Post on 19-Mar-2016
description
By WAN ZUHA WAN HASAN (UPM)
DEPARTMENT OF ELECTRICAL, ELECTRONIC AND SYSTEM, FACULTY OF ENGINEERING
UKM
Supervised byPROF DR MASURI OTHMAN
(UKM)
Co-supervisorDR BAMBANG SUNARYO SUPARJO
(MENTOR GRAPHIC USA)
THE DESIGN OF THE MEMORY BUILT-IN SELF-TEST, DIAGNOSIS AND REPAIR (MBISTDR)
FOR SRAMs
Outline
• Introduction• Memory Architecture • Memory Fault Models • Test Algorithms• Memory Testing, Diagnosis and
Repair • Conclusion
IntroductionWhy BIST, BISD and BISR
The advances of semiconductor memory technologies have become more complex and also the numbers of memory cell per chip (transistors) rapidly increase.
The ITRS 2003 has shown an ever Increasing percentage of chip area devoted to embedded memory, with today’s SoCs already consisting of over 50% memory.
Introduction
Introduction
Memory Sizes Versus Yield
Introduction
ITRS 2004 - SOC Test Requirements
Introduction The Requirement of Future
MBISTDR• Fault Modeling – New Fault Models
(defect in deep-submicron) • Test algorithm design – Optimal
test/diagnosis (high defect coverage)
• BIST – allow at speed testing• BISR – low cost repair scheme
( improve the yield and reliability)
Memory architecture
Functional RAM ModelSource: Testing and semiconductor memories, A.J. van de Goor
Reduced Functional RAM Model
Memory architecture
Source: Testing and semiconductor memories, A.J. van de Goor
Memory Fault Models
Source: Testing and semiconductor memories, A.J. van de Goor
Memory Fault Models
Source: Testing and semiconductor memories, A.J. van de Goor
Memory Fault Models
Memory Fault Models
Memory Fault Models
Memory Fault ModelsCoupling Fault(CF)
Memory Fault ModelsTwo Cell Faults - cont
Memory Fault Models
Memory Fault Models
Memory Fault ModelsCoupling Fault
State Coupling Fault
Source: Testing and semiconductor memories, A.J. van de Goor
Memory Fault Models
Memory Fault Models
Memory Fault Models
Test AlgorithmsFunctional RAM Testing
• Traditional Test- Zero-One - SAF - Checkerboard - SAF- GALPAT and Walking 1/0 – AF, SAF, TF and CF - testing time
unacceptable- Sliding Diagonal – SAF, TF- Butterfly – SAF, AF
Source: Testing and semiconductor memories, A.J. van de Goor
Test AlgorithmsMarch Test Algorithms
Test Algorithms March Test Algorithms
Test Algorithms March Test Notation
Source: Testing and semiconductor memories, A.J. van de Goor
Test Algorithms March Test Notation
Source: Testing and semiconductor memories, A.J. van de Goor
Test Algorithms
Source: Testing and semiconductor memories, A.J. van de Goor
Test Algorithms Comparison of March Tests
March Test
Algorithm NumberOperation
Fault Coverage
Test-US
MATS 4n or * 2N SAF, some AF
MATS+ 2
5n or 5 * 2N
SAF, AF
Test-UT MATS++ 7 or 7 * 2N SAF, TF, AF
Test-UC March C 11n SAF, TF, AF, CF
Test-LC March A 15n SAF, AF, CF
Test-LCT March B 17n SAF, AF, CF, TF
Source: Testing and semiconductor memories, A.J. van de Goor
Test AlgorithmsFault detection using March C-
M0 M1 M2 M3
{⇕(w0); (r0, w1); (r1, w0); (r0,w1);
M4 M5
(r1, w0); ⇕(r0} - 10N Test algorithm
Disable RAM (wait) { (r0, w1,); Disable RAM(wait) (r1):} - Data retention fault(DRF)
Test AlgorithmsFault detection using
Extended March C- (covered SOF)
M0 M1 M2 M3
{⇕(w0); (r0, w1,r1); (r1, w0); (r0,w1);
M4 M5
(r1, w0); ⇕(r0)} - 11N Test algorithm
Disable RAM (wait) { (r0, w1,); Disable RAM(wait) (r1):} - Data retention fault(DRF)
Test AlgorithmsFault detection using extended March C-
