1. Manufacturing Testing

2. Manufacturing Testing
What is testing?
Apply the input stimuli, test vector, to DUT
Observe the response from DUT, and compare with expected results
How?
Fast and exact
Automation

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23. Fault Modeling Why model faults? Some real defects in VLSI and PCB
Common fault models
Stuck-at faults
Single stuck-at faults
Fault equivalence
Fault dominance and checkpoint theorem
Classes of stuck-at faults and multiple faults
Transistor faults
Bushnell & Agrawal (KAP)

24. Why Model Faults?
I/O function tests inadequate for manufacturing (functionality versus component and interconnect testing)
Real defects (often mechanical) too numerous and often not analyzable
A fault model identifies targets for testing
A fault model makes analysis possible
Effectiveness measurable by experiments
Bushnell & Agrawal (KAP)

25. Some Real Defects in Chips
Processing defects
Missing contact windows
Parasitic transistors
Oxide breakdown
. . .
Material defects
Bulk defects (cracks, crystal imperfections)
Surface impurities (ion migration)
Time-dependent failures
Dielectric breakdown
Electromigration
Packaging failures
Contact degradation
Seal leaks
Ref.: M. J. Howes and D. V. Morgan, Reliability and Degradation -
Semiconductor Devices and Circuits, Wiley, 1981.
Bushnell & Agrawal (KAP)

26. Occurrence frequency (%)
Observed PCB Defects
Defect classes
Shorts
Opens
Missing components
Wrong components
Reversed components
Bent leads
Analog specifications
Digital logic
Performance (timing)
Occurrence frequency (%) 51 1 6 13 8 5
Ref.: J. Bateson, In-Circuit Testing, Van Nostrand Reinhold, 1985.
Bushnell & Agrawal (KAP)

27. Common Fault Models Single stuck-at faults
Transistor open and short faults
Memory faults
PLA faults (stuck-at, cross-point, bridging)
Functional faults (processors)
Delay faults (transition, path)
Analog faults
For more examples, see Section 4.4 (p ) of the book.
Bushnell & Agrawal (KAP)

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37. Single Stuck-at Fault Three properties define a single stuck-at fault
Only one line is faulty
The faulty line is permanently set to 0 or 1
The fault can be at an input or output of a gate
Example: XOR circuit has 12 fault sites ( ) and 24 single stuck-at faults
Faulty circuit value
Good circuit value c j
0(1)
s-a-0 a d
1(0) g 1 h z i 1 b e 1 k f
Test vector for h s-a-0 fault
Bushnell & Agrawal (KAP)

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42. Scan Flip-Flop (SFF) D Master latch Slave latch TC Q MUX Q SD CK
Logic
overhead
MUX Q SD CK
D flip-flop
Master open CK
Slave open t
Normal mode, D selected
Scan mode, SD selected TC t
Bushnell & Agrawal (KAP)

43. Arbitrary Synchronous Sequencial Circuits
Combinational
logic PI PO FF
Not shown: CK or
MCK/SCK feed all
SFFs.
Bushnell & Agrawal (KAP)

44. Adding Scan Structure Combinational logic PI PO SFF SCANOUT TC SCANIN
Not shown: CK or
MCK/SCK feed all
SFFs.
SCANIN
Bushnell & Agrawal (KAP)

45. Comb. Test Vectors I1 I2 O1 O2 PI PO Combinational logic SCANIN TC
SCANOUT S1 S2 N1 N2
Next
state
Present
state
Bushnell & Agrawal (KAP)