本論文的研究在於利用電吸引法的製作一維透鏡光纖陣列，藉由電極加電壓後對透鏡的吸引而形成圓錐狀，但是因光纖併排而造成透鏡所受的電場強度不均勻而產生透鏡成形時的偏移現象，因此我們以縮短電極長度來平衡透鏡所受的電場強度，以修正透鏡成形時的偏移。另外利用縮小光纖之間的間距，再配合適當的電極長度，使透鏡在成形時不產生偏移，並製作出高耦光效率的一維透鏡光纖陣列。
關於上述方法，在論文中除了以電腦模擬確定其可行性外，更以實驗證實其正確性。

The research is focus on manufacturing one dimension lens plastic optical fiber array, carrying out by electrostatic force was applied to shape polymer liquid from hemisphere into paraboloid or near cone shape. In manufacturing process, the lens will be slanted by electrostatic force, so we shorten the electrode to solve the problem, and shorten the distance between fiber and fiber to manufacture the most small volume of the fiber array. To combine the two methods, we can manufacture the high coupling efficiency of the one dimension lens plastic optical fiber array.
Finally, the above improved strategies are verified by the simulation and experimental results.

中文摘要..................................................i
英文摘要.................................................ii
總目錄..................................................iii
圖目錄....................................................v
表目錄.................................................viii
第一章 緒論..............................................1
1.1 塑膠光纖介紹.......................................1
1.2 光纖陣列介紹.......................................4
1.3 研究動機...........................................8
1.4 研究目的...........................................9
第二章 微透鏡成形技術...................................10
2.1 雷射技術加工......................................10
2.2 LIGA技術加工......................................12
2.2.1 熔膠法.......................................12
2.2.2 滴定法.......................................13
2.3 電場技術加工......................................14
2.3.1 電濕潤法.....................................14
2.3.2 電吸引法.....................................16
第三章 研究方法.........................................19
3.1 透鏡光纖陣列成形與模擬............................19
3.1.1 電吸引法製作透鏡光纖陣列.....................19
3.1.2 透鏡光纖陣列電場模擬.........................27
3.2 透鏡成形偏移修正..................................32
3.3 光纖間距最小化....................................36
第四章 實驗與成果.......................................42
4.1 實驗配置..........................................42
4.2 最佳透鏡曲率實驗參數..............................46
4.3 點膠體積量測......................................47
4.4 實驗步驟與成果....................................49
第五章 結論與未來展望...................................59
5.1 結論..............................................59
5.2 未來工作..........................................59
參考文獻.................................................60

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