Fault March ElementsM0⇕(w0
)
M1(r0, w1,r1)
M2 (r1, w0)
M3(r0,w1)
M4 (r1, w0)
M5 ⇕(r0)
SAFINITIALZATION
r0 – s-a-1 r1 – s-a-0
TF M1(r0,w1) followed M2(r1,w0) followed by M2(r1) for </0> by M3(r0) for </1>
CF M1(r0,w1) for Cfid </1> *j<iM1 followed by M2 for Cfin </↕>*j>i
M2(r1,w0) for Cfid </0>
*j<iM2(r1,w0) for Cfin </↕> *j>i
M3(r0,w1) followed M4(r1,w0) followed by M4(r1,w0) by M5(r0) for Cfid for Cfid </0> </1> M1 & M3(r0,w1) M2 & M4(r1,w0) Followed by followed by M5(r0) M4(r1,w0) for for Cfin </ ↕ >Cfin </↕>
*all CFids is j<i ( for j>i is similar)AF (M1(r0, w1,r1) M2(r1, w0)) – j>i, (M3(r0,w1) M4 (r1, w0)) – i>j
(Satisfied with known technology)SOF r1
DRF Disable RAM (wait) { (r0, w1,); Disable RAM(wait) (r1):}
Test Algorithms Functional Fault Models for Diagnosis
ICCAD 2000 Chi-Feng Wu
Test Algorithms Fault detection and diagnosis using
March CL
{(w0); (r0, w1,); (r1, w0,); ⇕(r1); R0 R1 R2 (r0,w1); ⇕(r1); (r1, w0); ⇕(r0)} R3 R4 R5 R6
-12N Test algorithmDisable RAM (wait){ (r0, w1,); Disable RAM(wait) (r1):} - Data retention Fault(DRF).
Test Algorithms Fault detection and diagnosis by
Extended March CL
{(w0); (r0, w1, r1); (r1, w0); ⇕(r1); R0 R1 R2 R3(r0,w1); ⇕(r1); (r1, w0); ⇕(r0)} R4 R5 R6 R7
-13N Test algorithm
Disable RAM (wait){ (r0, w1,); Disable RAM(wait) (r1):}- Data retention Fault(DRF).
Test Algorithms Fault syndrome for March CL
Test Algorithms Fault syndrome for Extended March CL
1. { (w0); (r0, w1,); (r1, w0); (r0,w1); (r1, w0) }- Disable RAM (wait){(r0,w1,); Disable RAM(wait) (r1):}9N test algorithm with data retention test – Rob Dekker 1988, has covered 100% coverage of the faults under the listed fault models.
2. { (w0); (r0, w1, r1, w0); delay (r0, r0); (w1);
(r1, w0, r0, w1); delay (r1, r1)}14N test algorithm - Said Hamdioui 2000, has covered 100% coverage of the faults under the listed fault models and spot defects.
Test Algorithms Existing March Test Algorithms
3. { (w0); (r0); delay (r0); (w1); (r1); delay (r1)} or { (w0); (r0); delay (r0); (w1); (r1); delay (r1)}
6N test algorithm – Baosheng Wang 2003, has reduced less than half of the required time for the 9N test algorithm
4. { ⇕(w0); (r0, w1,); ⇕(r1); (r1, w0); ⇕(r0); (r0, w1);
⇕(r1); (r1, w0); ⇕(r0); 13N test algorithm – V. N. Yarmolik 1996, has introduced diagnosis capability and achieved 63.6% diagnostic resolution (SAF & CF).
Test Algorithms Existing March Test Algorithms
Test Algorithms Existing March Test Algorithms
5. { ⇕(w0); (r0, w1,r1, w0); (r0, w1); (r1, w0,r0, w1); ⇕(r1); (r1, w0); ⇕(r0); (r0, w1); ⇕(r1); 18N test algorithm – V. N. Yarmolik 1996, has been introduced for the diagnosis capability and achieved 90.9%diagnostic resolution (SAF & CF).
6. { (w0); (r0, w1, w0, w1); (r1, w0, r0, w1); (r1, w0, w1,
w0); (r0, w1, r1, w0); Hold (r0, w1); Hold (r1);
20N test algorithm – I. Kim 1998, has been diagnosis
capability and achieved 59% diagnostic resolution (SAF
& CF).
Test Algorithms Existing March Test Algorithms
7. { (w0); (r0, w1,r1, w0 ); ⇕(r0); ⇕(w1); (r1, w0,r0, w1);
⇕(r1); }
12N test algorithm – T. J. Bergfeld 2000, has
proposed diagnosis capability but it could only achieve
22.7% diagnostic resolution (SAF & CF).
8. { ⇕(w0); (r0, w1, r1); ⇕(r1); (r1, w0,r0); ⇕(r0); (r0, w1,
r1); ⇕(r1); (r1, w0, r0); ⇕(r0); }
17N test algorithm – Jin-Fu Li 1996, has introduced
diagnosis capability and achieved 100% diagnostic
resolution(SAF & CF).
