Seyab Khan, I. Agbo, S. Hamdioui, H. Kukner, B. Kaczer, P. Raghavan, F. Catthoor
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引用次数: 59
摘要
偏置温度不稳定性(BTI)降低了半导体器件的性能,对当今和未来的半导体器件的可靠性构成了重大挑战。本文提供了一个全面的BTI影响分析,在时间相关的退化,基于FinFET的SRAM电池。评价指标为读静态噪声裕度(SNM)、保持SNM和写跳闸点(WTP);而研究的方面包括BTI对供电电压、电池强度和设计风格(6 vs 8晶体管电池)的影响。比较了FinFET和基于平面CMOS的SRAM电池的退化。基于FinFET的电池在额定Vdd下运行108秒的仿真表明,Read SNM的退化率为16.72%,比hold SNM快1.17倍,而WTP提高了6.82%。此外,电源电压增加25%可使Read SNM退化降低40%,而将电池下拉晶体管加强1.5倍仅可使退化降低22%。结果表明,8T电池的降解速度比6T电池快1.31倍,而FinFET电池比平面CMOS电池更容易受到BTI降解的影响(~2倍)。
Bias Temperature Instability analysis of FinFET based SRAM cells
Bias Temperature Instability (BTI) is posing a major reliability challenge for today's and future semiconductor devices as it degrades their performance. This paper provides a comprehensive BTI impact analysis, in terms of time-dependent degradation, of FinFET based SRAM cell. The evaluation metrics are read Static Noise Margin (SNM), hold SNM and Write Trip Point (WTP); while the aspects investigated include BTI impact dependence on the supply voltage, cell strength, and design styles (6 versus 8 Transistors cell). A comparison between FinFET and planar CMOS based SRAM cells degradation is also covered. The simulation performed on FinFET based cells for 108 seconds of operation under nominal Vdd show that Read SNM degradation is 16.72%, which is 1.17× faster than hold SNM, while WTP improves by 6.82%. In addition, a supply voltage increment of 25% reduces the Read SNM degradation by 40%, while strengthening the cell pull-down transistors by 1.5× reduces the degradation by only 22%. Moreover, the results reveal that 8T cell degrades 1.31× faster than 6T cell, and that FinFET cells are more vulnerable (~2×) to BTI degradation than planar CMOS cells.
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