A built-in self-repair scheme for semiconductor memories with 2-d redundancy

International Test Conference, 2003. Proceedings. ITC 2003. Pub Date : 2003-11-06 DOI:10.1109/TEST.2003.1270863

Jin-Fu Li, J. Yeh, Rei-Fu Huang, Cheng-Wen Wu, Peir-Yuan Tsai, Archer Hsu, Eugene Chow

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引用次数: 66

Abstract

Embedded memories are among the most widely used cores in current system-on-chip (SOC) implementations. Memory cores usually occupy a significant portion of the chip area, and dominate the manufacturing yield of the chip. Efficient yield-enhancement techniques for embedded memories thus are important for SOC. In this paper we present a built-in self-repair (BISR) scheme for semiconductor memories with 2-D redundancy structures. The BISR design is composed of a built-in self-test (BIST) module and a built-in redundancy analysis (BIRA) module. Our BIST circuit supports three test modes: the 1) main memory testing, 2) spare memory testing, and 3) repair modes. The BIRA module executes the proposed redundancy analysis (RA) algorithm for RAM with a 2-D redundancy structure, i.e., spare rows and spare columns. The BIRA module also serves as the reconfiguration (address remapping) unit in the normal mode. Experimental results show that a high repair rate (i.e., the ratio of the number of repaired memories to the number of defective memories) is achieved with the proposed RA algorithm and BISR scheme. The BISR circuit has a low area overhead—about 4.6% for an 8K 64 SRAM.

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具有二维冗余的半导体存储器的内置自修复方案

嵌入式存储器是当前片上系统(SOC)实现中使用最广泛的核心之一。存储核心通常占据芯片面积的很大一部分，并主导着芯片的制造成品率。因此，嵌入式存储器的高效产量增强技术对SOC非常重要。本文提出了一种具有二维冗余结构的半导体存储器的内置自修复(BISR)方案。BISR设计由内置自检(BIST)模块和内置冗余分析(BIRA)模块组成。我们的BIST电路支持三种测试模式:1)主存储器测试，2)备用存储器测试和3)修复模式。BIRA模块对具有二维冗余结构(即备用行和备用列)的RAM执行所提出的冗余分析(RA)算法。在正常模式下，BIRA模块还可以作为重新配置(地址重新映射)单元。实验结果表明，本文提出的RA算法和BISR方案具有较高的修复率(即修复记忆数与缺陷记忆数之比)。BISR电路具有较低的面积开销-约为8k64 SRAM的4.6%。

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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International Test Conference, 2003. Proceedings. ITC 2003.

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