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Low power test compatibility classes: exploiting regularity for simultaneous reduction in test application time and power dissipation

Low power test compatibility classes: exploiting regularity for simultaneous reduction in test application time and power dissipation
Low power test compatibility classes: exploiting regularity for simultaneous reduction in test application time and power dissipation
Traditional DFT methodologies increase useless power dissipation during testing and are not suitable for testing low power VLSI circuits leading to lower reliability and manufacturing yield. Traditional test scheduling approaches based on fixed test resource allocation decrease power dissipation at the expense of higher test application time. On the one hand it was shown that power conscious test synthesis and scheduling eliminate useless power dissipation. On the other hand by exploiting regularity in BIST RTL data paths using test compatibility classes an improvement in test application time, BIST area overhead, performance degradation, volume of test data, and fault escape probability is achieved. This paper shows that when combining power conscious test synthesis and scheduling with the test compatibility classes into low power test compatibility classes, simultaneous reduction in test application time and power dissipation is obtained.
Nicolici, N.
9be70b5e-becc-4ec4-a564-14758ef4f03c
Al-Hashimi, B.M.
0b29c671-a6d2-459c-af68-c4614dce3b5d
Nicolici, N.
9be70b5e-becc-4ec4-a564-14758ef4f03c
Al-Hashimi, B.M.
0b29c671-a6d2-459c-af68-c4614dce3b5d

Nicolici, N. and Al-Hashimi, B.M. (2001) Low power test compatibility classes: exploiting regularity for simultaneous reduction in test application time and power dissipation.

Record type: Conference or Workshop Item (Other)

Abstract

Traditional DFT methodologies increase useless power dissipation during testing and are not suitable for testing low power VLSI circuits leading to lower reliability and manufacturing yield. Traditional test scheduling approaches based on fixed test resource allocation decrease power dissipation at the expense of higher test application time. On the one hand it was shown that power conscious test synthesis and scheduling eliminate useless power dissipation. On the other hand by exploiting regularity in BIST RTL data paths using test compatibility classes an improvement in test application time, BIST area overhead, performance degradation, volume of test data, and fault escape probability is achieved. This paper shows that when combining power conscious test synthesis and scheduling with the test compatibility classes into low power test compatibility classes, simultaneous reduction in test application time and power dissipation is obtained.

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More information

Published date: November 2001
Additional Information: Organisation: IEEE
Organisations: Electronic & Software Systems
Learn more about Cyber Physical Systems research

Identifiers

Local EPrints ID: 256012
URI: http://eprints.soton.ac.uk/id/eprint/256012
PURE UUID: 12962d0e-87c3-483c-aa5a-9bca250fe70a

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Date deposited: 04 Sep 2001
Last modified: 14 Mar 2024 05:37

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Contributors

Author: N. Nicolici
Author: B.M. Al-Hashimi

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