Power reduction through X-filling of transition fault test vectors for LOS testing

2011 6th International Conference on Design & Technology of Integrated Systems in Nanoscale Era (DTIS) Pub Date : 2010-05-27 DOI:10.1109/DTIS.2011.5941434

F. Wu, L. Dilillo, A. Bosio, P. Girard, S. Pravossoudovitch, A. Virazel, M. Tehranipoor, K. Miyase, X. Wen, N. Ahmed

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引用次数: 21

Abstract

Launch-Off-Capture (LOC) and Launch-Off-Shift (LOS) are the two main test schemes for at-speed scan delay testing. In [1, 2], authors proposed a comparison between LOC and LOS, showing that LOS has higher performance than LOC in terms of fault coverage and test length, but higher peak power consumption during the launch-to-capture cycle. This shows the potential benefits of using LOS test scheme provided that power issues can be solved. In this context, this study investigates power reduction of LOS testing through X-filling techniques. Basically, the proposed solution consists in using test relaxation to identify don't-care bits (X-bits) in test vectors and then applying various X-filling techniques so that peak power during the launch-to-capture cycle is comparable to the power consumption in functional mode. In our experiments, we used ITC'99 benchmark circuits synthesized with an industrial 65nm technology. Experimental results show peak power reduction of up to 50% compared to the peak power when test vectors are generated with a conventional ATPG using the random filling option.

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通过对过渡故障测试向量进行x填充来降低LOS测试的功耗

发射-关闭-捕获(LOC)和发射-关闭-移位(LOS)是高速扫描延迟测试的两种主要测试方案。在[1,2]中，作者提出了LOC和LOS的比较，表明LOS在故障覆盖率和测试长度方面比LOC具有更高的性能，但在发射到捕获周期的峰值功耗更高。这显示了如果可以解决电源问题，使用LOS测试方案的潜在好处。在此背景下，本研究通过x填充技术研究LOS测试的功耗降低。基本上，提出的解决方案包括使用测试松弛来识别测试向量中的不关心位(x位)，然后应用各种x填充技术，以便在发射到捕获周期内的峰值功率与功能模式下的功耗相当。在我们的实验中，我们使用了ITC'99基准电路，采用工业65纳米技术合成。实验结果表明，与使用随机填充选项生成测试向量的传统ATPG相比，峰值功率降低高达50%。

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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2011 6th International Conference on Design & Technology of Integrated Systems in Nanoscale Era (DTIS)

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