從初步只包含石英單層毛細管光纖內部能量傳輸模擬計算,再改變不同輸入條件(不同入射角度、多模與單模)觀察毛細管光纖管壁模態與中芯模態分佈差異。模態模擬方面，在單純只包含石英毛細管光纖中加入一層高介質環改變其傳導機制，藉由模擬控制其高介質環幾何形狀(厚度)與其中芯空氣孔洞大小可模擬出其傳輸模態種類數量。藉著單層與雙層毛細管模態能量傳輸模擬與不同輸入條件模態變化，進一步了解毛細管光纖模態傳輸特性。
加入光纖耦合器觀念結合毛細管光纖與單模光纖製作出新型原件，再利用毛細管粗管塞管方式製作可更便利及快速製作出新型耦合器元件。

Purpose of this research is that capillary optic fiber transmission and energy distribution of internal energy.
Contains only single from the initial silica capillary fiber energy transfer within the simulation, and then changing the different input conditions (different incident angles, multi- mode and single mode) optical observation of the capillary wall modes and modal distribution between hole mode. Mode simulation, containing only the capillary in the simple addition of a layer of high-dielectric fiber optic ring to change its transmission mechanism, by analog control of its high dielectric ring geometry (thickness) of air holes the size of its hole mode can simulate the type of transmission mode number. By single-and double- layer energy transfer capillary mode simulation and modal changes in different input conditions, and further understanding of the capillary mode fiber transmission characteristics.
Combining the concept of adding fiber coupler and single-mode optical fiber capillary to produce a new original, and then by capillary tube method to make thick plugs can be more convenient and rapid production of a new type of coupler components.

論文審定書 i
致 謝 iii
中文摘要 iv
英文摘要 v
緒論
第一章 1
第二章 毛細管光纖之理論 3
2.1 毛細管光纖傳輸分佈探討 3
2.1.1 毛細管光纖能量計算 3
2.1.2 毛細管光纖能量分佈 7
2.2 不同輸入條件對於毛細管光纖之影響 14
2.2.1 輸入不同入射角度 14
2.2.2 輸入多模與單模 18
2.2.3 輸入多模與單模並偏移 21
2.3 雙層毛細管傳輸模態模擬計算 24
第三章 毛細管光纖製程 30
3.1 抽絲塔製作流程與其功能簡介 30
3.2 毛細管光纖製作 34
第四章 2X2光纖耦合器 36
4.1 毛細管光纖感測器應用 36
4.2 2X2新式光纖耦合器裝置製作 39
4.3 2X2新式光纖耦合器裝置測試 42
結論 45
參考文獻 47

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