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Encountering Gate Oxide Breakdown with Shadow Transistors to Increase Reliability Claas Cornelius1, Frank Sill2, Hagen Sämrow1, Jakob Salzmann1, Dirk Timmermann1, Diógenes Cecílio da Silva Jr.2 1University of Rostock, Germany 2 Federal University of Minas Gerais (UFMG), Brazil Gramado, 3rd September 2008 1 Focus / Main ideas 1. Reliability regarding oxide breakdown 2. Transistor / Gate level approach 3. Selective insertion / thick oxide devices Cornelius et. al: Shadow Transistors 2 Outline Motivation – Technology development – Error classification – Time-Dependent Dielectric Breakdown (TDDB) Shadow Transistors – Used model – Main Ideas – Algorithm Results Conclusion Cornelius et. al: Shadow Transistors 3 Motivation Technology development [Mill.] Transistors [Mill.] Transistors 130 nm 400 400 90 nm 300 300 100 100 0 0 100 nm Yonah 65 nm 151 Mill. 200 200 150 nm Technology Wolfdale 410 Mill. 500 500 Prescott 125 Mill. 45 nm 50 nm Northwood 55 Mill. Yonah, 151 Mill. 0 nm 2002 2002 2004 2004 Year Year 2006 2006 2008 2008 Probability for failures increases due to: Increasing transistor count Shrinking technology Cornelius et. al: Shadow Transistors 4 Motivation Error classification Error Temporary Permanent Soft errors, Voltage drop, Coupling, … Reduced Performance Process variations, Electromigration, Oxide wearout ... Oxide wearout Cornelius et. al: Shadow Transistors Malfunction Electromigration, Oxide breakdown ... Oxide breakdown 5 Motivation Time-Dependent Dielectric Breakdown (TDDB) Tunneling currents Wear out of gate oxide Creation of conducting path between Gate and Substrate, Drain, Source Depending on electrical field over gate oxide, temperature (exp.), Source: Pey&Tung and gate oxide thickness (exp.) Also: abrupt damage due to extreme overvoltage (e.g. ElectroStatic Discharge) Source: Pey&Tung Cornelius et. al: Shadow Transistors 6 Motivation TDDB ─ Trends 10000 16 Current Density Jox Reliability (Weibull slope β) Increasing probability for Gate-Oxide-Breakdown 12 8 4 0 1000 100 high-k? 10 1 0 2 4 6 8 10 12 Gate Oxide Thickness [nm] Source: Kauerauf, EDL, 2002 Cornelius et. al: Shadow Transistors 180 nm 90 nm 45 nm 22 nm Technology Source: Borkar, Intel 7 Shadow Transistors Applied model TDDB between gate and channel Gate For an Inverter, 65nm-BPTM: Gate Oxide Source Drain 100% 20 75% 15 50% Model: RGC W W1 W2 W= W1+W2 Cornelius et. al: Shadow Transistors Vout/VDD rel. delay 10 25% 5 0% 0 - RGC [kΩ] → Based on: Segura et. al., “A Detailed Analysis of GOS Defects in MOS Transistors: Testing Implications at Circuit Level” 1995. 8 Shadow Transistors Applied model TDDB between gate and source/drain Gate For an Inverter, 65nm-BPTM: Gate Oxide Source Drain 100% 75% Vout/VDD 50% Model: 25% RGD RGS W W 0% -RGC [kΩ] → Based on: Segura et. al., “A Detailed Analysis of GOS Defects in MOS Transistors: Testing Implications at Circuit Level” 1995. Cornelius et. al: Shadow Transistors 9 Shadow Transistors Main idea (1) ─ Parallel transistors 1. Insertion of additional transistors in parallel to vulnerable transistors Shadow transistors (ST) VDD/Vout Relative Delay 10 8 6 4 2 0 100% wo/ ST 75% w/ ST 50% w/ ST wo/ ST 25% 0% R - GC [kΩ] → -R GC [kΩ] → For an Inverter, 65nm-BPTM Cornelius et. al: Shadow Transistors 10 Shadow Transistors Main idea (2) ─ Thick gate oxides H-Vt/To 2. Application of H-Vt/To transistors with: – Higher threshold voltage – Thicker gate oxide Less vulnerable to TDDB 10 tox 0.22 MTTF – Mean Time To Failure 0.15 MTTFH Vt / To 10 0.22 4.81 MTTFLVt / To Source: Srinivasan, “RAMP: A Model for Reliability Aware Microprocessor Design” Stathis, J., “Reliability Limits for the Gate Insulator in CMOS Technology” Cornelius et. al: Shadow Transistors 11 Shadow Transistors Main idea (3) ─ Selective insertion 3. Selective insertion of shadow transistors in parallel to vulnerable transistors: – Component reliability depends on Activity, state, temperature, size, fabrication … Most vulnerable can be identified Netlist modification Cornelius et. al: Shadow Transistors Shadow transistors only added in parallel to most vulnerable devices. 