TranGen: A SAT-based ATPG for path-oriented transition faults

Kai Yang; Kwang Ting Cheng; Li C. Wang

TranGen: A SAT-based ATPG for path-oriented transition faults

Kai Yang^*, Kwang Ting Cheng, Li C. Wang

^*Corresponding author for this work

Research output: Contribution to conference › Conference Paper › peer-review

66 Citations (Scopus)

Abstract

This paper presents a SAT-based ATPG tool targeting on a path-oriented transition fault model. Under this fault model, a transition fault is detected through the longest sensitizable path. In the ATPG process, we utilize an efficient false-path pruning technique to identify the longest sensitizable path through each fault site. We demonstrate that our new SAT-based ATPG can be orders-of-magnitude faster than a commercial ATPG tool. To demonstrate the quality of the tests generated by our approach, we compare its resulting test set to three other test sets: a single-detection transition fault test set, a multiple-detection transition fault test set, and a traditional critical path test set added to the single-detection set. The superiority of our approach is demonstrated through various experiments based on statistical delay simulation and defect injection using benchmark circuits.

Original language	English
Pages	92-97
Number of pages	6
Publication status	Published - 2004
Externally published	Yes
Event	Proceedings of the ASP - DAC 2004 Asia and South Pacific Design Automation Conference - 2004 - Yokohama, Japan Duration: 27 Jan 2004 → 30 Jan 2004

Conference

Conference	Proceedings of the ASP - DAC 2004 Asia and South Pacific Design Automation Conference - 2004
Country/Territory	Japan
City	Yokohama
Period	27/01/04 → 30/01/04

Cite this

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title = "TranGen: A SAT-based ATPG for path-oriented transition faults",

abstract = "This paper presents a SAT-based ATPG tool targeting on a path-oriented transition fault model. Under this fault model, a transition fault is detected through the longest sensitizable path. In the ATPG process, we utilize an efficient false-path pruning technique to identify the longest sensitizable path through each fault site. We demonstrate that our new SAT-based ATPG can be orders-of-magnitude faster than a commercial ATPG tool. To demonstrate the quality of the tests generated by our approach, we compare its resulting test set to three other test sets: a single-detection transition fault test set, a multiple-detection transition fault test set, and a traditional critical path test set added to the single-detection set. The superiority of our approach is demonstrated through various experiments based on statistical delay simulation and defect injection using benchmark circuits.",

author = "Kai Yang and Cheng, \{Kwang Ting\} and Wang, \{Li C.\}",

year = "2004",

language = "English",

pages = "92--97",

note = "Proceedings of the ASP - DAC 2004 Asia and South Pacific Design Automation Conference - 2004 ; Conference date: 27-01-2004 Through 30-01-2004",

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TY - CONF

T1 - TranGen

T2 - Proceedings of the ASP - DAC 2004 Asia and South Pacific Design Automation Conference - 2004

AU - Yang, Kai

AU - Cheng, Kwang Ting

AU - Wang, Li C.

PY - 2004

Y1 - 2004

N2 - This paper presents a SAT-based ATPG tool targeting on a path-oriented transition fault model. Under this fault model, a transition fault is detected through the longest sensitizable path. In the ATPG process, we utilize an efficient false-path pruning technique to identify the longest sensitizable path through each fault site. We demonstrate that our new SAT-based ATPG can be orders-of-magnitude faster than a commercial ATPG tool. To demonstrate the quality of the tests generated by our approach, we compare its resulting test set to three other test sets: a single-detection transition fault test set, a multiple-detection transition fault test set, and a traditional critical path test set added to the single-detection set. The superiority of our approach is demonstrated through various experiments based on statistical delay simulation and defect injection using benchmark circuits.

AB - This paper presents a SAT-based ATPG tool targeting on a path-oriented transition fault model. Under this fault model, a transition fault is detected through the longest sensitizable path. In the ATPG process, we utilize an efficient false-path pruning technique to identify the longest sensitizable path through each fault site. We demonstrate that our new SAT-based ATPG can be orders-of-magnitude faster than a commercial ATPG tool. To demonstrate the quality of the tests generated by our approach, we compare its resulting test set to three other test sets: a single-detection transition fault test set, a multiple-detection transition fault test set, and a traditional critical path test set added to the single-detection set. The superiority of our approach is demonstrated through various experiments based on statistical delay simulation and defect injection using benchmark circuits.

UR - https://www.scopus.com/pages/publications/2442536097

M3 - Conference Paper

AN - SCOPUS:2442536097

SP - 92

EP - 97

Y2 - 27 January 2004 through 30 January 2004

ER -

TranGen: A SAT-based ATPG for path-oriented transition faults

Abstract

Conference

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