Modeling and characterization of the system-level Power Delivery Network for a dual-core ARM Cortex-A57 cluster in 28nm CMOS

2015 IEEE/ACM International Symposium on Low Power Electronics and Design (ISLPED) Pub Date : 2015-07-22 DOI:10.1109/ISLPED.2015.7273505

Shidhartha Das, P. Whatmough, David M. Bull

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引用次数: 34

Abstract

Power delivery is a well-known challenge for high-end microprocessor systems. Comparatively, mobile computing platforms typically consume order-of-magnitude lower currents, but economic and volume constraints limit the quality of the Power Delivery Network. In addition, the trend towards GHz+ operating frequencies and the ubiquity of low-power techniques such as clock-gating and power-gating, make these systems susceptible to pathological AC transients. Consequently, mobile computing systems are ultimately limited by power-delivery. In this paper, we present the system-level Power Delivery Network (PDN) modeling, analysis and measurement results on a dual-core 64bit ARM Cortex-A57 compute cluster in 28nm CMOS. We present a comprehensive analysis of the PDN by characterizing the individual contribution of each constituent i.e. the PCB, package and the die. We present frequency- and time-domain simulation results and correlate that with measurement (both on-chip and off-chip). Our results demonstrate how complex software and micro-architectural interactions can trigger PDN resonances that ultimately lead to system failure.

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基于28nm CMOS的双核ARM Cortex-A57集群系统级功率传输网络建模与表征

功率传输是高端微处理器系统面临的一个众所周知的挑战。相比之下，移动计算平台通常消耗数量级更低的电流，但经济和体积限制限制了电力输送网络的质量。此外，GHz+工作频率的趋势以及时钟门控和功率门控等低功耗技术的普遍存在，使这些系统容易受到病态交流瞬变的影响。因此，移动计算系统最终受到功率传输的限制。在本文中，我们介绍了在28nm CMOS的双核64位ARM Cortex-A57计算集群上的系统级功率传递网络(PDN)建模、分析和测量结果。我们通过描述每个组成部分(即PCB，封装和模具)的单独贡献，对PDN进行了全面分析。我们提出了频率和时域仿真结果，并将其与测量(片上和片外)相关联。我们的研究结果表明，复杂的软件和微架构交互如何触发PDN共振，最终导致系统故障。

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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2015 IEEE/ACM International Symposium on Low Power Electronics and Design (ISLPED)

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