Materials and devices for spin-based neuromorphic computing – application of spintronics to fzzy logic
Research in the area of Spintronics is gradually gaining popularity in recent times due to the stagnation of Moore’s Law and the electronics industry. The research conducted in this paper aims to adopt Spin-based Domain Wall devices for application in Neuromorphic Computing where methods for low-pow...
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Nanyang Technological University
2021
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sg-ntu-dr.10356-1482332023-02-28T23:14:08Z Materials and devices for spin-based neuromorphic computing – application of spintronics to fzzy logic Poh, Cai MIn S.N. Piramanayagam School of Physical and Mathematical Sciences prem@ntu.edu.sg Science::Physics Research in the area of Spintronics is gradually gaining popularity in recent times due to the stagnation of Moore’s Law and the electronics industry. The research conducted in this paper aims to adopt Spin-based Domain Wall devices for application in Neuromorphic Computing where methods for low-power consumption Artificial Intelligence and Machine Learning is explored. The mechanism of Spin Orbit Torque will be explored in this paper, exploring a novel design of a dual-tungsten layer which is able to achieve low power requirement for movement of domain walls. Also, a new logic system called Fuzzy Logic is in the process of being tested for implementation through spin-based domain wall devices. The device focuses on the idea of geometrical domain wall pinning and also multi-resistive states that is necessary for this fuzzy logic system over the classical Boolean logic. As a proof of concept, the movement of a domain wall has shown to be controlled and domain wall devices for Fuzzy Logic implementation has been shown to be possible through said devices. This will assist in the agenda of promoting lower power consumption Artificial Intelligence by mimicking a synaptic learning as stated in Neuromorphic Computing. Bachelor of Science in Physics 2021-04-26T02:22:03Z 2021-04-26T02:22:03Z 2021 Final Year Project (FYP) Poh, C. M. (2021). Materials and devices for spin-based neuromorphic computing – application of spintronics to fzzy logic. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/148233 https://hdl.handle.net/10356/148233 en PH4415 application/pdf Nanyang Technological University |
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Science::Physics Poh, Cai MIn Materials and devices for spin-based neuromorphic computing – application of spintronics to fzzy logic |
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Research in the area of Spintronics is gradually gaining popularity in recent times due to the stagnation of Moore’s Law and the electronics industry. The research conducted in this paper aims to adopt Spin-based Domain Wall devices for application in Neuromorphic Computing where methods for low-power consumption Artificial Intelligence and Machine Learning is explored. The mechanism of Spin Orbit Torque will be explored in this paper, exploring a novel design of a dual-tungsten layer which is able to achieve low power requirement for movement of domain walls. Also, a new logic system called Fuzzy Logic is in the process of being tested for implementation through spin-based domain wall devices. The device focuses on the idea of geometrical domain wall pinning and also multi-resistive states that is necessary for this fuzzy logic system over the classical Boolean logic. As a proof of concept, the movement of a domain wall has shown to be controlled and domain wall devices for Fuzzy Logic implementation has been shown to be possible through said devices. This will assist in the agenda of promoting lower power consumption Artificial Intelligence by mimicking a synaptic learning as stated in Neuromorphic Computing. |
| author2 |
S.N. Piramanayagam |
| author_facet |
S.N. Piramanayagam Poh, Cai MIn |
| format |
Final Year Project |
| author |
Poh, Cai MIn |
| author_sort |
Poh, Cai MIn |
| title |
Materials and devices for spin-based neuromorphic computing – application of spintronics to fzzy logic |
| title_short |
Materials and devices for spin-based neuromorphic computing – application of spintronics to fzzy logic |
| title_full |
Materials and devices for spin-based neuromorphic computing – application of spintronics to fzzy logic |
| title_fullStr |
Materials and devices for spin-based neuromorphic computing – application of spintronics to fzzy logic |
| title_full_unstemmed |
Materials and devices for spin-based neuromorphic computing – application of spintronics to fzzy logic |
| title_sort |
materials and devices for spin-based neuromorphic computing – application of spintronics to fzzy logic |
| publisher |
Nanyang Technological University |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/148233 |
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