基于布局的时序优化逻辑分解

Proceedings of the ASP-DAC '99 Asia and South Pacific Design Automation Conference 1999 (Cat. No.99EX198) Pub Date : 1999-01-18 DOI:10.1109/ASPDAC.1999.760002

Yun-Yin Lian, Y. Lin

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引用次数: 9

摘要

随着特征尺寸缩小到深亚微米，互连延迟成为VLSI芯片性能的主要因素。在传统的自顶向下设计流程中，由于缺乏物理设计信息，逻辑合成算法优化栅极面积或延迟，而没有准确的互连延迟。因此，优化技术的有效性是有限的。我们将逻辑综合和物理设计集成到性能优化的迭代过程中。逻辑合成过程可以根据从物理设计中提取的准确互连延迟信息来优化电路延迟。物理设计工具可以根据逻辑综合过程传递的工程变更信息和变更网表，逐步细化布局。在本文中，我们将逻辑分解、栅极尺寸和缓冲器插入集成在一起，以提高电路速度。在一组基准电路上的实验结果表明，该方法是有效的。

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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Layout-based logic decomposition for timing optimization

As feature sizes shrink to deep sub-micron, the performance of VLSI chips becomes dominated by the interconnect delay. In a traditional top-down design flow, logic synthesis algorithms optimize gate area or delay without accurate interconnect delay because of lack of physical design information. Thus, the effectiveness of the optimization techniques is limited. We integrate logic synthesis and physical design into an iterative procedure for performance optimization. The logic synthesis process can optimize circuit delay based on accurate interconnect delay information extracted from the physical design. The physical design tools can refine the layout incrementally with the engineering change information and changed netlist passed from the logic synthesis process. In this thesis, we integrate logic decomposition, gate sizing and buffer insertion to work together to improve the circuit speed. Experimental results on a set of benchmark circuits show that the techniques are indeed effective.

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Proceedings of the ASP-DAC '99 Asia and South Pacific Design Automation Conference 1999 (Cat. No.99EX198)

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