CMOS技术高几个数量级的水平。这项工作提出了BISR架构的面积成本和成品率的评估，以解决受高缺陷密度影响的存储器。在几种存储器上进行了统计故障注入仿真。结果表明，通过合理的硬件成本，BISR架构可以用于未来的高缺陷技术，提供接近100%的存储器成品率。

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Evaluation of memory built-in self repair techniques for high defect density technologies

Memory built in self repair (BISR) is gaining importance since several years. New fault tolerance approaches are mandatory to cope with increasing defect levels affecting memories produced with current and upcoming nanometric CMOS process. This problem will be exacerbated with nanotechnologies, where defect densities are predicted to reach levels that are several orders of magnitude higher than in current CMOS technologies. This work presents an evaluation of the area cost and yield of BISR architectures addressing memories affected by high defect densities. Statistical fault injection simulations were conducted on several memories. The obtained results show that BISR architectures can be used for future high defect technologies, providing close to 100% memory yield, by means of reasonable hardware cost.

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10th IEEE Pacific Rim International Symposium on Dependable Computing, 2004. Proceedings.

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