利用内置自修复技术提高内存产量和修复率的方案

2014 Innovative Applications of Computational Intelligence on Power, Energy and Controls with their impact on Humanity (CIPECH) Pub Date : 2014-11-01 DOI:10.1109/CIPECH.2014.7019092

Jyotika, Balwinder Singh

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引用次数: 1

摘要

存储器是每个计算系统的重要组成部分。在 SOC 中，嵌入式存储器占芯片总面积的 90% 至 92%（ITRS，2009 年），这意味着存储器密度高于逻辑密度。因此，存储器的测试和诊断是 SOC 中的重要问题。存储器的良品率受存储器故障的影响，而存储器故障也会影响 SOC 的良品率。内置自修复技术用于修复嵌入式存储器。内置自修复技术通过使用各种技术（如 1-D 冗余和 2-D 冗余）来提高系统的良品率。测试、冗余分析和修复交付是内存修复的三个基本步骤。内置冗余算法（BIRA）用于实现内置自修复（BISR）。

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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Memory yield and repair rate improvement scheme using built in self repair techniques

Memory is an important part of every computing system. In SOC, 90 to 92% of the total chip area is covered by embedded memories (ITRS 2009) and that means memory density is higher than the logic density. Therefore testing and diagnosis of memories are important issues in the SOCs. Yield of memory is affected by the faults present in memory which also affects the yield of SOC. Built in self-repair techniques are used to repair the embedded memories. Built in self-repair techniques are used for the better yield of the system by using various techniques like 1-D Redundancy and 2-D Redundancy. Test, Redundancy analysis, Repair delivery are the three basic steps for the memory repair. A built in redundancy algorithms (BIRA) are used to implement built in self-repair (BISR).

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2014 Innovative Applications of Computational Intelligence on Power, Energy and Controls with their impact on Humanity (CIPECH)

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