通过区分电压缩放优化缓解bti诱导的FPGA器件老化(仅摘要)

Proceedings of the 2014 ACM/SIGDA international symposium on Field-programmable gate arrays Pub Date : 2014-02-26 DOI:10.1145/2554688.2554752

Yu Bai, Mohammed Alawad, Mingjie Lin

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引用次数: 0

摘要

随着CMOS技术向22nm节点的积极扩展，由于偏置温度稳定性(BTI)和热载流子注入(HCI)，现代FPGA器件面临着巨大的老化引起的可靠性挑战。本文提出了一种新的逻辑级抗老化技术，该技术既可扩展，又适用于用FPGA器件实现的超大规模集成电路数字电路。关键思想是通过基于模块临界值战略性地提高一些lut的VDD值来延长fpga映射设计的寿命。虽然为了提高能源效率或电路可靠性而扩展VDD的想法已经被广泛探索，但我们的研究通过分析过程来解决这一挑战，因此能够通过严格建模bti诱导的设备可靠性和最佳解决VDD分配问题来最大化目标FPGA设计的整体可靠性。

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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Optimally mitigating BTI-induced FPGA device aging with discriminative voltage scaling (abstract only)

With the CMOS technology aggressively scaling towards the 22nm node, modern FPGA devices face tremendous aging- induced reliability challenges due to Bias Temperature In- stability (BTI) and Hot Carrier Injection (HCI). This paper presents a novel antiaging technique at logic level that is both scalable and applicable for VLSI digital circuits implemented with FPGA devices. The key idea is to prolong the lifetime of FPGA-mapped designs by strategically elevating the VDD values of some LUTs based on their modular criticality values. Although the idea of scaling VDD in order to improve either energy efficiency or circuit reliability has been explored extensively, our study distinguishes itself by approaching this challenge through analytical procedure, therefore able to maximize the overall reliability of target FPGA design by rigorously modelling the BTI-induce de- vice reliability and optimally solving the VDD assignment problem.

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Proceedings of the 2014 ACM/SIGDA international symposium on Field-programmable gate arrays

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