Scalable Approach for Power Droop Reduction During Scan-Based Logic BIST

Abstract: Abstract-The generation of significant power droop (PD) during at-speed test performed by Logic BIST is a serious concern for modern ICs. In fact, the PD originated during test may delay signal transitions of the circuit under test (CUT): an effect that may be erroneously recognized as delay faults, with consequent erroneous generation of test fails, and increase in yield loss. In this paper, we propose a novel, scalable approach to reduce the PD during at-speed test of sequential circuits with scan-based Logi… Show more

“…Please note that in cases when the presumed offset Θ is known, Table 2 makes it possible to find out 𝑛 and 𝑡 parameters of the appropriate DT-LFSR register to enable designing of a TPG that is able to supply test sequences to any number of scan paths, or at least as many as practicable. 15 6.21×10 14 3.11×10 14 1.55×10 14 7.76×10 13 3.88×10 13 12 59 60 1.53×10 14 7.63×10 13 3.82×10 13 1.91×10 13 9.54×10 12 4.77×10 12 13 59 68 3.91×10 16 1.95×10 16 9.77×10 15 4.89×10 15 2.44×10 15 1.22×10 15 14 62 63 1.16×10 15 5.81×10 14 2.91×10 14 1.45×10 14 7.26×10 13 3.63×10 13 15 62 71 2.98×10 17 1.49×10 17 7.44×10 16 3.72×10 16 1.86×10 16 9.30×10 15 16 65 71 2.84×10 17 1.42×10 17 7.09×10 16 3.55×10 16 1.77×10 16 8.87×10 15 17 65 81 2.91×10 20 1.45×10 20 7.27×10 19 3.63×10 19 1.82×10 19 9.08×10 18 18 70 79 6.75×10 19 3.37×10 19 1.69×10 19 78 95 3.97×10 24 1.98×10 24 9.92×10 23 4.96×10 23 2.48×10 23 1.24×10 23 22 84 95 3.68×...…”

“…On the contrary, the figures from Table 5 indicate that the phase shift (separation factor for output channels) enabled by the DT-LFSR Test Pattern Generator (DT-LFSR-TPG) for a specific number of scan chains can be higher by several magnitudes than numbers offered by LFSR+PS and CA+PS solutions disclosed in aforementioned studies. 25 7.28×10 24 3.64×10 24 1.82×10 24 9.10×10 23 4.55×10 23 2.28×10 23 24 91 1.36×10 25 6.80×10 24 3.40×10 24 1.70×10 24 8.50×10 23 4.25×10 23 2.13×10 23…”

“…There are numerous studies where researchers make efforts to improve the solution in terms of hardware overhead, testing time, power consumption, fault coverage, diagnosability, etc. [17][18][19][20][21][22][23][24][25][26]. Some variations of the STUMPS architecture are implemented into hybrid LBIST, where pseudo-random testing is combined with deterministic testing or test data compression [27][28][29][30][31][32].…”

A New, Fast Pseudo-Random Pattern Generator for Advanced Logic Built-In Self-Test Structures

“…Please note that in cases when the presumed offset Θ is known, Table 2 makes it possible to find out 𝑛 and 𝑡 parameters of the appropriate DT-LFSR register to enable designing of a TPG that is able to supply test sequences to any number of scan paths, or at least as many as practicable. 15 6.21×10 14 3.11×10 14 1.55×10 14 7.76×10 13 3.88×10 13 12 59 60 1.53×10 14 7.63×10 13 3.82×10 13 1.91×10 13 9.54×10 12 4.77×10 12 13 59 68 3.91×10 16 1.95×10 16 9.77×10 15 4.89×10 15 2.44×10 15 1.22×10 15 14 62 63 1.16×10 15 5.81×10 14 2.91×10 14 1.45×10 14 7.26×10 13 3.63×10 13 15 62 71 2.98×10 17 1.49×10 17 7.44×10 16 3.72×10 16 1.86×10 16 9.30×10 15 16 65 71 2.84×10 17 1.42×10 17 7.09×10 16 3.55×10 16 1.77×10 16 8.87×10 15 17 65 81 2.91×10 20 1.45×10 20 7.27×10 19 3.63×10 19 1.82×10 19 9.08×10 18 18 70 79 6.75×10 19 3.37×10 19 1.69×10 19 78 95 3.97×10 24 1.98×10 24 9.92×10 23 4.96×10 23 2.48×10 23 1.24×10 23 22 84 95 3.68×...…”

“…On the contrary, the figures from Table 5 indicate that the phase shift (separation factor for output channels) enabled by the DT-LFSR Test Pattern Generator (DT-LFSR-TPG) for a specific number of scan chains can be higher by several magnitudes than numbers offered by LFSR+PS and CA+PS solutions disclosed in aforementioned studies. 25 7.28×10 24 3.64×10 24 1.82×10 24 9.10×10 23 4.55×10 23 2.28×10 23 24 91 1.36×10 25 6.80×10 24 3.40×10 24 1.70×10 24 8.50×10 23 4.25×10 23 2.13×10 23…”

“…There are numerous studies where researchers make efforts to improve the solution in terms of hardware overhead, testing time, power consumption, fault coverage, diagnosability, etc. [17][18][19][20][21][22][23][24][25][26]. Some variations of the STUMPS architecture are implemented into hybrid LBIST, where pseudo-random testing is combined with deterministic testing or test data compression [27][28][29][30][31][32].…”

A New, Fast Pseudo-Random Pattern Generator for Advanced Logic Built-In Self-Test Structures

“…The formalization of linguistic meanings within the theory of fuzzy sets is carried out through membership functions (MFs) . The most widespread methods of constructing MFs are based on the statistical processing of expert information and on paired comparisons [4][5][6][18][19][20][21][22][23]. These methods are mainly used in the development of pure expert systems that apply only expert knowledge [7][8][9][10].…”

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