Reliability and performance tradeoffs in the design of on-chip power delivery and interconnects

IEEE 8th Topical Meeting on Electrical Performance of Electronic Packaging (Cat. No.99TH8412) Pub Date : 1999-10-25 DOI:10.1109/EPEP.1999.819191

G. Taylor, T. Arabi, H. Greub, R. Muyshondt, A. Manthe, P. Aminzadeh

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引用次数: 10

Abstract

The performance of CMOS integrated circuits has always been, and continues to be, limited by reliability considerations. Performance, reliability, and cost are traded off through voltage and temperature specifications. Higher operating voltage raises performance but impacts reliability both directly and through increased temperatures unless extra cooling is supplied. Lower temperatures yield higher performance and higher reliability but also higher cost. As silicon technology scales, these trade-offs are becoming more pronounced. While hot carrier injection may be becoming less significant as semiconductor technology scales to thinner gate oxides, other mechanisms are becoming more significant. The temperature acceleration of oxide breakdown is increasing with decreasing thickness (Degraeve et al., 1999), current densities are increasing, further stressing electromigration, and inductive noise effects are becoming more significant, while soft error susceptibility is increasing (Dai et al., 1999). There are many mechanisms that can lead to the failure of an integrated circuit. Hot carrier injection has been a significant issue, but has been surpassed by other mechanisms as CMOS technology has advanced into the deep submicron regime. In this paper, we focus mainly on the design and validations issues associated with oxide wear-out failure mechanisms.

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片上供电和互连设计中的可靠性和性能权衡

CMOS集成电路的性能一直并将继续受到可靠性考虑的限制。通过电压和温度规格来权衡性能、可靠性和成本。更高的工作电压提高了性能，但直接或通过温度升高影响可靠性，除非提供额外的冷却。温度越低，性能越好，可靠性越高，但成本也越高。随着硅技术的规模化，这些权衡变得越来越明显。随着半导体技术向更薄的栅极氧化物扩展，热载流子注入可能变得不那么重要，但其他机制正变得越来越重要。氧化物击穿的温度加速随着厚度的减少而增加(Degraeve et al.， 1999)，电流密度增加，进一步强调电迁移，感应噪声效应变得更加显著，而软误差敏感性也在增加(Dai et al.， 1999)。有许多机制可以导致集成电路的故障。热载流子注入一直是一个重要的问题，但随着CMOS技术进入深亚微米领域，其他机制已经超越了这一问题。在本文中，我们主要关注与氧化物磨损失效机制相关的设计和验证问题。

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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IEEE 8th Topical Meeting on Electrical Performance of Electronic Packaging (Cat. No.99TH8412)

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