Using defect density modelling to drive the optimisation of circuit layout, maximising yield

Proceedings of International Workshop on Defect and Fault Tolerance in VLSI Pub Date : 1995-11-13 DOI:10.1109/DFTVS.1995.476949

M. Baxter, D. Muir

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Abstract

With integrated circuit [IC] market requirements driving the increase in diversity of product families and technologies, modelling of defect density within wafer fabrication is increasing in complexity. The exponential growth in the number of applications of the IC has meant that the requirement of each wafer fabrication facility has moved from running single volume products to being able to cope with running up to hundreds of different products at one time. Where it is possible to retain one volume product per wafer fabrication site, simpler defect density modelling may be representative models or indicators of defect density. When multiple process flows, product families and technologies are manufactured at one time, using one model was found to be unviable. By developing wafer fabrication site specific models, the effects of inline defectivity and design layout were found to consistently relate to yield. Product family variations also showed relationships with yield, where memory size, complexity and module choice could be optimised to maximise yield of a new product.

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使用缺陷密度模型来驱动电路布局的优化，最大限度地提高产量

随着集成电路(IC)市场需求推动产品系列和技术多样性的增加，晶圆制造中缺陷密度的建模越来越复杂。集成电路应用数量的指数级增长意味着每个晶圆制造工厂的要求已经从运行单批量产品转变为能够同时处理多达数百种不同产品。在每个晶圆制造地点可以保留一个体积产品的情况下，更简单的缺陷密度建模可以是缺陷密度的代表性模型或指标。当一次生产多个工艺流、产品族和技术时，使用一个模型是不可行的。通过开发晶圆制造现场特定模型，发现内联缺陷和设计布局的影响始终与良率相关。产品系列的变化也显示出与产量的关系，其中内存大小，复杂性和模块选择可以优化，以最大限度地提高新产品的产量。

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 International Workshop on Defect and Fault Tolerance in VLSI

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