SAT-based ATPG for reversible circuits

Hongyan Zhang; Robert Wille; Rolf Drechsler

doi:10.1109/IDT.2010.5724428

SAT-based ATPG for reversible circuits

Hongyan Zhang, Robert Wille, Rolf Drechsler

University of Bremen

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

8 Scopus citations

Abstract

Reversible circuits, in particular with their application in the domain of quantum computation and low-power design, are seen as promising alternative to conventional circuit technologies. First physical implementations are already available. Hence, researchers started to investigate testing of this kind of circuits. However, so far only simple reversible circuits have been considered. In this paper, we show that automatic test pattern generation of reversible circuits is harder, if additional constraints (like the frequently used constant inputs) occur. As a consequence, we propose an alternative ATPG method that makes use of solvers for Boolean satisfiability (SAT). Experiments demonstrate that with this approach, testsets for reversible circuits can be efficiently generated even if additional constraints like constant inputs have to be considered.

Original language	English
Title of host publication	IDT'10 - 2010 5th International Design and Test Workshop, Proceedings
Pages	149-154
Number of pages	6
DOIs	https://doi.org/10.1109/IDT.2010.5724428
State	Published - 2010
Externally published	Yes
Event	2010 5th International Design and Test Workshop, IDT'10 - Abu Dhabi, United Arab Emirates Duration: 14 Dec 2010 → 15 Dec 2010

Publication series

Name	IDT'10 - 2010 5th International Design and Test Workshop, Proceedings

Conference

Conference	2010 5th International Design and Test Workshop, IDT'10
Country/Territory	United Arab Emirates
City	Abu Dhabi
Period	14/12/10 → 15/12/10

Access to Document

10.1109/IDT.2010.5724428

Cite this

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title = "SAT-based ATPG for reversible circuits",

abstract = "Reversible circuits, in particular with their application in the domain of quantum computation and low-power design, are seen as promising alternative to conventional circuit technologies. First physical implementations are already available. Hence, researchers started to investigate testing of this kind of circuits. However, so far only simple reversible circuits have been considered. In this paper, we show that automatic test pattern generation of reversible circuits is harder, if additional constraints (like the frequently used constant inputs) occur. As a consequence, we propose an alternative ATPG method that makes use of solvers for Boolean satisfiability (SAT). Experiments demonstrate that with this approach, testsets for reversible circuits can be efficiently generated even if additional constraints like constant inputs have to be considered.",

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doi = "10.1109/IDT.2010.5724428",

language = "English",

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series = "IDT'10 - 2010 5th International Design and Test Workshop, Proceedings",

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note = "2010 5th International Design and Test Workshop, IDT'10 ; Conference date: 14-12-2010 Through 15-12-2010",

}

Zhang, H, Wille, R & Drechsler, R 2010, SAT-based ATPG for reversible circuits. in IDT'10 - 2010 5th International Design and Test Workshop, Proceedings., 5724428, IDT'10 - 2010 5th International Design and Test Workshop, Proceedings, pp. 149-154, 2010 5th International Design and Test Workshop, IDT'10, Abu Dhabi, United Arab Emirates, 14/12/10. https://doi.org/10.1109/IDT.2010.5724428

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AB - Reversible circuits, in particular with their application in the domain of quantum computation and low-power design, are seen as promising alternative to conventional circuit technologies. First physical implementations are already available. Hence, researchers started to investigate testing of this kind of circuits. However, so far only simple reversible circuits have been considered. In this paper, we show that automatic test pattern generation of reversible circuits is harder, if additional constraints (like the frequently used constant inputs) occur. As a consequence, we propose an alternative ATPG method that makes use of solvers for Boolean satisfiability (SAT). Experiments demonstrate that with this approach, testsets for reversible circuits can be efficiently generated even if additional constraints like constant inputs have to be considered.

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ER -

SAT-based ATPG for reversible circuits

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