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High-Level Fault Grading

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Title: High-Level Fault Grading


1
High-Level Fault Grading
2
Improving Gate-Level Fault Coverage by RTL Fault
Grading
  • W. Mao and R. K. Gulati, ITC 1996, pp. 150-159.

3
Motivation
  • Gate-level fault simulation is computationally
    infeasible for large circuits
  • RTL design available early in the design cycle
    for fault grading of available (validation or
    legacy) test vectors
  • It would be nice if fault analysis could be done
    at RTL level but the results closely approximated
    gate-level coverage.

4
Basic Idea
  • Inject stuck-type faults on all PIs, internal
    signals, and their fanouts using RTL constructs.
  • Use an RTL fault simulator (e.g. Verifault for
    Verilog) for fault grading at the RTL level
  • Verify the closeness of approximation against
    gate-level fault coverage.

5
Example RTL Model and Signal- Flow Diagram
6
RTL Modified for Fault Injection
7
Testability Analysis Flow
8
Handling Signal Fanouts(Optimistic Mode)
9
Handling Signal Fanouts(Pessimistic Mode)
10
RTL vs. Gate-Level Fault Coverage
11
Critique
  • Technique works well only when the circuit is
    simulated at low-level RTL
  • Errors arise because of
  • Differences in fanouts at the two levels
  • Most signal fanout lot more at the RTL level
    (exception Reset signal)
  • Complex blocks with only I/O visibility
  • The last shortcoming is addressed in the
    stratified sampling approach of Thaker, Agrawal,
    and Zaghloul that we consider next.

12
Stratified Sampling for Fault Coverage of VLSI
Systems
  • Vishwani D. Agrawal
  • Auburn University
  • Collaborators Pradip Thaker and Mona Zaghloul


13
VLSI System Design
Register-transfer level (RTL) design and
verification
90-100 stuck-at fault coverage required
Logic synthesis
Test generation
Timing and physical design
Design and test data for manufacturing
14
Problem
  • Accurately estimate the gate-level fault coverage
    for a VLSI system at the RT-level
  • Advantages
  • Improve test
  • Improve design
  • Avoid expensive design changes
  • Previous approaches do not accurately represent
    gate-level fault coverage (function errors,
    mutation, statement faults, branch faults, etc.)

15
Solution
  • Model faults as representative sample of the
    targeted (gate-level stuck-at) faults.
  • Treat the coverage in an RTL module as a
    statistical sampling estimate.
  • For a multi-module VLSI system, combine module
    coverages according to the stratified sampling
    technique.

16
Outline of Talk
  • Introduction to fault sampling.
  • RTL fault model and application to modules.
  • Coverage in a multi-module system
  • Need for stratified sampling
  • Stratum weights
  • Experimental results
  • Conclusion
  • References

17
Fault Sampling
  • A randomly selected subset (sample) of faults is
    simulated.
  • Measured coverage in the sample is used to
    estimate fault coverage in the entire circuit.
  • Advantage Saving in computing resources (CPU
    time and memory.)
  • Disadvantage Limited data on undetected faults.

18
Random Sampling Model
Detected fault
Undetected fault
All faults with a fixed but unknown coverage
Random picking
Np total number of faults (population
size) C fault coverage (unknown)
Ns sample size Ns ltlt Np
c sample coverage (a random variable)
19
Probability Density of Sample Coverage, c

(x--C )2

-- ------------
1 2s 2 p (x )
Prob(x lt c lt x dx ) -------------- e
s (2
p) 1/2
C (1 - C) Variance, s 2
------------ Ns
Sampling error
s
s
p (x )
Mean C
x
1.0
C 3s
C -3s
x
C
Sample coverage
20
Sampling Error Bounds
C (1 - C ) x - C 3
-------------- 1/2 Ns
Millot, 1923
Solving the quadratic equation for C, we get the
3-sigma (99.8 confidence) estimate
(Agrawal-Kato, 1990)
4.5 C 3s x ------- 1
0.44 Ns x (1 - x )1/2 Ns

Where Ns is sample size and x is the measured
fault coverage in the sample. Example A circuit
with 39,096 faults has an actual fault coverage
of 87.1. The measured coverage in a random
sample of 1,000 faults is 88.7. The
above formula gives an estimate of 88.7 3.
CPU time for sample simulation was about 10 of
that for all faults.

21
An RTL Fault Model(ITC-2000)
  • Language operators are assumed to be fault-free
  • Variables (map onto signal lines) contain faults
  • stuck-at-0
  • stuck-at-1
  • Only one fault is applied at a time (single fault
    assumption)

22
RTL Fault Injection
  • Not affected by faults
  • Synthetic operators - gt lt !
  • Boolean operators
  • Logical operators !
  • Sequential elements (flip-flops latches)
  • Faults introduced in signal variables (stems and
    fan-outs)
  • Separate faults for bits of data words

23
Fault Modeling for Boolean Operators
24
Stem and Fan-out Fault Modeling
  • RTL fan-out faults if(X) then ZY else Z!Y
  • Unique RTL fault is placed on each fan-out of
    each bit of a variable
  • Unique RTL fault on each stem

25
More RTL Faults
26
Observations and Assumption RTL Faults
  • RTL faults may have detection probability
    distribution similar to that of collapsed
    gate-level faults
  • Statistically, an RTL fault-list approximates a
    random sample from the gate-level fault-list
  • Number of RTL faults vs. gate-level faults
    depends on
  • Level of RTL description
  • Synthesis procedure used to convert RTL to gate
    level

