High speed serializing/de-serializing design-for-test method for evaluating a 1 GHz microprocessor

Heidel, D.; Dhong, S.H.; Hofstee, Peter; Immediato, M.; Nowka, K.; Silberman, J. A.; Stawiasz, K.

doi:10.1109/vtest.1998.670873

Cited by 33 publications

(20 citation statements)

References 1 publication

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“…This allows us to use slower testers without increasing the test application time. The external clock and scan clocks must be synchronized, e.g., using the scheme described in [24], [25], and , where the Golomb code parameter is usually a power of two. This allows the bits of to be generated by the decoder at the frequency of .…”

Section: B Analysis Of Test Application Time and Test-data Compressionmentioning

confidence: 99%

System-on-a-chip test-data compression and decompression architectures based on Golomb codes

Chandra

Chakrabarty

2001

IEEE Trans. Comput.-Aided Des. Integr. Circuits Syst.

313

262

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Abstract-We present a new test-data compression method and decompression architecture based on variable-to-variable-length Golomb codes. The proposed method is especially suitable for encoding precomputed test sets for embedded cores in a system-on-a-chip (SoC). The major advantages of Golomb coding of test data include very high compression, analytically predictable compression results, and a low-cost and scalable on-chip decoder. In addition, the novel interleaving decompression architecture allows multiple cores in an SoC to be tested concurrently using a single automatic test equipment input-output channel. We demonstrate the effectiveness of the proposed approach by applying it to the Internaional Symposium on Circuits and Systems' benchmark circuits and to two industrial production circuits. We also use analytical and experimental means to highlight the superiority of Golomb codes over run-length codes.

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Section: B Analysis Of Test Application Time and Test-data Compressionmentioning

confidence: 99%

System-on-a-chip test-data compression and decompression architectures based on Golomb codes

Chandra

Chakrabarty

2001

IEEE Trans. Comput.-Aided Des. Integr. Circuits Syst.

313

262

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“…A particular advantage of methods which use data compression coding schemes is that they are capable of exploiting the ever increasing gap between the on-chip test frequency and the ATE operating frequency. While in the past this gap has been exploited at the cost of multiple ATE channels [35,36], hence increasing the bandwidth requirements, approaches which use data compression coding schemes can leverage the frequency ratio without the penalty of extra ATE channels. This is achieved by moving the serialization of test data from the spatial domain (multiple input channels from the ATE at a low frequency to single scan channel at a high frequency) to the temporal domain (single input channel from the ATE at a low frequency to single scan channel at a high frequency).…”

Section: Existing Approaches To Reduce Volume Of Test Datamentioning

confidence: 99%

“…It should be noted that for the decompression of T di f f , a CSR architecture [2,30] is used after the VIHC decoder in Figure 5. This work assumes that the ATE is capable of external clock synchronization [36].…”

Section: Decompressionmentioning

confidence: 99%

Variable-length input huffman coding for system-on-a-chip test

Gonciari

Al-Hashimi

Nicolici

2003

IEEE Trans. Comput.-Aided Des. Integr. Circuits Syst.

148

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This paper presents a new compression method for embedded core-based system-on-a-chip test. In addition to the new compression method, this paper analyzes the three test data compression environment (TDCE) parameters: compression ratio, area overhead and test application time, and explains the impact of the factors which influence these three parameters. The proposed method is based on a new Variable-length Input Huffman Coding scheme, which proves to be the key element that determines all the factors that influence the TDCE parameters. Extensive experimental comparisons show that, whencompared to three previous approaches [1][2][3], which reduce some test data compression environment's parameters at the expense of the others, the proposed method is capable of improving on all the three TDCE parameters simultaneously.

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“…Since for at-speed testing, it is not necessary to load/unload test data at the rated frequencies, the shift frequency is used to tradeoff testing time against power dissipation. Unlike [4], we do not speed up the test data load/unload to its functional frequency through serializing/de-serializing technique since this will reduce the tester channel capacity and increase test power. Rather, we load/unload test data from/to the ATE at the speed of the tester frequency f t and distribute it to multiple scan chains at the speed of shift frequency f s using the proposed wrapper architecture.…”

Section: Mfcwd: Given a Core With Its Test Set Parameters Ie The mentioning

confidence: 99%