用拉格朗日松弛法快速精确地同时确定门和线的尺寸

1998 IEEE/ACM International Conference on Computer-Aided Design. Digest of Technical Papers (IEEE Cat. No.98CB36287) Pub Date : 1998-11-01 DOI:10.1145/288548.289097

C. C. Chen, C. Chu, Martin D. F. Wong

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引用次数: 270

摘要

本文考虑在Elmore延迟模型下通用VLSI电路的同时门和线尺寸(W.C. Elmore, 1948)。我们提出了一种快速精确的算法，可以在最大延迟界下最小化总面积。该算法可以很容易地修改，以给出优化其他几个目标的精确算法(例如，最小化最大延迟或最小化所有输入和输出的到达时间规格的总面积)。对于一般电路，以往的门线尺寸同步算法无法保证精确的解。我们的算法是一个迭代算法，保证收敛到全局最优解。它基于拉格朗日松弛和“一门一线”局部优化，非常经济和快速。例如，我们可以在IBM RS/6000工作站上使用渲染23 MB内存，在大约36分钟内优化具有27648个门和导线的电路。

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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Fast and exact simultaneous gate and wire sizing by Lagrangian relaxation

The paper considers simultaneous gate and wire sizing for general VLSI circuits under the Elmore delay model (W.C. Elmore, 1948). We present a fast and exact algorithm which can minimize total area subject to maximum delay bound. The algorithm can be easily modified to give exact algorithms for optimizing several other objectives (e.g. minimizing maximum delay or minimizing total area subject to arrival time specifications at all inputs and outputs). No previous algorithm for simultaneous gate and wire sizing can guarantee exact solutions for general circuits. Our algorithm is an iterative one with a guarantee on convergence to global optimal solutions. It is based on Lagrangian relaxation and "one-gate/wire-at-a-time" local optimizations, and is extremely economical and fast. For example, we can optimize a circuit with 27648 gates and wires in about 36 minutes using render 23 MB memory on an IBM RS/6000 workstation.

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来源期刊

1998 IEEE/ACM International Conference on Computer-Aided Design. Digest of Technical Papers (IEEE Cat. No.98CB36287)

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