The purpose of a testability analysis program is to estimate the difficulty of testing a fault. A good measurement can give an early warning about the testing problem so as to provide guidance in improving the testability of a circuit. There have been researches attempting to efficiently compute the testability analysis. Among those, the Controllability and Observability Procedure COP can calculate the testability value of a stuck-at fault efficiently in a tree-structured circuit but may be very inaccurate for a general circuit. The inaccuracy in COP is due to the ignorance of signal correlations. Recently, the algorithm of TAIR in 5 proposes a testability analysis algorithm, which starts from the result of COP and then gradually improves the result by applying a set of rules. The set of rules in TAIR can capture some signal correlations and therefore the results of TAIR are more accurate than COP. In this paper, we first prove that the rules in TAIR can be replaced by a closed-form formulation. Then, based on the closed-form formulation, we proposed two novel techniques to further improve the testability analysis results. Our experimental results have shown improvement over the results of TAIR.
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机译:可测试性分析程序的目的是估计测试故障的难度。良好的测量可以对测试问题进行早期预警,从而为提高电路的可测试性提供指导。已经有研究试图有效地计算可测试性分析。其中,可控性和可观察性程序COP可以在树形结构电路中有效地计算卡住故障的可测试性值,但对于一般电路来说可能非常不准确。COP的不准确性是由于对信号相关性的无知。最近,TAIR算法在[5]中提出了一种可测试性分析算法,该算法从COP的结果开始,然后通过应用一组规则逐步改进结果。TAIR 中的规则集可以捕获一些信号相关性,因此 TAIR 的结果比 COP 更准确。在本文中,我们首先证明了TAIR中的规则可以被封闭式公式所取代。然后,基于封闭式公式,提出了两种新技术,以进一步改善可测试性分析结果。我们的实验结果表明,与TAIR的结果相比有所改善。
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