Title :
Advanced scan chain failure analysis using laser modulation mapping and continuous wave probing
Author :
Kasapi, Steven ; Lo, William ; Liao, Joy ; Cory, Bruce ; Marks, Howard
Author_Institution :
NVIDIA, Santa Clara, CA, USA
Abstract :
Scan chain failures are a significant fraction of yield loss. The complexity of modern design-for-test (DFT) implementation techniques and more subtle failure mechanisms of sub-40nm technologies make defect identification more challenging. Software chain diagnosis and a variety of EFA techniques have been deployed to improve scan chain failure isolation. However, we have found in practice that each of these techniques has significant limitations. In earlier papers we presented a new image-based laser technique (Modulation Mapping) to identify the first failing flop in the broken scan chain of stuck-at failures. Here we present three case studies of scan chains with more subtle resistive failure mechanisms, including transition, bridge, and slow-to-rise/fall failures, using a combination of modulation mapping (MM) and continuous-wave (CW) laser probing.
Keywords :
design for testability; failure analysis; fault diagnosis; flip-flops; integrated circuit yield; logic testing; optical modulation; CW laser probing; DFT; EFA technique; bridge failure; continuous wave laser probing; defect identification; design-for-test; flip-flop; image-based laser technique; laser modulation mapping; resistive failure mechanism; scan chain failure analysis; scan chain failure isolation; size 40 nm; slow-to-rise/fall failure; software chain diagnosis; stuck-at failure; transition failure; yield loss; Clocks; Computer aided software engineering; Failure analysis; Frequency modulation; Harmonic analysis; Laser transitions;
Conference_Titel :
Physical and Failure Analysis of Integrated Circuits (IPFA), 2012 19th IEEE International Symposium on the
Conference_Location :
Singapore
Print_ISBN :
978-1-4673-0980-6
DOI :
10.1109/IPFA.2012.6306326
