用LFSR生成基准电路的测试模式

2013 Fourth International Conference on Computing, Communications and Networking Technologies (ICCCNT) Pub Date : 2013-07-04 DOI:10.1109/ICCCNT.2013.6726500

Chengani VinodChandra, S. Ramasamy

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引用次数: 5

摘要

众所周知，电路的测试生成问题是np困难的。有效的测试生成技术对于减少测试生成时间至关重要。使用ATPG(自动测试模式生成)生成测试模式，并将故障插入到使用DFT(测试设计)生成的网表文件中。在这里，ATPG是使用设计编译器和Tetramax的结合来实现的。生成了故障覆盖和测试模式。结果表明，无论是全面的功能验证序列，还是高卡滞故障覆盖率的序列，都不能为顺序电路提供高的过渡故障覆盖率。使用自定义的LFSR算法确定故障覆盖范围和用于检测故障的模式。与ATPG工具相比，LFSR技术在中小型电路中似乎是好的。LFSR技术的故障覆盖率为100%，而Tetramax的故障覆盖率约为97%。

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Test pattern generation for benchmark circuits using LFSR

The test generation problem for circuits is known to be NP-hard. Efficient techniques for test generation are essential in order to reduce the test generation time. Test patterns were generated using ATPG (Automatic Test Pattern Generation) and faults were inserted in the netlist file generated using DFT (Design for Test). Here ATPG is achieved using the combination of Design Compiler and the Tetramax. Fault coverage and test patterns were generated. It was observed that neither a comprehensive functional verification sequence nor a sequence with high stuck-at fault coverage gives high transition fault coverage for sequential circuits. A customized LFSR algorithm is used to find the fault coverage and pattern used to detect the faults. It is found that LFSR techniqque seems to be good when compared to the ATPG tool for the small and medium circuits. LFSR technique yields 100% fault coverage where as Tetramax is giving about 97% fault coverage.

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2013 Fourth International Conference on Computing, Communications and Networking Technologies (ICCCNT)

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