Dynamic Thermal Clock Skew Compensation using Tunable Delay Buffers

A. Chakraborty, K. Duraisami, A. Sathanur, P. Sithambaram, L. Benini, A. Macii, E. Macii, M. Poncino
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引用次数: 78

Abstract

The thermal gradients existing in high-performance circuits may significantly affect their timing behavior, in particular by increasing the skew of the clock net and/or altering hold/setup constraints, possibly causing the circuit to operate incorrectly. The knowledge of the spatial distribution of temperature can be used to properly design a clock network that is able to compensate such thermal non-uniformities. However, re-design of the clock network is effective only if temperature distribution is stationary, i.e., does not change over time. In this work, we specifically address the problem of dynamically modifying the clock tree in such a way that it can compensate for temporal variations of temperature. This is achieved by exploiting the buffers that are inserted during the clock network generation, by transforming them into tunable delay elements. Temperature-induced delay variations are then compensated by applying the proper tuning to the tunable buffers, which is computed off-line and, stored in a tuning table inserted in the design. We propose an algorithm to minimize the number of inserted tunable buffers, as well as their tunable range (which directly relates to complexity). Results show that clock skew is kept within original bounds with minimum area and power penalty. The maximum increase in power is 23.2% with most benchmarks exhibiting less than 5% increase in power
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动态热时钟偏差补偿使用可调延迟缓冲器
高性能电路中存在的热梯度可能会显著影响其时序行为,特别是通过增加时钟网的倾斜和/或改变保持/设置约束,可能导致电路工作不正确。温度空间分布的知识可以用来适当地设计一个时钟网络,能够补偿这种热不均匀性。然而,时钟网络的重新设计是有效的,只有当温度分布是平稳的,即不随时间变化。在这项工作中,我们专门解决了动态修改时钟树的问题,这样它就可以补偿温度的时间变化。这是通过利用在时钟网络生成期间插入的缓冲区来实现的,通过将它们转换为可调的延迟元素。然后通过对可调缓冲器进行适当的调整来补偿温度引起的延迟变化,可调缓冲器离线计算并存储在设计中插入的调优表中。我们提出了一种算法来最小化插入的可调缓冲区的数量,以及它们的可调范围(这直接关系到复杂性)。结果表明,时钟偏差保持在原来的范围内,面积和功率损失最小。最大功率增长为23.2%,大多数基准测试显示功率增长不到5%
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