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Robust Low Power VLSI ECE 7502 S2015 Minimum Supply Voltage and Very- Low-Voltage Testing ECE 7502 Class Discussion Elena Weinberg Thursday, April 16,

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Presentation on theme: "Robust Low Power VLSI ECE 7502 S2015 Minimum Supply Voltage and Very- Low-Voltage Testing ECE 7502 Class Discussion Elena Weinberg Thursday, April 16,"— Presentation transcript:

1 Robust Low Power VLSI ECE 7502 S2015 Minimum Supply Voltage and Very- Low-Voltage Testing ECE 7502 Class Discussion Elena Weinberg Thursday, April 16, 2015

2 Robust Low Power VLSI Requirements Specification Architecture Logic / Circuits Physical Design Fabrication Manufacturing Test Packaging Test PCB Test System Test PCB Architecture PCB Circuits PCB Physical Design PCB Fabrication Design and Test Development Customer Validate Verify Post Silicon Verification Test

3 Robust Low Power VLSI Low voltage testing  THE IDEA: ICs with defects more likely to fail at lower voltages  Can we determine a defective chip based on the voltage at which an IC fails?  Idea proposed in [1] in 1993 3

4 Robust Low Power VLSI Approaches  Very-low-voltage (VLV) testing [1]  MINVDD testing [2]  Low VDD vs. delay correlation metric [4]  Selecting optimal VDD for test [5] 4

5 Robust Low Power VLSI Challenges for low voltage testing  Time consuming  Scaling  higher impacts from variations  How low is low enough? What is an optimal VDD selection? 5

6 Robust Low Power VLSI VLV testing [1]  Test chips with very low supply voltage  “Weak” ICs fail when “good” ICs do not  Simple—no design for testability required  Detects resistive shorts and hot carrier effects 6

7 Robust Low Power VLSI Resistive short 7 [1] Hao et al, TC’93

8 Robust Low Power VLSI  Increased threshold voltage (V T )  Decreased transconductance (proportional to mobility)  Increased substrate current in FET  oxide degradation 8 Hot carrier effects V T shifted 0.3V [1] Hao et al, TC’93

9 Robust Low Power VLSI Applications [1]  Built-in self test (BIST)  Production test  Detects weak chips due to resistive shorts  Preventative test  high reliability in field  In-system test performed periodically (e.g. at power up)  System degradation detected before failure occurs  Diagnostic test 9

10 Robust Low Power VLSI VLV results [1] 10 [1] Hao et al, TC’93

11 Robust Low Power VLSI VLV results [1] (2)  Done in conjunction with  IDDQ testing, burn-in testing  Detected delay faults  Advantage: simplicity and applicability  Disadvantage: time consuming 11

12 Robust Low Power VLSI MINVDD testing [2]  Builds on [1]  Determine the minimum supply voltage at which a circuit continues to switch  Below this VDD, the circuit no longer switches  “Weak” ICs are determined by their minimum supply voltage  Higher than for “good” ICs  Detects  Metal shorts  Gate-oxide shorts  V T shifts (global and local)  Tunneling opens 12 [2] Tseng et al, VLSITS’01

13 Robust Low Power VLSI MINVDD testing [2] (2)  Metal shorts  Gate oxide shorts ^ Significantly higher minVDD for circuits with shorts  V T shifts: larger shift => larger minVDD  minVDD of good chip should be slightly above V T  Tunneling opens  Higher delay 13 [2] Tseng et al, VLSITS’01

14 Robust Low Power VLSI Results [2]  320 Murphy CUTs (circuits under test)  195 good  116 defective  9 VLV-only 14 [2] Tseng et al, VLSITS’01

15 Robust Low Power VLSI Low VDD vs. Delay [4]  How to determine limit value with parameter variations?  Popular method: correlate supply voltage reduction to induced change in circuit delay  Delay variation-dependence with lower VDD not explored  As VDD  V T  impact of parameter variations on delay 15 [4] Bota et al, VLSITS’06

16 Robust Low Power VLSI Reduce Test Time for Power Constrained Circuits [5]  Optimal selection of VDD  Power constraints  Fastest clock speed 16 [5] Venkataramani et al, VLSID’13 T = Test clock period E MAX(test) = Max energy dissipated during vector period P MAX(func) = Max allowable power obtained from functional simulation Min VDD is optimum

17 Robust Low Power VLSI 17 [5] Venkataramani et al, VLSID’13 Max allowable power during functional op. Percentage reduction achieved through proposed method

18 Robust Low Power VLSI Other related techniques  [6] evaluates functionality of SRAM at low VDD  [3] evaluates trade-off between maximum defect coverage and lowest test cost  “You can test for all of the defects part of the time, part of the defects all of the time but you cannot test for all the defects all of the time!” (Madge et al, TC’04)  Min VDD testing often used in conjunction with other techniques, much like IDDQ testing 18

19 Robust Low Power VLSI Conclusion  Low voltage testing techniques are useful as a first step to defect detection, however, they are time consuming and detect a limited number of faults. 19

20 Robust Low Power VLSI Discussion questions 1.What are the limitations of min VDD testing? 2.Could standard min VDD testing be applied to circuit components designed to operate in sub-threshold? 3.With the sensitivity to variations that nearly all modern circuits experience from scaling, is min VDD testing still effective? 4.What are some other applications of min VDD or VLV testing? Are there any other ways these techniques could be used in the testing process? 5.How can we best manage the trade-off between lowest test cost and maximum defect coverage? 20

21 Robust Low Power VLSI Papers  [1] Hao, Hong, and Edward J. McCluskey. "Very-low-voltage testing for weak CMOS logic ICs." Test Conference, 1993. Proceedings., International. IEEE, 1993.  [2] Tseng, Chao-Wen, et al. "MINVDD testing for weak CMOS ICs." VLSI Test Symposium, 19th IEEE Proceedings on. VTS 2001. IEEE, 2001.  [3] Madge, Robert, et al. "In search of the optimum test set-adaptive test methods for maximum defect coverage and lowest test cost." Test Conference, 2004.  [4] Bota, Sebastiàn A., et al. "Low v/sub dd/vs. delay: is it really a good correlation metric for nanometer ics?." VLSI Test Symposium, 2006. Proceedings. 24th IEEE.  [5] Venkataramani, Praveen, and Vishwani D. Agrawal. "Reducing test time of power constrained test by optimal selection of supply voltage." VLSI Design and 2013 12th International Conference on Embedded Systems (VLSID), 2013 26th International Conference on. IEEE, 2013.  [6] Gottscho, Mark, et al. "Power/capacity scaling: energy savings with simple fault- tolerant caches." Proc. DAC. 2014. 21

22 Robust Low Power VLSI Paper Map 22  [1] Hao, H.; …"Very-low-voltage testing …," TC’93.  [2] Tseng, C.; …"MINVDD testing for …," VLSITS’01.  [3] Madge, R.; …"In search of the optimum …," TC’04.  [4] Bota, S.; …"Low v/sub dd/vs. delay: is …," VLSITS’06.  [5] Venkataramani, P.; …"Reducing test time …," VLSID’13.  [6] Gottscho, Mark, et al. "Power/capacity scaling: …,” DAC’14. [1] Proposed very-low-voltage (VLV) testing [2] Proposed min VDD testing [4] Low VDD vs. Delay comparison [6] More related to sub-VT, but involves low voltage testing [2] builds on [1] [5] Optimal selection of VDD [4] evaluates effectiveness of methodology in [2] [3] Managing trade-offs in test

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