时序逻辑测试生成的经济扫描设计

[1989] The Nineteenth International Symposium on Fault-Tolerant Computing. Digest of Papers Pub Date : 1989-06-21 DOI:10.1109/FTCS.1989.105539

K. Cheng, V. Agrawal

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引用次数: 95

摘要

提出了一种局部扫描设计方法，其中扫描触发器的选择旨在打破电路的循环结构。实验数据表明，测试生成复杂度随电路周期长度呈指数增长。这种复杂性只随着顺序深度线性增长。提出了一种图论算法来选择一个最小的触发器集来消除循环，以减少序列深度。结果电路的测试可以通过顺序逻辑测试发生器有效地生成。扫描时钟的独立控制允许在测试发生器产生的矢量序列内插入扫描序列。在5000栅极电路上的实验结果表明，只需扫描5%的触发器就可以获得98%以上的测试覆盖率。此外，作者还设计了一种扫描触发器，以减少单时钟设计中的输入引脚和信号路由开销。

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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An economical scan design for sequential logic test generation

A method of partial scan design in which the selection of scan flip-flops is aimed at breaking up the cyclic structure of the circuit is presented. Experimental data are given to show that the test generation complexity may grow exponentially with the length of the cycles in the circuit. This complexity grows only linearly with sequential depth. Graph-theoretic algorithms are presented to select a minimal set of flip-flops for eliminating cycles to reduce sequential depth. Tests for the resulting circuit can be efficiently generated by a sequential logic test generator. An independent control of the scan clock allows the insertion of scan sequences within the vector sequence produced by the test generator. Experimental results on a 5000 gate circuit show that a test coverage above 98% could be obtained by scanning just 5% of the flip-flops. In addition, the authors give the design of a scan flip-flop to reduce the input pin and signal routing overheads in a single-clock design.<>

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来源期刊

[1989] The Nineteenth International Symposium on Fault-Tolerant Computing. Digest of Papers

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