高性能低vcc序核

HPCA - 16 2010 The Sixteenth International Symposium on High-Performance Computer Architecture Pub Date : 2010-04-01 DOI:10.1109/HPCA.2010.5416630

J. Abella, P. Chaparro, X. Vera, J. Carretero, Antonio González

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引用次数: 6

摘要

新技术节点的功率密度不断增长，因此需要Vcc进行扩展，尤其是在能源至关重要的移动平台上。本文提出了一种在保持高工作频率的情况下降低压降比的新方法。我们的机制被称为写后立即读(IRAW)避免。我们提出了一种用于Intel®SilverthorneTM顺序核的机制实现。此外，我们证明了我们的机制可以动态地适应，以在每个Vcc水平上提供最高的性能和最低的能量延迟积(EDP)。结果表明，在500mV和400mV下，避免IRAW使工作频率分别提高了57%和99%，而面积和功率开销可以忽略不计(低于1%)，这意味着大幅加速(500mV时为48%，400mV时为90%)和EDP降低(500mV时为0.61 EDP, 400mV时为0.33)。

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High-Performance low-vcc in-order core

Power density grows in new technology nodes, thus requiring Vcc to scale especially in mobile platforms where energy is critical. This paper presents a novel approach to decrease Vcc while keeping operating frequency high. Our mechanism is referred to as immediate read after write (IRAW) avoidance. We propose an implementation of the mechanism for an Intel® SilverthorneTM in-order core. Furthermore, we show that our mechanism can be adapted dynamically to provide the highest performance and lowest energy-delay product (EDP) at each Vcc level. Results show that IRAW avoidance increases operating frequency by 57% at 500mV and 99% at 400mV with negligible area and power overhead (below 1%), which translates into large speedups (48% at 500mV and 90% at 400mV) and EDP reductions (0.61 EDP at 500mV and 0.33 at 400mV).

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HPCA - 16 2010 The Sixteenth International Symposium on High-Performance Computer Architecture

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