SLIM--The Translation of Symbolic Layouts into Mask Data

17th Design Automation Conference Pub Date : 1988-06-01 DOI:10.1145/62882.62906

A. Dunlop

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引用次数: 26

Abstract

A new form of symbolic layout for integrated circuits is coupled with a mask compaction procedure which removes excess space while guaranteeing that all design rules are met. Trade-offs between X and Y compaction are made based on critical path information. Two types of compaction are used to minimize mask area and computer run-time. Additional procedures reduce mask area by inserting jogs at strategic locations in the layout. A partitioned data base is used to store mask data in a hierarchical manner. The symbolic layout and mask compaction procedures require only 30 to 50 percent of the time traditionally needed to do equivalent hand layouts. The global guidance information is used to control local compaction (clustering), automatic jog insertion, and global compaction procedures. These procedures make extensive use of design rule tolerance tests in reducing the area of the "initial placement" mask layout. The symbolic input is a loose topological description of the layout made up of single-connection-per-side symbols (e.g., transistors, interlayer contacts, etc.) and multiple-connection-per-side symbols (e.g., predefined RAMs, ROMs, flip-flops, etc.). The output is a legal mask description and graphical displays.

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SLIM——符号布局到掩码数据的转换

一种新的集成电路符号布局形式与掩模压缩程序相结合，该程序在保证满足所有设计规则的同时消除了多余的空间。X和Y压缩之间的权衡是基于关键路径信息进行的。使用两种类型的压缩来最小化掩模面积和计算机运行时间。额外的程序通过在布局的战略位置插入慢跑来减少遮罩面积。分区数据库用于以分层方式存储掩码数据。符号布局和掩模压缩过程只需要传统手工布局所需时间的30%到50%。全局引导信息用于控制局部压缩(聚类)、自动慢跑插入和全局压缩过程。这些程序广泛使用设计规则公差测试来减少“初始放置”掩模布局的面积。符号输入是由每侧单连接符号(例如，晶体管，层间触点等)和每侧多连接符号(例如，预定义的ram, rom，触发器等)组成的布局的松散拓扑描述。输出是一个合法的掩码描述和图形显示。

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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17th Design Automation Conference

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