利用全局灵敏度和综合灵活性进行功率优化的工程变更

Proceedings of 1997 International Symposium on Low Power Electronics and Design Pub Date : 1997-08-01 DOI:10.1145/263272.263290

Premal Buch, C. Lennard, A. Newton

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引用次数: 4

摘要

提出了一种技术依赖的功率优化技术，该技术将热点减小问题表述为工程变更问题的变体。提出了一种既考虑局部效应又考虑全局效应的电路功耗灵敏度测定方法。这种灵敏度与合成灵活性的测量相结合，以识别电路中的热区，这些热区在功能变化方面具有很大的灵活性，并且对其来说，小的功能变化可以极大地影响整体功耗。为热区构造了一个不完全指定的目标函数，使得任何满足该函数的实现都有望降低功耗。在不影响电路面积、栅极电容或单位延迟模型下的延迟的情况下，采用一种重新布线算法来解决由此产生的EC问题。在一组MCNC基准电路上的实验结果表明，该方法可使功耗降低13%，平均降低4%。

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Engineering change for power optimization using global sensitivity and synthesis flexibility

A technology dependent power optimization technique is proposed which formulates the problem of hot spot reduction as a variant of the engineering change (EC) problem. A technique is presented for determining the sensitivity of circuit power dissipation to functional changes considering both local and global effects. This sensitivity is combined with a measure of synthesis flexibility to identify hot regions in the circuit which have a lot of flexibility in making functional changes and for whom a small functional change can greatly affect the overall power dissipation. An incompletely specified target function is constructed for the hot region such that any implementation satisfying it is expected to reduce power. A rewiring algorithm is used to solve the resulting EC problem without affecting circuit area, gate capacitance or delay under the unit delay model. Experimental results on a set of MCNC benchmark circuits show that the proposed approach can give up to 13% reduction in power dissipation with an average reduction of 4%.

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Proceedings of 1997 International Symposium on Low Power Electronics and Design

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