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Defect-tolerant N2-transistor structure for reliable nanoelectronic designs

Defect-tolerant N2-transistor structure for reliable nanoelectronic designs
Defect-tolerant N2-transistor structure for reliable nanoelectronic designs
Nanodevices based circuit design will be based on the acceptance that a high percentage of devices in the design will be defective. In this work, we investigate a defect tolerant technique that adds redundancy at the transistor level and provides built-in immunity to permanent defects (stuck-open, stuck-short and bridges). The proposed technique is based on replacing each transistor by N2-transistor structure (N≥2) that guarantees defect tolerance of all N-1 defects as validated by theoretical analysis and simulation. As demonstrated by extensive simulation results using ISCAS 85 and 89 benchmark circuits, the investigated technique achieves significantly higher defect tolerance than recently reported nanoelectronics defect-tolerant techniques (even with up to 4 to 5 times more transistor defect probability) and at reduced area overhead. For example, the quadded-transistor structure technique requires nearly half the area of the quadded logic technique.
1751-8601
570-580
El-Maleh, A.H.
5f9ddeed-c012-473e-9b67-ac218e8bec40
Al-Hashimi, B.M.
0b29c671-a6d2-459c-af68-c4614dce3b5d
Melouki, A.
b14f1adf-1c12-4ed4-ada7-a1c7827c2051
Khan, F.
3b66a0b4-2807-422f-92f8-729692cd597b
El-Maleh, A.H.
5f9ddeed-c012-473e-9b67-ac218e8bec40
Al-Hashimi, B.M.
0b29c671-a6d2-459c-af68-c4614dce3b5d
Melouki, A.
b14f1adf-1c12-4ed4-ada7-a1c7827c2051
Khan, F.
3b66a0b4-2807-422f-92f8-729692cd597b

El-Maleh, A.H., Al-Hashimi, B.M., Melouki, A. and Khan, F. (2009) Defect-tolerant N2-transistor structure for reliable nanoelectronic designs. IET Computers & Digital Techniques, 3 (6), 570-580. (doi:10.1049/iet-cdt.2008.0133).

Record type: Article

Abstract

Nanodevices based circuit design will be based on the acceptance that a high percentage of devices in the design will be defective. In this work, we investigate a defect tolerant technique that adds redundancy at the transistor level and provides built-in immunity to permanent defects (stuck-open, stuck-short and bridges). The proposed technique is based on replacing each transistor by N2-transistor structure (N≥2) that guarantees defect tolerance of all N-1 defects as validated by theoretical analysis and simulation. As demonstrated by extensive simulation results using ISCAS 85 and 89 benchmark circuits, the investigated technique achieves significantly higher defect tolerance than recently reported nanoelectronics defect-tolerant techniques (even with up to 4 to 5 times more transistor defect probability) and at reduced area overhead. For example, the quadded-transistor structure technique requires nearly half the area of the quadded logic technique.

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IET_DefectTolerantStructureNanoelectronics.pdf - Accepted Manuscript
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Submitted date: 28 March 2009
Published date: November 2009
Organisations: Electronic & Software Systems
Learn more about Cyber Physical Systems research Learn more about School of Electronics and Computer Science research

Identifiers

Local EPrints ID: 267678
URI: http://eprints.soton.ac.uk/id/eprint/267678
DOI: doi:10.1049/iet-cdt.2008.0133
ISSN: 1751-8601
PURE UUID: 5df439a1-82d0-46a0-b730-72424bee91de

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Date deposited: 17 Jul 2009 17:42
Last modified: 17 Mar 2024 07:52

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Contributors

Author: A.H. El-Maleh
Author: B.M. Al-Hashimi
Author: A. Melouki
Author: F. Khan

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