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Weighted Random and Transition Density Patterns for Scan-BIST

Weighted Random and Transition Density Patterns for Scan-BIST. Farhana Rashid* Vishwani D. Agrawal Auburn University ECE Department, Auburn, Alabama 36849 * Presently with Intel Corp., Austin, Texas 78746. A BIST Architecture. p 1 = Prob {bit = 1}, or TD = Prob {bit makes transition}.

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Weighted Random and Transition Density Patterns for Scan-BIST

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  1. Weighted Random and Transition Density Patterns for Scan-BIST Farhana Rashid* Vishwani D. Agrawal Auburn University ECE Department, Auburn, Alabama 36849 * Presently with Intel Corp., Austin, Texas 78746 NATW'12: Rashid and Agrawal

  2. A BIST Architecture p1 = Prob{bit = 1}, or TD = Prob{bit makes transition} TPG SAR Combinational Logic PO PI NATW'12: Rashid and Agrawal

  3. WRP and TDP LFSR • Random pattern: • 0100101110, p1 = 0.5 • Weighted random patterns (WRP): • 1011101101, p1 = 0.7 • 0010011000, p1 = 0.3 • Transition density patterns (TDP): • 0111001011, TD = 0.5 • 1101001001, TD = 0.7 • 0011101111, TD = 0.3 Random patterns LOGIC WRP FF TDP NATW'12: Rashid and Agrawal

  4. Outline Motivation Problem Statement and Contribution Introduction and Background Fault coverage analysis of WRP and TDP for scan-BIST Test Time reduction by using dynamically adapted scan clock Results Conclusion and future work NATW'12: Rashid and Agrawal

  5. Motivation Design BIST for High coverage Satisfying power constrain Reduced test time NATW'12: Rashid and Agrawal

  6. Problem Statement and Contribution • Examineeffect of weighted random patterns and transition density patterns on fault coverage. • Reduce test application time for test-per-scan BIST. • Proposed solution: • Pre-select weighted random patterns or transition density patterns to produce high coveragetest with shortest test length. • Further reduce test time with adaptive activity-driven scan clock. NATW'12: Rashid and Agrawal

  7. Performance of Weighted Random Patterns (WRP) • Number of test per scan vectors for 95% coverage s1269 NATW'12: Rashid and Agrawal

  8. Performance of Transition Density Patterns (TDP) • Number of test per scan vectors for 95% coverage s1269 NATW'12: Rashid and Agrawal

  9. Best WRP and TDP for 95% Fault Coverage NATW'12: Rashid and Agrawal

  10. BIST-TPG for WRP and TDP NATW'12: Rashid and Agrawal

  11. TDP and WRP of s1512 for 95% Coverage WRP p1 = 0.75 768 vectors TD = 0.25 406 vectors NATW'12: Rashid and Agrawal

  12. Adaptive TestClock for BIST NATW'12: Rashid and Agrawal

  13. 90% Fault Coverage BIST, 25-100MHz Adaptive Clock NATW'12: Rashid and Agrawal

  14. Conclusion • Low toggle rate vectors, often suggested for reducing test power, generally cause slow rise in fault coverage and result in increased test time. • We show that a proper weight or transition density, which is circuit dependent, can be best for fault coverage. • Any, low or high,toggle rate can be used for quicker fault coverage withadaptive scan clock for an overall reduction in test time. • Combining multiple transition densities or weights can further reduce test time and/or enhance fault coverage; see my thesis referenced in the paper. NATW'12: Rashid and Agrawal

  15. References • F. Rashid, “Controlled Transition Density Based Power Constrained Scan-BIST with Reduced Test Time,” Master’s thesis, Auburn University, Alabama, USA, May 2012. • P. Shanmugasundaram and V. D. Agrawal, “Dynamic Scan Clock Control for Test Time Reduction Maintaining Peak Power Limit,” in Proc. 29th IEEE VLSI Test Symp., May 2011, pp. 248–253. NATW'12: Rashid and Agrawal

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