近阈值电压下可容错的末级缓存结构设计

Wei Liu; Zhigang Wei; Wei Du; Guangyi Cao; Wei Wang

doi:10.11999/JEIT170989

近阈值电压下可容错的末级缓存结构设计

Wei Liu^*
, Zhigang Wei
, Wei Du
, Guangyi Cao
, Wei Wang

^*此作品的通讯作者

Wuhan University of Technology
Hubei Key Laboratory of Transportation Internet of Things
Tongji University

科研成果: 期刊稿件 › 文章 › 同行评审

1 引用（Scopus）

摘要

Near-threshold voltage computing enables transistor voltage scaling to continue with Moore’s Law projection and dramatically improves power and energy efficiency. However, a great number of bit-cell errors occur in large SRAM structures, such as Last-Level Cache (LLC). A Fault-Tolerant LLC (FTLLC) design with conventional 6T SRAM cells is proposed to deal with a higher failure rate which is more than 1% at near-threshold voltage. FTLLC improves the reliability of data stored in Cache by correcting the single-error and compressing multi-errors in Cache entry. To validate the efficiency of FTLLC, FTLLC and prior works are implemented in gem5, and are simulated with SPEC CPU2006. The experiment shows that compared with Concertina at 650 mV, the performance of a 65 nm FTLLC with 4-Byte subblock size improves by 7.2% and the Cache capacity increases by 24.9%. Besides, the miss rate decreases by 58.2%, and there are little increases on area overhead and power consumption.

投稿的翻译标题	Fault-tolerant Last Level Cache Architecture Design at Near-threshold Voltage
源语言	繁体中文
页（从-至）	1759-1766
页数	8
期刊	Dianzi Yu Xinxi Xuebao/Journal of Electronics and Information Technology
卷	40
期	7
DOI	https://doi.org/10.11999/JEIT170989
出版状态	已出版 - 1 7月 2018
已对外发布	是

联合国可持续发展目标

此成果有助于实现下列可持续发展目标：

可持续发展目标 7 经济适用的清洁能源

关键词

Compression mechanism
Error correction code
Fault-tolerant Cache
Near-threshold voltage

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10.11999/JEIT170989

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链接到 Scopus 的出版物

引用此

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title = "近阈值电压下可容错的末级缓存结构设计",

abstract = "Near-threshold voltage computing enables transistor voltage scaling to continue with Moore{\textquoteright}s Law projection and dramatically improves power and energy efficiency. However, a great number of bit-cell errors occur in large SRAM structures, such as Last-Level Cache (LLC). A Fault-Tolerant LLC (FTLLC) design with conventional 6T SRAM cells is proposed to deal with a higher failure rate which is more than 1\% at near-threshold voltage. FTLLC improves the reliability of data stored in Cache by correcting the single-error and compressing multi-errors in Cache entry. To validate the efficiency of FTLLC, FTLLC and prior works are implemented in gem5, and are simulated with SPEC CPU2006. The experiment shows that compared with Concertina at 650 mV, the performance of a 65 nm FTLLC with 4-Byte subblock size improves by 7.2\% and the Cache capacity increases by 24.9\%. Besides, the miss rate decreases by 58.2\%, and there are little increases on area overhead and power consumption.",

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T1 - 近阈值电压下可容错的末级缓存结构设计

AU - Liu, Wei

AU - Wei, Zhigang

AU - Du, Wei

AU - Cao, Guangyi

AU - Wang, Wei

PY - 2018/7/1

Y1 - 2018/7/1

N2 - Near-threshold voltage computing enables transistor voltage scaling to continue with Moore’s Law projection and dramatically improves power and energy efficiency. However, a great number of bit-cell errors occur in large SRAM structures, such as Last-Level Cache (LLC). A Fault-Tolerant LLC (FTLLC) design with conventional 6T SRAM cells is proposed to deal with a higher failure rate which is more than 1% at near-threshold voltage. FTLLC improves the reliability of data stored in Cache by correcting the single-error and compressing multi-errors in Cache entry. To validate the efficiency of FTLLC, FTLLC and prior works are implemented in gem5, and are simulated with SPEC CPU2006. The experiment shows that compared with Concertina at 650 mV, the performance of a 65 nm FTLLC with 4-Byte subblock size improves by 7.2% and the Cache capacity increases by 24.9%. Besides, the miss rate decreases by 58.2%, and there are little increases on area overhead and power consumption.

AB - Near-threshold voltage computing enables transistor voltage scaling to continue with Moore’s Law projection and dramatically improves power and energy efficiency. However, a great number of bit-cell errors occur in large SRAM structures, such as Last-Level Cache (LLC). A Fault-Tolerant LLC (FTLLC) design with conventional 6T SRAM cells is proposed to deal with a higher failure rate which is more than 1% at near-threshold voltage. FTLLC improves the reliability of data stored in Cache by correcting the single-error and compressing multi-errors in Cache entry. To validate the efficiency of FTLLC, FTLLC and prior works are implemented in gem5, and are simulated with SPEC CPU2006. The experiment shows that compared with Concertina at 650 mV, the performance of a 65 nm FTLLC with 4-Byte subblock size improves by 7.2% and the Cache capacity increases by 24.9%. Besides, the miss rate decreases by 58.2%, and there are little increases on area overhead and power consumption.

KW - Compression mechanism

KW - Error correction code

KW - Fault-tolerant Cache

KW - Near-threshold voltage

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DO - 10.11999/JEIT170989

M3 - 文章

AN - SCOPUS:85054870739

SN - 1009-5896

VL - 40

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EP - 1766

JO - Dianzi Yu Xinxi Xuebao/Journal of Electronics and Information Technology

JF - Dianzi Yu Xinxi Xuebao/Journal of Electronics and Information Technology

IS - 7

ER -

近阈值电压下可容错的末级缓存结构设计

摘要

联合国可持续发展目标

关键词

访问文件

其它文件与链接

指纹

引用此