Integration of Hard Repair Techniques with ECC for Enhancing Fabrication Yield and Reliability of Embedded Memories

2015 IEEE 24th Asian Test Symposium (ATS) Pub Date : 2015-11-22 DOI:10.1109/ATS.2015.16

Shyue-Kung Lu, Cheng-Ju Tsai, M. Hashizume

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引用次数: 2

Abstract

Error correction code (ECC) and hard repair (built-in self-repair) techniques by using redundancies have been widely used for improving the yield and reliability of memories. The target faults of these two schemes are soft errors and permanent faults, respectively. In recent works, there are also some techniques integrating ECC and BISR to deal with soft errors and hard defects simultaneously. However, this will compromise reliability since some of the ECC protection capability is used for repairing hard defects. To cure this dilemma, we propose an ECC-enhanced BISR (EBISR) technique which uses ECC to repair single permanent faults first and spares for the remaining faults in the production/power-on test and repair stage. However, techniques are proposed to maintain the original reliability during the on-line test and repair stage. We also propose the corresponding hardware architecture of the EBISR scheme. A simulator is implemented to evaluate the hardware overhead, repair rate, and reliability. Experimental results show that the proposed EBISR scheme can improve yield and reliability significantly with negligible hardware overhead.

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硬修复技术与ECC集成提高嵌入式存储器的成品率和可靠性

纠错码(ECC)和利用冗余的硬修复(内置自修复)技术已被广泛用于提高存储器的良率和可靠性。这两种方案的目标故障分别是软故障和永久故障。在最近的研究中，也出现了一些将ECC和BISR结合起来同时处理软错误和硬缺陷的技术。然而，这将损害可靠性，因为一些ECC保护能力用于修复硬缺陷。为了解决这一困境，我们提出了一种ECC增强的BISR (EBISR)技术，该技术首先使用ECC修复单个永久故障，并在生产/通电测试和修复阶段为剩余故障提供备件。然而，在在线测试和维修阶段，提出了保持原有可靠性的技术。提出了相应的EBISR方案的硬件结构。实现了一个模拟器来评估硬件开销、维修率和可靠性。实验结果表明，所提出的EBISR方案在硬件开销很小的情况下，可以显著提高良率和可靠性。

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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2015 IEEE 24th Asian Test Symposium (ATS)

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