Title: Ugur Kalay,
1Universally Testable AND-EXOR Networks
- Ugur Kalay,
- Marek Perkowski, Douglas Hall
Speaker Alan Mishchenko
Portland State University
2Agenda
- Introduction
- desired properties of a test set
- testing AND and EXOR gates
- test scheme proposed by Reddy
- Testing Two-level AND-EXOR Networks
- implementation of the new testing scheme
- experimental results
- Testing Multi-Level AND-EXOR Networks
- extending the scheme for multi-level circuits
- Conclusions and Directions of Future Research
3Introduction
Requirements for a Test Set
- 100 Fault Coverage
- no fault simulation
- Minimal (as few tests as possible)
- shorter testing time
- Universal (does not depend on the circuit)
- portability of the pattern generator
- reduced engineering
- Regular (test patterns have certain structure)
- simpler pattern generator
- Good Scalability
- easy pattern generator expandability
4Introduction
Testing AND gate
1
a
4
2
b
3
c
5Introduction
Testing EXOR gate
a
g
b
6Introduction
- Reddys Positive Polarity Reed-Muller Testing
Scheme - Example f x1x2 Ã… x1x3 Ã… x1x2x3
-
x0 x1 x2
x3 x0 x1
x2 x3 -
0 0 0
0 - 0 1 1 -
T1 0 1 1
1 T2 - 1 0 1 -
1 0 0
0 - 1 1 0 -
1 1 1
1 -
- dont care
100 Single Stuck-at Fault Coverage
Minimal (C n 4)
Universal
Regular Patterns
Linear increase
Large expression leads to long EXOR cascade
7Introduction
- Other Reed-Muller Canonical Forms
- PPRM (Positive Polarity Reed-Muller)
- x1x2x3 Ã… x1x2
- FPRM (Fixed Polarity Reed-Muller)
- x1x2x3 Ã… x2x3
- GRM (Generalized Reed-Muller)
- x1 Ã… x2 Ã… x2x3
- Free Expression
- ESOP (EXOR-Sum-of-Products)
- x1x2x3 Ã… x1x2x3
ESOP
GRM
FPRM
PPRM
8Introduction
- Comparison of the Number of Product Terms
9Testing Two-level AND-EXOR Networks
100 single stuck at faults
Minimal C n 6
Universal
Regular
Linear size increase
Perfect for BIST !
10Testing Two-level AND-EXOR Networks
Advantages of deterministic testing for ESOP
- much shorter test cycle than pseudo-random and
pseudo-exhaustive test sets - better fault coverage than a pseudo-random test
set - no test point insertion required
- a fixed, simple, and easily expandable pattern
generator
11Testing Two-level AND-EXOR Networks
- Built-in Self-Test Circuitry for ESOP Networks
PRPG
EDPG
Circuit Under Test
Easily Testable 2-level ESOP Network
MISR
12Testing Two-level AND-EXOR Networks
- ESOP Deterministic Pattern Generator
- Linearly expandable
- No initialization seed circuitry
- Much shorter cycle than a PRPG
- Comparable size to PRPG (see later)
13Testing Two-level AND-EXOR Networks
14Testing Two-level AND-EXOR Networks
Experimental Results
- Comparisons of the number of test vectors for
100 single stuck-at fault fault coverage
15Testing Two-level AND-EXOR Networks
- Comparisons of the number of test vectors for
100 single stuck-at fault fault coverage (cont)
16Testing Two-level AND-EXOR Networks
- Area and delay comparisons (LSI Logic Corp., 0.5
micron)
17Testing Two-level AND-EXOR Networks
- Area comparisons (Cont...)
18Testing Two-level AND-EXOR Networks
- Multiple Fault Simulation Results
19Testing Multi-level AND-EXOR Networks
- Two-level implementations
- easily testable
- large delay
- It is possible to factorize the two-level ESOP
expression - Universal testing of two-level ESOPs can be
adopted for multi-level testing - requires scan registers
20Testing Multi-level AND-EXOR Networks
Example The multi-output function, X acefg Ã…
acefg Ã… adefg Ã… adefg Ã… ajhi Ã… ajd Ã…
bcefg Ã… bcefg Ã… bdefg Ã… bdefg Ã…
bhij Ã… bdj Y bg Ã… acefg Ã… adefg Z
adj Ã… bdj Ã… ahij Ã… bhij can be factorized
as, X UV(efg Ã… efg) Ã… jW Y bg Ã…
aefgV Z jUW where, U a Ã… b V c Ã…
d W hi Ã… d
21Testing Multi-level AND-EXOR Networks
- Implementation without testability improvements
22Testing Multi-level AND-EXOR Networks
23Testing Multi-level AND-EXOR Networks
24Testing Multi-level AND-EXOR Networks
- Creating cascade of EXOR gates at each level
25Testing Multi-level AND-EXOR Networks
26Testing Multi-level AND-EXOR Networks
- Inserting specialized Scan Registers and Scan Path
27Testing Two-level AND-EXOR Networks
- TESTING SCHEME
- Each level is tested separately (can be improved)
- ESOP planes of the same level are tested in
parallel - Test vectors of the first level are applied from
the primary inputs in parallel - Test vectors of the internal levels are applied
from the primary inputs and from the scan
registers - The bits applied from the scan registers are
shifted into the scan path before applied in
parallel - The network results are collected by the scan
registers and shifted out, and/or observed from
the primary outputs
28Testing Multi-level AND-EXOR Networks
- Implementation of Scan Registers
- In normal circuit operation, only one mux delay
added
- Inserted only at the output of internal ESOP
planes
29Testing Multi-level AND-EXOR Networks
- Scan Register mode of operations
30Testing Multi-level AND-EXOR Networks
- Scan Register mode of operations
31Testing Multi-level AND-EXOR Networks
- Scan Register mode of operations
32Testing Multi-level AND-EXOR Networks
- Critical Path Delay 2.95 ns
vs. 4.33 ns of 2-level impl.
33Testing Multi-level AND-EXOR Networks
- (4 AND3 5 AND2 24 EXOR2) gates 5 SR
vs. (17 AND3 24 AND2 33 EXOR2) gates of
2-level impl.
34Future Directions
- Developing a universal test set for bridging and
stuck-open faults - Developing a factorization/decomposition method
targeting EXOR-based multi-level synthesis and
universal (deterministic) testability
35Advantages and Disadvantages of the New Scheme
- Test set is exponentially smaller than a
pseudorandom test set and much smaller than
algorithmically generated test set for 100
coverage of single stuck-at faults - Properties of deterministic pattern generator for
BIST - easy to implement (small area overhead)
- does not require seed generation
- guarantees 100 testability
- Detects significant fraction of multiple stuck-at
faults and bridging faults - Cascade of EXOR gates is relatively slow
- Area of the AND-EXOR circuit is relatively large
- ESOP factorization algorithm is computationally
complex
36Rereferences
1 Ugur Kalay, Douglas V. Hall, Marek A.
Perkowski. A Minimal Universal Test Set for
Self-Test of EXOR-Sum-of-Products Circuits. IEEE
Trans. Comp. Vol. 49, N3, March 1999,
pp.267-276.2 Ugur Kalay, Marek Perkowski.
Rectangle Covering Factorization of EXORs into
Scan-Based Levelized Circuits with Universal Test
Set. Proc. of International Workshop on
Application of Reed-Muller Expansion in Circuit
Design. 1999.