Magnetoresistive sensor development roadmap (non-recording applications)

Magnetoresistive sensor development roadmap (non-recording applications)

Magnetoresistive (MR) sensors have been identified as promising candidates for the development of high-performance magnetometers due to their high sensitivity, low cost, low power consumption, and small size. The rapid advance of MR sensor technology has opened up a variety of MR sensor applications...

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Main Authors: Zheng, Chao, Zhu, Ke, De Freitas, Susana Cardoso, Chang, Jen-Yuan, Davies, Joseph E., Eames, Peter, Freitas, Paulo P., Kazakova, Olga, Kim, Cheol Gi, Leung, Chi-Wah, Liou, Sy-Hwang, Ognev, Alexey, Piramanayagam, S. N., Ripka, Pavel, Samardak, Alexander, Shin, Kwang-Ho, Tong, Shi-Yuan, Tung, Mean-Jue, Wang, Shan X., Xue, Songsheng, Yin, Xiaolu, Pong, Philip W. T.
Other Authors: School of Physical and Mathematical Sciences
Format: Article
Language:English
Published: 2021
Subjects:
Science::Physics
Magnetoresistive Sensor
Research and Development Guide
Online Access:https://hdl.handle.net/10356/151182
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1511822021-06-09T08:56:14Z Magnetoresistive sensor development roadmap (non-recording applications) Zheng, Chao Zhu, Ke De Freitas, Susana Cardoso Chang, Jen-Yuan Davies, Joseph E. Eames, Peter Freitas, Paulo P. Kazakova, Olga Kim, Cheol Gi Leung, Chi-Wah Liou, Sy-Hwang Ognev, Alexey Piramanayagam, S. N. Ripka, Pavel Samardak, Alexander Shin, Kwang-Ho Tong, Shi-Yuan Tung, Mean-Jue Wang, Shan X. Xue, Songsheng Yin, Xiaolu Pong, Philip W. T. School of Physical and Mathematical Sciences Science::Physics Magnetoresistive Sensor Research and Development Guide Magnetoresistive (MR) sensors have been identified as promising candidates for the development of high-performance magnetometers due to their high sensitivity, low cost, low power consumption, and small size. The rapid advance of MR sensor technology has opened up a variety of MR sensor applications. These applications are in different areas that require MR sensors with different properties. Future MR sensor development in each of these areas requires an overview and a strategic guide. An MR sensor roadmap (non-recording applications) was therefore developed and made public by the Technical Committee of the IEEE Magnetics Society with the aim to provide an research and development (R&D) guide for MR sensors intended to be used by industry, government, and academia. The roadmap was developed over a three-year period and coordinated by an international effort of 22 taskforce members from ten countries and 17 organizations, including universities, research institutes, and sensor companies. In this paper, the current status of MR sensors for non-recording applications was identified by analyzing the patent and publication statistics. As a result, timescales for MR sensor development were established and critical milestones for sensor parameters were extracted in order to gain insight into potential MR sensor applications (non-recording). Five application areas were identified, and five MR sensor roadmaps were established. These include biomedical applications, flexible electronics, position sensing and human-computer interactions, non-destructive evaluation and monitoring, and navigation and transportation. Each roadmap was analyzed using a logistic growth model, and new opportunities were predicted based on the extrapolated curve, forecast milestones, and professional judgment of the taskforce members. This paper provides a framework for MR sensor technology (non-recording applications) to be used for public and private R&D planning, in order to provide guidance into likely MR sensor applications, products, and services expected in the next 15 years and beyond. This work was supported in part by the Seed Funding Program for Basic Research, in part by the Seed Funding Program for Applied Research and Small Project Funding Program from the University of Hong Kong, and in part by ITF Tier 3 funding under Grant ITS/203/14, Grant ITS/104/13, and Grant ITS/214/14), in part by RGC-GRF under Grant HKU 17210014 and Grant HKU 17204617, and in part by the University Grants Committee of Hong Kong under Contract AoE/P-04/08. 2021-06-09T08:56:14Z 2021-06-09T08:56:14Z 2019 Journal Article Zheng, C., Zhu, K., De Freitas, S. C., Chang, J., Davies, J. E., Eames, P., Freitas, P. P., Kazakova, O., Kim, C. G., Leung, C., Liou, S., Ognev, A., Piramanayagam, S. N., Ripka, P., Samardak, A., Shin, K., Tong, S., Tung, M., Wang, S. X., ...Pong, P. W. T. (2019). Magnetoresistive sensor development roadmap (non-recording applications). IEEE Transactions On Magnetics, 55(4), 0800130-. https://dx.doi.org/10.1109/TMAG.2019.2896036 0018-9464 0000-0003-4489-5304 0000-0002-0157-8969 0000-0001-8560-1777 0000-0001-6913-6529 0000-0002-8473-2414 0000-0001-9531-5758 0000-0003-0083-6273 0000-0003-4692-7154 0000-0002-3178-2960 0000-0003-1115-6265 0000-0002-5554-8386 https://hdl.handle.net/10356/151182 10.1109/TMAG.2019.2896036 2-s2.0-85063272685 4 55 0800130 en IEEE Transactions on Magnetics © 2019 IEEE. All rights reserved.
