Pre-Computed Asynchronous Scan Invited Talk

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Pre-Computed Asynchronous Scan Invited Talk Vishwani D. Agrawal James J. Danaher Professor Electrical and Computer Engineering Auburn University, USA With help from Praveen Venkataramani, PhD Candidate Quito, Ecuador, April 13, 2012

Agrawal: Asynchronous Scan Scan Testing PI PO SFF Combinational logic SCANOUT SFF SFF SE or TCK Not shown: CK or MCK/SCK feed all SFFs. SCANIN LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Test Time Total scan test time (Number of scan test clock cycles × clock period): TT = NT = [(ncomb + 2) nsff + ncomb + 4] × T Where, ncomb = number of combinational vectors nsff = number scan flip-flops in the longest scan chain T = scan clock period Example: 10,000 scan flip-flops in longest chain, 1,000 comb. vectors, total scan test length, TT ≈ 107 T. Reference: M. L. Bushnell and V. D. Agrawal, Essentials of Electronic Testing for Digital, Memory and Mixed- Signal VLSI Circuits, Springer, 2000. LATW, April 13, 2012 Agrawal: Asynchronous Scan

Scan Power During a Clock Cycle Chip current, i(t) time Clock period, T T Cycle energy, E = VDD ∫ i(t) dt Cycle power, P = E/T LATW, April 13, 2012 Agrawal: Asynchronous Scan

Scan Power During Test With Synchronous Clock Emax E Cycle Energy, E Pmax P Cycle power, P P E E E E P E E P P P P P 1 2 3 4 5 6 7 8 Clock cycles T T T T T T T T Scan clock period, T = Emax/Pmax LATW, April 13, 2012 Agrawal: Asynchronous Scan

Test Time for Synchronous Clock N Emax TTsync = NT = ———— Pmax Where, N = Number of scan test clock cycles LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Power vs. Time Reduce power: Use low activity vectors ⇒ slower rise in fault coverage ⇒ more vectors ⇒ longer test time Reduce test time: Use high efficiency vectors ⇒ produce high activity ⇒ increase test power LATW, April 13, 2012 Agrawal: Asynchronous Scan

Can We Speed Up Scan Testing? Maximum clock speed is limited by Emax of vectors and Pmax of circuit; T ≥ Emax/Pmax. For most cycles E << Emax ⇒ reduce period. Structural limits on clock period: Critical path delay (functional and scan) Set up and hold times < critical path delay A variable clock period can be shorter than the global (synchronous) power constrained period, T = Emax/Pmax. LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Pre-compute energy {Ei} for all clock cycles {i}. For given power constrain Pmax of the circuit, set the period Ti of ith clock cycle as: Ti = max {Ei/Pmax, critical path delay} = Ei/Pmax, for power constrained testing Where critical path delay can be different for scan and normal mode cycles. LATW, April 13, 2012 Agrawal: Asynchronous Scan

Scan Power During Test With Asynchronous Clock Emax E Cycle Energy, E Pmax P P P P P P P P Cycle power, P E E E E E E 1 2 3 4 5 6 7 8 Clock cycle, i T1 T2 T3 T4 T5 T6 T7 T8 Scan clock period, Ti = Ei/Pmax LATW, April 13, 2012 Agrawal: Asynchronous Scan

Test Time for Asynchronous Clock N N TTasyn = Σ Ti = Σ Ei/Pmax i=1 i=1 N 1 N = ——— × — Σ Ei Pmax N i=1 N Eav Etotal = ——— = ——— Pmax Pmax LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Comparing Two Scans 200 150 100 50 Emax/Eav = 4 Test time (arbitrary units) TTsync TTasyn Pmax LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Test Time Reduction N Emax TTsync = ———— Pmax N Eav Etotal TTasyn = ——— = ——— Pmax Pmax TTsync/TTasyn = Emax/Eav ≥ 1 LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Theorem For any given Pmax, minimum test time has a lower bound, obtained upon dividing the smallest synchronous scan test time by the Emax/Eav ratio. This lower bound is achieved by asynchronous scan when every cycle consumes Pmax. LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Comparing Tests Emax/Eav = 2 1.0 0.5 0.0 Energy time Emax/Eav = 5 1.0 0.5 0.0 Low power test Energy time LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Spice Simulation: s289 (14FF) Scan Test Pmax= 0.711 mW Asynchronous clock Synchronous clock, T = 40ns Pav = 0.455 mW TTasyn Circuit s289 Total Test patterns = 33 ATPG patterns + 2 Additional set of patterns with alternate 1’s and 0’s Pmax= 0.711 mW Pavg = 0.455 mW Test cycles = 14 Scan shift cycles + 1 Capture cycle Synchronous clock period = 40ns Test Time Synchronous= 21.010 µs Test Time Asynchronous= 13.459 µs Gain=1.562 TTsync, 40ns clock LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Spice Simulation: s289 (14FF) Scan Test Pmax= 0.356 mW Asynchronous clock Synchronous clock, T = 80ns Pav = 0.228 mW TTasyn Circuit s289 Total Test patterns = 33 ATPG patterns + 2 Additional set of patterns with alternate 1’s and 0’s Pmax= 0.356 mW Pavg = 0.228 mW Test cycles = 14 Scan shift cycles + 1 Capture cycle Synchronous clock period = 40ns Test Time Synchronous= 42.021 µs Test Time Asynchronous= 26.902 µs Gain=1.562 TTsync, 80ns clock LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Spice Simulation: s289 (14FF) Scan Test Asynchronous clock Synchronous clock, T = 80ns Pav = 0.228 mW Circuit s289 Total Test patterns = 33 ATPG patterns + 2 Additional set of patterns with alternate 1’s and 0’s Pmax= 0.228 mW Pavg = 0.228 mW Test cycles = 14 Scan shift cycles + 1 Capture cycle Synchronous clock period = 40ns Test Time Synchronous= 42.021 µs Test Time Asynchronous= 42.021 µs Gain=1 LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Spice Simulation: s298 Test Time Ratio Test Time Synchronous Test Time Asynchronous = 1.54 Test Time (Synchronous) Test Time (Asynchronous) Test time Gain = (Test Time Synchronous clock)/(Test time adaptive clock) Synchronous Clock Asynchronous Clock Test Time Synchronous Test Time Asynchronous Ratio 0.711 0.711 19.81 12.83 1.544 0.532 0.532 26.41 16.17 1.634 0.385 0.385 39.62 23.58 1.680 0.238 0.238 59.43 38.45 1.546 0.179 0.179 79.24 51.14 1.549 0.143 0.143 99.05 63.95 1.549 0.118 0.118 118.86 77.32 1.537 LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Spice Simulation: s713 Scan Test Asynchronous clock Synchronous clock, T 40ns Pmax = 1.06mW Pav = 0.53mW Circuit: s713 Total Vectors = 60 Atpg vectors Constant clock period = 40ns Gain: 2 LATW, April 13, 2012 Agrawal: Asynchronous Scan

Agrawal: Asynchronous Scan Conclusion Total test energy (Etotal) is invariant for a test. Cycle power (Pmax) is a circuit characteristic. For power constrained scan testing, Synchronous clock test time = Etotal/Pav Asynchronous clock test time = Etotal/Pmax Asynch. clock test will benefit from low energy tests. Recent work on adaptive clock BIST (VTS’11, VLSI Design’12, etc.). Future explorations may investigate energy reduction techniques like reduced voltage testing. Test programming for asynchronous clock needs to be worked out. LATW, April 13, 2012 Agrawal: Asynchronous Scan

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