Clock Tree Construction based on Arrival Time Constraints

Proceedings of the 2017 ACM on International Symposium on Physical Design Pub Date : 2017-03-19 DOI:10.1145/3036669.3036671

Rickard Ewetz, Cheng-Kok Koh

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引用次数: 2

Abstract

There are striking differences between constructing clock trees based on dynamic implied skew constraints and based on static arrival time constraints. Dynamic implied skew constraints allow the full timing margins to be utilized, but the constraints are required to be updated (with high time complexity). In contrast, static arrival time constraints are decoupled and are not required to be updated. Therefore, the constraints can be obtained in constant time, which facilitates the exploration of various tree topologies. On the other hand, arrival time constraints do not allow the full timing margins to be utilized. Consequently, there is a trade-off between topology exploration and timing margin utilization. In this paper, the advantages of static arrival time constraints are leveraged to construct clock trees with useful skew while exploring various tree topologies. Moreover, the constraints are specified and respecified throughout the synthesis process reduce the cost of the constructed clock trees. It is experimentally demonstrated that the proposed approach results in clock trees with 16% lower average capacitive cost compared with clock trees constructed based on dynamic implied skew constraints.

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基于到达时间约束的时钟树构造

基于动态隐含偏差约束和基于静态到达时间约束的时钟树构造存在显著差异。动态隐含的倾斜约束允许充分利用时间余量，但需要更新约束(具有高时间复杂性)。相反，静态到达时间约束是解耦的，不需要更新。因此，约束条件可以在恒定时间内得到，便于探索各种树的拓扑结构。另一方面，到达时间限制不允许充分利用时间余量。因此，在拓扑探索和时间裕度利用之间存在一种权衡。在本文中，利用静态到达时间约束的优势来构建具有有用偏差的时钟树，同时探索各种树拓扑。此外，在整个合成过程中指定和重新指定约束，减少了构造时钟树的成本。实验表明，与基于动态隐含偏差约束的时钟树相比，该方法的时钟树的平均电容成本降低了16%。

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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Proceedings of the 2017 ACM on International Symposium on Physical Design

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