FTSPM:一种容错的暂存存储器

2013 43rd Annual IEEE/IFIP International Conference on Dependable Systems and Networks (DSN) Pub Date : 2013-06-24 DOI:10.1109/DSN.2013.6575351

Amir Mahdi Hosseini Monazzah, Hamed Farbeh, S. Miremadi, M. Fazeli, H. Asadi

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引用次数: 31

摘要

ScratchPad Memory (SPM)是大多数现代嵌入式处理器的重要组成部分。在安全关键型应用程序中使用嵌入式处理器意味着在SPM的设计中包括容错性。本文提出了一种将多优先级映射算法与混合SPM结构相结合的FTSPM方法。提出的结构将SPM分为三部分:1)一个部分配备非易失性存储器(Non-Volatile Memory, NVM)，它可以抵抗软错误，2)一个部分配备纠错码，3)一个部分配备奇偶校验。本文提出的映射算法负责将程序块根据漏洞级别在上述三个部分之间进行分配。仿真结果表明，与纯基于sram的SPM相比，FTSPM将SPM漏洞减少了约7倍。此外，该方法的动态能量消耗比基于nvm的纯SPM和基于sram的纯SPM分别低77%和47%。

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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FTSPM: A Fault-Tolerant ScratchPad Memory

ScratchPad Memory (SPM) is an important part of most modern embedded processors. The use of embedded processors in safety-critical applications implies including fault tolerance in the design of SPM. This paper proposes a method, called FTSPM, which integrates a multi-priority mapping algorithm with a hybrid SPM structure. The proposed structure divides SPM into three parts: 1) a part is equipped with Non-Volatile Memory (NVM) which is immune against soft errors, 2) a part is equipped with Error-Correcting Code, and 3) a part is equipped with parity. The proposed mapping algorithm is responsible to distribute the program blocks among the above three parts with regards to their vulnerability level. The simulation results demonstrate that the FTSPM reduces the SPM vulnerability by about 7x in comparison to a pure SRAM-based SPM. In addition, the dynamic energy consumption of the proposed method is 77% and 47% less than that of a pure NVM-based SPM and a pure SRAM-based SPM, respectively.

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来源期刊

2013 43rd Annual IEEE/IFIP International Conference on Dependable Systems and Networks (DSN)

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