12 Shadow Transistors Main idea (3) ─ Selective insertion 3. Selective insertion of shadow transistors in parallel to vulnerable transistors: – Component reliability depends on Our Approach Activity, state, temperature, size, fabrication … Estimation of stress factors Most vulnerable can be identified Determination of components reliability Adding redundancy only at most vulnerable components Advantage: Lower area, power and delay penalty compared to complete redundancy or random insertion [Sri04] Shadow transistors Source: [Sri04] Sirisantana, D&T, 2004 Netlist only added in parallel modification to most vulnerable devices. Cornelius et. al: Shadow Transistors 13 Shadow Transistors Main ideas ─ Discussion Advantages Increased reliability in respect to TDDB H-Vt/To: Reliability increases by ~5x (for Δtox = 0.15 nm) Remarkable increase of system life time Drawbacks Higher input capacity → higher delay and dynamic power dissipation Area increase Remarks Only slight improvements for Gate-Drain/Source breakdown H-Vt/To has to be supported by technology Cornelius et. al: Shadow Transistors 14 Shadow Transistors Algorithm Estimation of logical Signal Probabilities (SP) Insertion of Shadow transistors where SP is lower (PMOS) than threshold value SPth or higher (NMOS) than 1 - SPth Modification of SPth depending on Δtd / MTTF Estimation of delay increase Δtd and new Mean Time To Failure (MTTF) Cornelius et. al: Shadow Transistors 15 Results Improvemnet of MTTF as regards TDDB Improvement MTTF (L-Vt/To) ≈ 23 % additional transistors 20% 15% 10% 5% 0% c17 c432 c499 c880 c1355 c1908 c2670 c3540 c5315 c6288 c7552 our algorithm random insertion Insertion of L-Vt/To Shadow Transistors Cornelius et. al: Shadow Transistors 16 Results Performance Reduction (L-Vt/To) ≈ 23 % additional transistors Increase of circuit's delay 20% 15% 10% 5% 0% c17 c432 c499 c880 c1355 c1908 c2670 c3540 c5315 c6288 c7552 our algorithm random insertion Insertion of L-Vt/To Shadow Transistors Cornelius et. al: Shadow Transistors 17 Results Application of H-Vt/To-ST Improvemnet of MTTF as regards TDDB ≈ 23 % additional transistors 60% 45% 30% 15% 0% c432 c499 c880 c1355 c1908 c2670 c3540 c5315 c6288 c7552 H-Vt/To-ST Cornelius et. al: Shadow Transistors L-Vt-To-ST 18 Results Improvemnet of MTTF as regards TDDB Modification of Ccrit 250% 200% 150% 100% 50% 0% c432 c499 c880 c1355 c1908 c2670 c3540 c5315 c6288 c7552 SPth = 30 SPth = 55 Insertion of H-Vt/To Shadow Transistors Cornelius et. al: Shadow Transistors 19 Conclusion System reliability decreases with shrinking technologies and rising transistor count Increasing probability of Time-Dependent Dielectric Breakdown (TDDB) Insertion of Shadow Transistors (ST) increases system lifetime Remarkable improvements by application of transistors with thick gate-oxide Selective insertion of ST improves trade-off between reliability and performance Impact and amount of redundant transistors can be adapted by the threshold value SPth Cornelius et. al: Shadow Transistors 20 Thank you! 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