LFSR/SR伪穷举TPG在更少的测试周期

Proceedings 1999 IEEE International Symposium on Defect and Fault Tolerance in VLSI Systems (EFT'99) Pub Date : 1999-11-01 DOI:10.1109/DFTVS.1999.802878

D. Kagaris, S. Tragoudas

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引用次数: 0

摘要

线性反馈移位寄存器是数字组合或全扫描电路和系统的内置测试体系结构中最常用的机制。伪穷举TPG的目标是以较低的硬件开销最小化所需的测试长度。现有的方法是基于原始特征多项式的。在这种情况下，硬件开销(种子)是最小的，但是候选多项式很少。我们的实验表明，这些方法往往不能产生伪穷举测试。没有一种方法允许少量的种子，以便在规定的范围内获得伪穷举测试集。我们的方法允许考虑更多的候选多项式，它们不是原始的，但提供了非常少的种子。在ISCAS'85基准上的实验结果表明，当之前的方法失败时，该方法通常以非常少的种子数量成功。

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LFSR/SR pseudoexhaustive TPG in fewer test cycles

Linear feedback shift registers are the most commonly used mechanism in built-in test architectures for digital combinational or fully scanned circuits and systems. The goal in pseudo-exhaustive TPG is to minimize the required test length with low hardware overhead. Existing approaches are based on primitive characteristic polynomials. The hardware overhead (seeds) is minimal in this case, but the candidate polynomials are few. Our experiments show that these methods often fail to produce pseudoexhaustive tests. There are no approaches that allow a small number of seeds in order to obtain pseudoexhaustive test sets within a prescribed bound. Our method allows consideration of still more candidate polynomials, that are not primitive, but offer a very small number of seeds. Experimental results on the ISCAS'85 benchmarks show that the method often succeeds with a very low number of seeds when all previous methods fail.

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Proceedings 1999 IEEE International Symposium on Defect and Fault Tolerance in VLSI Systems (EFT'99)

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