1. Independence Fault Collapsing
Alok S. Doshi (Speaker)
Vishwani D. Agrawal
Auburn University, Department of Electrical and Computer Engineering Auburn, AL 36849, USA
Aug.13, 2005
VDAT05: Doshi and Agrawal

2. VDAT05: Doshi and Agrawal
Outline
Motivation
Fault Classification
Independence Graph and Matrix
Independence Fault Collapsing
Concurrent Test Generation
Conclusions and Future Work
Aug.13, 2005
VDAT05: Doshi and Agrawal

3. C17 - ISCAS85 Benchmark Circuit
Motivation
ATPG
Tests
Hitec1 10
Fastest2 7
Gentest3 a x b c y d e
C17 - ISCAS85 Benchmark Circuit
Minimum 4
1 T. M. Niermann and J. H. Patel, “HITEC: A Test Generation Package for Sequential Circuits,” Proc. European Design Automation Conference, Feb. 1991, pp
2 T. P. Kelsey, K. K. Saluja, and S. Y. Lee, “An Efficient Algorithm for Sequential Circuit Test Generation,” IEEE Trans. Computers, vol. 42, no. 11, pp , Nov
3 W. T. Cheng and T. J. Chakraborty, “Gentest: An Automatic Test Generation System for Sequential Circuits,” Computer, vol. 22, no. 4, pp. 43–49, April 1989.
Aug.13, 2005
VDAT05: Doshi and Agrawal

4. VDAT05: Doshi and Agrawal
Fault Classification
Aug.13, 2005
VDAT05: Doshi and Agrawal

5. VDAT05: Doshi and Agrawal
Definitions
Independent Faults4:
Two faults are independent if and only if they cannot be detected by the same test vector.
Concurrently-Testable Faults:
Two faults that neither have a dominance relationship nor are independent, are defined as concurrently-testable faults.
4 S. B. Akers, C. Joseph, and B. Krishnamurthy, “On the role of Independent Fault Sets in the Generation of Minimal Test Sets,” in Proc. International Test Conf., 1987, pp
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VDAT05: Doshi and Agrawal

6. Structural Independences
sa1
sa1
sa0
sa1
sa1
sa0
sa1
sa1
sa1
sa0
sa0
sa0
sa1
sa0
sa1
sa0
sa0
sa0
sa1
sa0
Aug.13, 2005
VDAT05: Doshi and Agrawal

7. Implied Independences
Equivalence implied independence:
If two faults are equivalent then all faults that are independent of one fault are also independent of the other fault.
Dominance implied independence:
If one fault dominates a second fault then all faults that are independent of the first fault are also independent of the second fault.
Aug.13, 2005
VDAT05: Doshi and Agrawal

8. Functional Independences
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VDAT05: Doshi and Agrawal

9. C17 - ISCAS85 Benchmark Circuit
Example Circuit
2-1
4-1 a x
5-1
1-1 b
3-1
7-1 c
11-1 y d
6-1
10-1
9-1 e
8-1
C17 - ISCAS85 Benchmark Circuit
5 R. K. K. R. Sandireddy and V. D. Agrawal, “Diagnostic and Detection Fault Collapsing for Multiple Output Circuits," in Proc. Design, Automation and Test in Europe (DATE) Conf., Mar. 2005, pp
Aug.13, 2005
VDAT05: Doshi and Agrawal

10. Independence Matrix and GraphF 1 2 3 4 5 6 7 8 9 10 11
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VDAT05: Doshi and Agrawal

11. VDAT05: Doshi and Agrawal
Clique
A clique is defined as a fully-connected subgraph, i.e., a subgraph in which every node is connected to every other node.
A lower bound on the number of tests required to cover all faults of an irredundant combinational circuit is given by the size of the largest clique of the independence graph.
Aug.13, 2005
VDAT05: Doshi and Agrawal

12. VDAT05: Doshi and Agrawal
Cliques
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VDAT05: Doshi and Agrawal

13. Degree of Independence
This is the number of edges attached to the fault node and is computed for the ith fault by adding all the elements of either the ith row or the ith column of the independence matrix.
DI (ith fault) = Σ xij = Σ xji N N
j=1
i=1
Aug.13, 2005
VDAT05: Doshi and Agrawal

14. Degree of Independence
Fault 1 2 3 4 5 6 7 8 9 10 11 DI
Aug.13, 2005
VDAT05: Doshi and Agrawal

15. VDAT05: Doshi and Agrawal
Similarity Metric
Similarity Metric:
This is a measure defined for a pair of faults that determines how similar they are in their independence and concurrent-testability with respect to the entire fault set of the circuit.
SIM (fault-i, fault-j) = Nxij + (1-xij) Σ |xik-xjk| N
k=1
Aug.13, 2005
VDAT05: Doshi and Agrawal

16. VDAT05: Doshi and Agrawal
Similarity Metrics
Fault 1 2 3 4 5 6 7 8 9 10 11
Aug.13, 2005
VDAT05: Doshi and Agrawal

17. Independence Collapsing
Fault 1 3 5 8 9 11 7 2 4 6 10 DI
Aug.13, 2005
VDAT05: Doshi and Agrawal

18. Independence CollapsingF 1 3 5 8 9 11 7 2 4 6 10 11 4 11 3
1,8 1
5,11,7
5,11 5
3,9,2
3,9 3
4,6,10
4,6 4 11 4 6
Similarity index for fault F for each existing node i:
Max. SIM (F, kth fault of node i)
where k = 1…..K, and K is number of faults in node i.
Aug.13, 2005
VDAT05: Doshi and Agrawal

19. Concurrent test generation for C17
2-1
4-1 a x
5-1
1-1 b
3-1
7-1 c
11-1 y d
6-1
10-1
9-1
Fault Targets
Test
(a b c d e)
1,8
10010
3,9,2
01111
5,11,7
X1010
4,6,10
10101 e
8-1
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VDAT05: Doshi and Agrawal

20. VDAT05: Doshi and Agrawal
Results (ALU – 74181)
Node
Number of faults
Test vectors
no.
Total
Targeted
Detected from
Cumulative
this
node
other
nodes
coverage 1 5 6 11 2 3 16 8 7 26 4 32
101x 39 47 54 14 66 9 72 10 77 1x 81 12 84 1x
Aug.13, 2005
VDAT05: Doshi and Agrawal

21. Conclusions and Future Work
Faults are reclassified into four classes:
Equivalent
Dominant
Independent
Concurrently-testable (also called compatible in the literature)
A new fault collapsing algorithm based on Independent Faults is introduced.
This algorithm frequently collapses the graph into a minimal clique.
This work motivates the need for ATPG algorithms for concurrent fault targets.
The problem of completely determining all edges of the independence graph is complex.
The algorithm needs to be extended for incompletely – specified independence graph.
Aug.13, 2005
VDAT05: Doshi and Agrawal

22. VDAT05: Doshi and Agrawal
Thank You!
Aug.13, 2005
VDAT05: Doshi and Agrawal