Optimized Stress Testing for Flexible Hybrid Electronics Designs
abstract: Flexible hybrid electronics (FHE) is emerging as a promising solution to combine the benefits of printed electronics and silicon technology. FHE has many high-impact potential areas, such as wearable applications, health monitoring, and soft robotics, due to its physical advantages, which...
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ndltd-asu.edu-item-516632019-02-02T03:01:14Z Optimized Stress Testing for Flexible Hybrid Electronics Designs abstract: Flexible hybrid electronics (FHE) is emerging as a promising solution to combine the benefits of printed electronics and silicon technology. FHE has many high-impact potential areas, such as wearable applications, health monitoring, and soft robotics, due to its physical advantages, which include light weight, low cost and the ability conform to different shapes. However, physical deformations that can occur in the field lead to significant testing and validation challenges. For example, designers have to ensure that FHE devices continue to meet specs even when the components experience stress due to bending. Hence, physical deformation, which is hard to emulate, has to be part of the test procedures developed for FHE devices. This paper is the first to analyze stress experience at different parts of FHE devices under different bending conditions. Then develop a novel methodology to maximize the test coverage with minimum number of text vectors with the help of a mixed integer linear programming formulation. Dissertation/Thesis Gao, Hang (Author) Ozev, Sule (Advisor) Ogras, Umit Y (Committee member) Christen, Jennifer Blain (Committee member) Arizona State University (Publisher) Electrical engineering eng 32 pages Masters Thesis Electrical Engineering 2018 Masters Thesis http://hdl.handle.net/2286/R.I.51663 http://rightsstatements.org/vocab/InC/1.0/ 2018 |
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English |
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Dissertation |
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Electrical engineering |
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Electrical engineering Optimized Stress Testing for Flexible Hybrid Electronics Designs |
description |
abstract: Flexible hybrid electronics (FHE) is emerging as a promising solution to combine the benefits of printed electronics and silicon technology. FHE has many high-impact potential areas, such as wearable applications, health monitoring, and soft robotics, due to its physical advantages, which include light weight, low cost and the ability conform to different shapes. However, physical deformations that can occur in the field lead to significant testing and validation challenges. For example, designers have to ensure that FHE devices continue to meet specs even when the components experience stress due to bending. Hence, physical deformation, which is hard to emulate, has to be part of the test procedures developed for FHE devices. This paper is the first to analyze stress experience at different parts of FHE devices under different bending conditions. Then develop a novel methodology to maximize the test coverage with minimum number of text vectors with the help of a mixed integer linear programming formulation. === Dissertation/Thesis === Masters Thesis Electrical Engineering 2018 |
author2 |
Gao, Hang (Author) |
author_facet |
Gao, Hang (Author) |
title |
Optimized Stress Testing for Flexible Hybrid Electronics Designs |
title_short |
Optimized Stress Testing for Flexible Hybrid Electronics Designs |
title_full |
Optimized Stress Testing for Flexible Hybrid Electronics Designs |
title_fullStr |
Optimized Stress Testing for Flexible Hybrid Electronics Designs |
title_full_unstemmed |
Optimized Stress Testing for Flexible Hybrid Electronics Designs |
title_sort |
optimized stress testing for flexible hybrid electronics designs |
publishDate |
2018 |
url |
http://hdl.handle.net/2286/R.I.51663 |
_version_ |
1718970037387132928 |