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Science::Physics
Magnetoresistive Sensor
Research and Development Guide
spellingShingle Science::Physics
Magnetoresistive Sensor
Research and Development Guide
Zheng, Chao
Zhu, Ke
De Freitas, Susana Cardoso
Chang, Jen-Yuan
Davies, Joseph E.
Eames, Peter
Freitas, Paulo P.
Kazakova, Olga
Kim, Cheol Gi
Leung, Chi-Wah
Liou, Sy-Hwang
Ognev, Alexey
Piramanayagam, S. N.
Ripka, Pavel
Samardak, Alexander
Shin, Kwang-Ho
Tong, Shi-Yuan
Tung, Mean-Jue
Wang, Shan X.
Xue, Songsheng
Yin, Xiaolu
Pong, Philip W. T.
Magnetoresistive sensor development roadmap (non-recording applications)
description Magnetoresistive (MR) sensors have been identified as promising candidates for the development of high-performance magnetometers due to their high sensitivity, low cost, low power consumption, and small size. The rapid advance of MR sensor technology has opened up a variety of MR sensor applications. These applications are in different areas that require MR sensors with different properties. Future MR sensor development in each of these areas requires an overview and a strategic guide. An MR sensor roadmap (non-recording applications) was therefore developed and made public by the Technical Committee of the IEEE Magnetics Society with the aim to provide an research and development (R&D) guide for MR sensors intended to be used by industry, government, and academia. The roadmap was developed over a three-year period and coordinated by an international effort of 22 taskforce members from ten countries and 17 organizations, including universities, research institutes, and sensor companies. In this paper, the current status of MR sensors for non-recording applications was identified by analyzing the patent and publication statistics. As a result, timescales for MR sensor development were established and critical milestones for sensor parameters were extracted in order to gain insight into potential MR sensor applications (non-recording). Five application areas were identified, and five MR sensor roadmaps were established. These include biomedical applications, flexible electronics, position sensing and human-computer interactions, non-destructive evaluation and monitoring, and navigation and transportation. Each roadmap was analyzed using a logistic growth model, and new opportunities were predicted based on the extrapolated curve, forecast milestones, and professional judgment of the taskforce members. This paper provides a framework for MR sensor technology (non-recording applications) to be used for public and private R&D planning, in order to provide guidance into likely MR sensor applications, products, and services expected in the next 15 years and beyond.
author2 School of Physical and Mathematical Sciences
author_facet School of Physical and Mathematical Sciences
Zheng, Chao
Zhu, Ke
De Freitas, Susana Cardoso
Chang, Jen-Yuan
Davies, Joseph E.
Eames, Peter
Freitas, Paulo P.
Kazakova, Olga
Kim, Cheol Gi
Leung, Chi-Wah
Liou, Sy-Hwang
Ognev, Alexey
Piramanayagam, S. N.
Ripka, Pavel
Samardak, Alexander
Shin, Kwang-Ho
Tong, Shi-Yuan
Tung, Mean-Jue
Wang, Shan X.
Xue, Songsheng
Yin, Xiaolu
Pong, Philip W. T.
format Article
author Zheng, Chao
Zhu, Ke
De Freitas, Susana Cardoso
Chang, Jen-Yuan
Davies, Joseph E.
Eames, Peter
Freitas, Paulo P.
Kazakova, Olga
Kim, Cheol Gi
Leung, Chi-Wah
Liou, Sy-Hwang
Ognev, Alexey
Piramanayagam, S. N.
Ripka, Pavel
Samardak, Alexander
Shin, Kwang-Ho
Tong, Shi-Yuan
Tung, Mean-Jue
Wang, Shan X.
Xue, Songsheng
Yin, Xiaolu
Pong, Philip W. T.
author_sort Zheng, Chao
title Magnetoresistive sensor development roadmap (non-recording applications)
title_short Magnetoresistive sensor development roadmap (non-recording applications)
title_full Magnetoresistive sensor development roadmap (non-recording applications)
title_fullStr Magnetoresistive sensor development roadmap (non-recording applications)
title_full_unstemmed Magnetoresistive sensor development roadmap (non-recording applications)
title_sort magnetoresistive sensor development roadmap (non-recording applications)
publishDate 2021
url https://hdl.handle.net/10356/151182
_version_ 1702431305611870208

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