バイポーラ永久磁石型低磁場MRI装置の設計最適化に関する研究
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- Material Type
- 博士論文
- Author/Editor
- 孔, 暁涵
- Author Heading
- Publication, Distribution, etc.
- Publication Date
- 2023-12-25
- Publication Date (W3CDTF)
- 2023-12-25
- Alternative Title
- A Study on the Design Optimization of the Bipolar Permanent Magnet Type Low-field MRI Device
- Contributor
- 五十嵐, 一野口, 聡北, 裕幸近野, 敦
- Degree Grantor
- 北海道大学
- Date Granted
- 2023-12-25
- Date Granted (W3CDTF)
- 2023-12-25
- Dissertation Number
- 甲第15695号
- Degree Type
- 博士(情報科学)
- Text Language Code
- eng
- Subject Heading
- NDC
- Target Audience
- 一般
- Note (General)
- (主査) 教授 五十嵐 一, 教授 野口 聡, 教授 北 裕幸, 教授 近野 敦情報科学院(情報科学専攻)
- DOI
- 10.14943/doctoral.k15695
- Persistent ID (NDL)
- info:ndljp/pid/13520707
- Collection
- Collection (Materials For Handicapped People:1)
- Collection (particular)
- 国立国会図書館デジタルコレクション > デジタル化資料 > 博士論文
- Acquisition Basis
- 博士論文(自動収集)
- Date Accepted (W3CDTF)
- 2024-04-05T22:42:17+09:00
- Format (IMT)
- application/pdf
- Access Restrictions
- 国立国会図書館内限定公開
- Service for the Digitized Contents Transmission Service
- 図書館・個人送信対象外
- Availability of remote photoduplication service
- 可
- Periodical Title (URI)
- Is Referenced By (URI)
- Data Provider (Database)
- 国立国会図書館 : 国立国会図書館デジタルコレクション
- Summary, etc.
- In recent years, portable low-field Magnetic resonance imaging (MRI) devices have been developed to complement high-field superconducting MRI. Portable low-field MRI devices offer advantages such as being lightweight, movable, and providing low-cost diagnostic services compared to the commonly used high-field MRI devices. However, there are still some challenges to be addressed, particularly concerning the electromagnetic (EM) structure, including gradient coil design and permanent magnets design. Based on how the main magnetic field is generated, there are different types of low-field MRI device. Among these, the bipolar permanent magnet type low-field MRI device is commonly used due to its advantages, such as good magnetic field homogeneity, structural compactness, and an open imaging area. However, some problems remain to be studied, especially about the EM structure including gradient coil design and permanent magnets design. In this paper, we focus on the design optimization of the bipolar permanent magnet type low-field MRI device, the main content of the thesis is as follows: In Chapter 1, the research background and motivations are introduced, and the contributions of this study are also summarized. In Chapter 2, a novel method for designing gradient coils for low-field MRI devices is proposed. The proposed method considers the effect of magnetic materials, particularly anti- eddy plates, by introducing image dipole currents. In the optimal design of gradient coils, the effect of ferromagnetic materials is minimized to obtain highly linear fields. The magnetic field measurement results and phantom images reveal the validity of the proposed method. In Chapter 3, a design method for Z-gradient coils in low-field MRI systems is proposed, focusing on enhancing anti-eddy performance. The newly introduced design procedure significantly improves the anti-eddy performance of the coils. Measurement and imaging results demonstrate that the optimal coil exhibited superior anti-eddy performance compared to conventional coils. In Chapter 4, a multi-fidelity topology optimization method has been proposed to alleviate the local optima problem. This method simplifies the design difficulty by dividing the optimization into sub-problems at the physical level. The proposed method shows a better performance than the conventional method in the design of low-field MRI devices. In Chapter 5, a passive shimming method is proposed for fine-tuning the static magnetic field in a low-field MRI device. A test case validated the effectiveness of this approach, reducing non-uniformity from 10,000 ppm to 125 ppm after three iterations. In Chapter 6, conclusions and future works are discussed.
- DOI
- 10.14943/doctoral.k15695
- Format (IMT)
- application/pdf
- Source
- Xiaohan_Kong.pdf (fulltext)
- Access Restrictions
- インターネット公開
- Is Referenced By (URI)
- HDL
- Data Provider (Database)
- 国立情報学研究所 : 学術機関リポジトリデータベース(IRDB)(機関リポジトリ)
- Original Data Provider (Database)
- 北海道大学 : 北海道大学学術成果コレクション