The Performance Study of Two Genetic Algorithm Approaches for VLSI Macro-Cell Layout Area Optimization

2008 Second Asia International Conference on Modelling & Simulation (AMS) Pub Date : 2008-05-13 DOI:10.1109/AMS.2008.117

H. Rahim, A. Rahman, R. Ahmad, W. Ariffin, Muhammad Imran Ahmad

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引用次数: 7

Abstract

Very large scale integrated (VLSI) design has been the subject of much research since the early 1980s where the VLSI cell placement emerges to be a crucial stage in the chip design. Its area optimization is very important in order to reduce the delay and include more functionalities to the designed chip. The VLSI cell area optimization continues to become increasingly important to the performance of VLSI design due to the accelerating of the design complexities in VLSI. Thus, this paper addresses the performance comparisons of two different types of genetic algorithm (GA) techniques for VLSI macro-cell layout area optimization by utilizing the adopted method of cell placement that is binary tree method. Two GA approaches which are simple genetic algorithm (SGA) and steady-state genetic algorithm (SSGA) have been implemented and their performances in converging to their global minimums are examined and discussed. The performances of these techniques are tested on Microelectronics Center of North Carolina (MCNC) benchmark circuit's data set. The experimental results demonstrate that both algorithms achieve acceptable area requirement compared to the slicing floorplan approach (Lin et al., 2002). However, SSGA outperforms SGA where it achieves faster convergence rate and obtains more near optimum area.

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超大规模集成电路宏单元布局面积优化的两种遗传算法性能研究

自20世纪80年代初以来，超大规模集成电路(VLSI)设计一直是许多研究的主题，其中超大规模集成电路单元的放置成为芯片设计的关键阶段。它的面积优化是非常重要的，以减少延迟和包括更多的功能设计芯片。随着超大规模集成电路设计复杂度的不断提高，超大规模集成电路的单元面积优化对超大规模集成电路的设计性能变得越来越重要。因此，本文通过采用二叉树的单元放置方法，对两种不同类型的遗传算法(GA)技术进行VLSI宏单元布局区域优化的性能比较。本文给出了简单遗传算法(SGA)和稳态遗传算法(SSGA)两种遗传算法的实现，并对其收敛到全局最小值的性能进行了检验和讨论。在美国北卡罗来纳州微电子中心(MCNC)基准电路的数据集上对这些技术的性能进行了测试。实验结果表明，与切片平面图方法相比，两种算法都达到了可接受的面积要求(Lin et al.， 2002)。然而，SSGA在收敛速度更快和获得更接近最优区域方面优于SGA。

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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2008 Second Asia International Conference on Modelling & Simulation (AMS)

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