Test Algorithms Existing March Test Algorithms
9. {(w0); (r0, w1,); ⇕(r1); (r1, w0); (r0, w1); ⇕(r1);
(r1, w0); ⇕(r0);}
12N test algorithm plus 3N or 4N ( for aggressor
locating) – V. A. Vardanian 2002, has introduced
diagnosis capability and achieved 100%
diagnostic resolution.
STATE-OF-ART FOR TEST ALGORITHMS
• Optimality in term of time complexity
• Regularity and symmetry such that the self-test circuit can minimize the silicon area
• High defect coverage and diagnosis capability in order to increase the repair capabilities and the overall yield
Test Algorithms
Memory Testing, Diagnosis and RepairMBIST ARCHITECTURE
SRAM
MBIST SYSTEM
FSM
CONTROLLER
COMPARATOR
BIST
Memory Testing, Diagnosis and RepairMBISTD ARCHITECTURE
SRAM
MBISTDSYSTEM
FSM
CONTROLLER
COMPARATOR
BIST
INDICATOR
STATE-OF-ART FOR BISTD
• Minimizing BIST overhead in both silicon area and routing
• Supporting diagnosis capabilities
• Supporting different kinds of memories (single-port, multi-port)
Memory Testing, Diagnosis and RepairBISTD
Memory Testing, Diagnosis and RepairMBISTDR ARCHITECTURE
SRAM
MBISTDRSYSTEM
FSM
CONTROLLER
COMPARATOR
BIST
INDICATOR
EXTRA COLUMN /ROW/WORD
Conclusion
MBISTDR is essential for memory reliability in the near future.
The addition of BISD and BISR will enhance the yields of overall memory chips.
New test algorithm and fault syndromes base on March CL has been proposed to detect and diagnose SOF and AF.
THANK YOU
Q & A
THANK YOU
Q & A
THANK YOU
Q & A
Memory Testing, Diagnosis and RepairExample of MBISR
Fuse Box
Redundancy
Logic
RAM
MBIST
Mux
Mux
DataAddress Control
The Memory BIST and Self-Repair (MBISR) Concept [Volker 2001].Data
• The Figure above shows the MBIST and Self-Repair using redundancy logic and Fuse Box concept.
• The MBISR concept contains an interface between MBIST logic, redundancy wrapper logic to replace defect address and Fuse boxes to store the failling addresses
Memory Testing, Diagnosis and Repair
On Going Research
The design and simulation of MBISTDR .
New Test Algorithms with Diagnosis capability will be designed according to the required coverage and testing time.
Design of MBISTDR Controller for Stuck-at Faults
MBISTDRCONTROLLER
32 X 12 SRAM
MUX_1
MUX_2
d_in
Wr_en
Bistr_addr
Bistr_error_addr
bistr_data_read d_out
Rd_en
Sram_error
bistr_data_write
mode_sel
addr
bistr_en
clk
5
5
5
5
12
12
12
12
12
Mode_sel
MBISTDR Methodology
The schematic of MBISTDR Controller for Stuck-at Faults
MBISTDR Methodology
Figure above shows that MBISTDR contains MBISTDR controller and 32x12 SRAM
Test Pattern In – Bistr_data_write (w0/w1)Mode_sel – test or normal mode Enable the Wr_en or Rd_enTest Pattern Out – Bistr_data_read(r0/r1)
MBISTDR Methodology
Test and Repair Algorithm of MBISTDR controller for Stuck-at Faults
MBISTDR Methodology
MBISTDR Methodology
Figure above Shows that, how MBISTR controller implements the test and repair algorithm to the 32x12 SRAM memory.
Procedure:address 1 – w0 then compare with r0 address 2 – w1 then compare with r1
Run until either marked addresses or memory addresses reach the maximum
MBISTDR Results And Discussion
Fault Free Results for MBISTDR During Normal mode Operation
MBISTDR Result And Discussion
Fault Detection Results for MBISTDR during Test mode Operation
Results for MBISTDR During Normal Mode and Test Mode Operation
MBISTDR Result And Discussion
Final Target for MBISTDR Criteria: TA1)High defect coverage and diagnosis
capability in order to increase the repair capabilities and the overall yield – below 17N
BISTDR1)Supporting diagnosis capabilities – 100%
diagnosis resolution (include SOF and AF)
2) Using Extra Memory for the BISR
MBISTDR Conclusion
A new memory Built-in Self-test and Repair concept has been designed and this concept is proposed without using any extra rows and columns.
These test and repair are only focused on the reconfiguration of the memory addresses, which means no extra spaces needed as the previous researches.