27
RTL Fault Simulation
  • Analogous to gate-level approach
  • Faults injected in RTL code of the design
    description by a C parser a logic buffer
    element inserted at fault site (technique
    identical to Mao Gulatis).
  • Fault report contains statistics on detected and
    undetected RTL faults
  • Cadences Verifault-XL used as RTL fault simulator

28
Estimation Error for Module Fault Coverage
  • RTL fault coverage assumed to be an estimate of
    the collapsed gate-fault coverage within
    statistical bound Agrawal and Kato, DT, 1990

a 3.00 for confidence probability of 99.8 c
ratio of detected to total number of RTL faults M
number of gate faults N number of RTL faults,
k 1 - N/M
29
DSP Interface Module(3,168 Gates)
30
RTL Faults and VLSI System Coverage
  • Experimental results demonstrate RTL fault
    coverage of a module to be a good statistical
    estimate of the gate-level fault coverage
  • A VLSI system consists of many interconnected
    modules
  • Overall RTL fault-list of a VLSI system does not
    constitute a representative sample of the
    gate-level fault-list

31
Error at System Level
Gate- level
M1 150 faults 90 cov.
RTL
M1 100 faults 91 cov.
M2 400 faults 40 cov.
M2 100 faults 39 cov.
  • RTL Coverage (0.91 x 100 0.39 x 100) / 200
    65
  • Gate Coverage (0.90 x 150 0.40 x 400) / 550
    54
  • A correct estimation of gate-level fault coverage
    from RTL coverage

91 x (150 / 550) 39 x (400 / 550) 53
32
Application of Stratified Sampling
  • Fault population of a VLSI system divided into
    strata according to RTL module boundaries
  • RTL faults in each module are considered a sample
    of corresponding gate-level faults
  • The stratified RTL coverage is an estimate of the
    gate-level coverage

Wm stratum weight of mth module Gm/G cm RTL
fault coverage of mth module Gm number of
gate-level faults in mth module G number of all
gate-level faults in the system M number of RTL
modules in the system
M C S Wmcm m1
33
Application of Stratified Sampling
C t s
  • Range of coverage,

s2 -------- cm(1 -
cm)
M
Wm
S
where,
rm - 1
m1
rm number of RTL faults in mth module t
value from tables of normal distribution
The technique requires knowledge of stratum
weights and not absolute values of Gm and G
34
Stratum Weight Extraction Techniques
  • Logic synthesis based weight extraction
  • Wm Gm/G
  • Floor-planning based weight extraction
  • Wm Am/A
  • Entropy-measure based weight extraction

35
Experimental Procedure
  • Technology-dependent weight extraction
  • Several unique gate-level netlists obtained by
    logic synthesis from the same RTL code
  • Each synthesis run performed using a different
    set of constraints, e.g., area optimization
    (netlist 1), speed optimization (netlist 2), or
    combined area and speed optimizations (netlists 3
    and 4)
  • Strata weights calculated using gate-level fault
    lists of various synthesized netlists
  • Technology-independent weight extraction
  • Stratum weights calculated using area
    distribution among modules
  • Each set of stratum weights used to calculate RTL
    fault coverage and error bounds
  • Impact of estimation error investigated

36
Experimental Data Weight Distributions
37
Experimental Data RTL Fault Coverage
38
Experimental Data Error Bounds
39
Timing Controller ASIC (17,126 Gates)
40
A DSP ASIC(104,881 Gates)
41
Conclusion
  • Main ideas of RTL fault modeling
  • A small or high-level RTL module contributes few
    RTL faults, but large statistical tolerance gives
    a correct coverage estimate
  • Stratified sampling accounts for varying module
    sizes and for different RTL details that may be
    used
  • Stratum weights appear to be insensitive to
    specific details of synthesis
  • Advantages of the proposed RTL fault model
  • High-level test generation and evaluation
  • Early identification of hard-to-test RTL
    architectures
  • Potential for significantly reducing run-time
    penalty of the gate-level fault simulation

42
References - 1
  • V. D. Agrawal, Sampling Techniques for
    Determining Fault Coverage in LSI Circuits, J.
    Digital Systems, vol. V, no. 3, pp. 189-202,
    1981.
  • V. D. Agrawal and H. Kato, Fault Sampling
    Revisited, IEEE Design Test of Computers, vol.
    7, no. 4, pp. 32-35, Aug. 1990.
  • P. A. Thaker, M. E. Zaghloul, and M. B. Amin,
    Study of Correlation of Testability Aspects of
    RTL Description and Resulting Structural
    Implementation, Proc. 12th Int. Conf. VLSI
    Design, Jan. 1999, pp. 256-259.
  • P. A. Thaker, V. D. Agrawal, and M. E. Zaghloul,
    Validation Vector Grade (VVG) A New Coverage
    Metric for Validation and Test, Proc. 17th IEEE
    VLSI Test Symp., Apr. 1999, pp. 182-188.

43
References - 2
  • P. A. Thaker, Register-Transfer Level Fault
    Modeling and Evaluation Techniques, PhD Thesis,
    George Washington University, Washington, D.C.,
    May 2000.
  • P. A. Thaker, V. D. Agrawal, and M. E. Zaghloul,
    Register-Transfer Level Fault Modeling and Test
    Evaluation Techniques for VLSI Circuits, Proc.
    Int. Test Conf., Oct. 2000, pp. 940-949.
  • This presentation is available from the website
    http//cm.bell-labs.com/cm/cs/who/va

44
Other Related Papers
  • OCCOM Fallah et al., IEEE TCAD, Aug. 2001, pp.
    1003-1015.
  • IFMB Santos et al., ITC2001, pp. 377-385.
  • Probabilistic Testability Fernandes et al.,
    DATE04, pp. 10176-10181.
  • Kang et al., VTS07.
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