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Efficient Static Compaction Techniques for Sequential Circuits Based on Reverse-Order Restoration and Test Relaxation

Efficient Static Compaction Techniques for Sequential Circuits Based on Reverse-Order Restoration and Test Relaxation
Efficient Static Compaction Techniques for Sequential Circuits Based on Reverse-Order Restoration and Test Relaxation
The paper present efficient reverse-order-restoration (ROR)-based static test compaction techniques for synchronous sequential circuits. Unlike previous ROR techniques that rely on vector-by-vector fault-simulation-based restoration of test subsequences, the authors’ technique restores test sequences based on efficient test relaxation. The restored test subsequence can be either concatenated to the compacted test sequence, as in previous approaches, or merged with it. Furthermore, it allows the removal of redundant vectors from the restored subsequences using a state traversal technique and incorporates schemes for increasing the fault coverage of restored test subsequences to achieve an overall higher level of compaction. In addition, test relaxation is used to take ROR out of saturation. Experimental results demonstrate the effectiveness of the proposed techniques.
El-Maleh, Aiman
5f9ddeed-c012-473e-9b67-ac218e8bec40
Khursheed, Syed Saqib
df76c622-61ca-45b2-b067-2753f1ac0abf
M. Sait, Sadiq
1c02f129-ac17-43c7-ae8b-5d04d445a897
El-Maleh, Aiman
5f9ddeed-c012-473e-9b67-ac218e8bec40
Khursheed, Syed Saqib
df76c622-61ca-45b2-b067-2753f1ac0abf
M. Sait, Sadiq
1c02f129-ac17-43c7-ae8b-5d04d445a897

El-Maleh, Aiman, Khursheed, Syed Saqib and M. Sait, Sadiq (2006) Efficient Static Compaction Techniques for Sequential Circuits Based on Reverse-Order Restoration and Test Relaxation. IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems, 25 (11).

Record type: Article

Abstract

The paper present efficient reverse-order-restoration (ROR)-based static test compaction techniques for synchronous sequential circuits. Unlike previous ROR techniques that rely on vector-by-vector fault-simulation-based restoration of test subsequences, the authors’ technique restores test sequences based on efficient test relaxation. The restored test subsequence can be either concatenated to the compacted test sequence, as in previous approaches, or merged with it. Furthermore, it allows the removal of redundant vectors from the restored subsequences using a state traversal technique and incorporates schemes for increasing the fault coverage of restored test subsequences to achieve an overall higher level of compaction. In addition, test relaxation is used to take ROR out of saturation. Experimental results demonstrate the effectiveness of the proposed techniques.

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Published date: November 2006
Organisations: Electronic & Software Systems
Learn more about Cyber Physical Systems research

Identifiers

Local EPrints ID: 267548
URI: http://eprints.soton.ac.uk/id/eprint/267548
PURE UUID: fd2f6fe5-ed0c-49ee-a8f3-0910529248b8

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Date deposited: 11 Jun 2009 12:20
Last modified: 14 Mar 2024 08:54

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Contributors

Author: Aiman El-Maleh
Author: Syed Saqib Khursheed
Author: Sadiq M. Sait

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