# 臺灣博碩士論文加值系統

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 構裝過程中最重要也是最為複雜、繁瑣的步驟即為耦合對準的部分，因為這個過程對光耦合效率有最直接的影響，而在對準的過程中，過多參數的調整變化不易同時掌握，所以目前大部分的對準過程中搜尋最高耦合效率位置時，大多藉著減少自由度來簡化對準過程，尤其是角度對準。本文開發一多軸自動化耦合對準系統時，在觀察模擬結果後發現，對XY平面來說，在角度有誤差的情況下光耦合效率光偶合效率最高的位置並不會改變，故發展出2+2個自由度之搜尋法則，來達到四個自由度(X、Y、θx、θy)之自動化搜尋目標，結果可得到較高之耦合效率與快速之耦合對準過程。
 The most complicated and important step in optical packaging is coupling alignment. It is very difficult to handle too many parameters at the same time during the coupling alignment process. Most of the parameters are neglected in coupling alignment process, especially the parameters of angles.According to the analysis, we found that the misalignment of angles do not have influence on the position of highest coupling efficiency in XY plane. A 2+2 freedom searching method has been developed to reach the four axis coupling alignment. An automatic coupling alignment system has been carried out. And it can reach higher coupling efficiency and faster coupling alignment process.
 第一章 序論 1 1.1研究動機 1 1.2研究目的 2第二章 文獻回顧 32.1 目前耦合對準的方法 32.2 目前之耦合對準架構與其數據 5 2.3 搜尋方法 6第三章 研究方法 11 3.1 敏感度的計算與模擬 11 3.2 搜尋法則 15第四章 實驗 16 4.1 系統之建構 16 4.2 實驗量測 19第五章 結論與未來展望 24第六章 參考文獻 25
 1.David S. Alles, “Trends in Laser Packaging,” Electronic Components and Technology Conference, 1990. Proceedings. 40th, pp.185-192, 20-23 May 1990.2.Michael R. Matthews, ”Optical Components-the New Challenge in Packaging,” IEEE Transactions on Components, Hybrids, and Manufacturing Technology, Vol. 13, No. 4, pp. 798-806, Dec 1990.3.E. Suhir, “Microelectronics and Photonics-the Future,” Journal of Microelectronics, Vol. 31, pp.839-851, 2000.4.M. Eiklenborg, “Tools and Methods for Obtaining Precision Fiber Alignments,” IMPAS Advanced Technology Workshop on Optoelectronics Packaging, Oct. 11-14, 2001.5.Mino F. Dautartas, “Hybrid Optical Packaging, Challenges and Opportunities,” Electronic Components and Technology Conference, 2002. Proceedings. 52nd, pp.787-793, 2002.6.J.W. Shakespeare, “Optical Alignment in Optoelectronic Components,” Advanced Microelectronics, Vol. 9, No. 1, 2002.7.W. B. Joyce, “Alignment of Gaussian Beams,” Applied Optics, Vol. 23, No. 23, pp.4187-4196, 1984.8.L. A. Wang, “Tolerance Analysis of Aligning an Astigmatic Laser Diode with a Single-Mode Optical Fiber,” Journal of Lightwave Technology, Vol. 14, No. 12, pp. 2757-2762, 1996.9.S. Gangopadhyay, “Misalignment Consideration in Laser Diode to Single-Mode Fibre Excitation via Hyperbolic Lens on the Fibre Tip,” Optics Communications, Vol.146, pp.104-108, 1998.10.R. Zhang, “Fiber-Optical Angular Alignment Automation：Recent Progress,” Optoelectronics Packaging & Automation Lab., Samueli School of Engineering, University of California, Irvine, 2001.11.Z. Tang, “Effects of Angular Misalignments on Fiber-Optic Alignment Automation,” Optics Communications, Vol.196, pp. 173-180, 2001.12.M. Sumida, “Lens Coupling of Laser Diode to Single-Mode Fibers,” Journal of Lightwave Technology, pp.305-311, 1984.13.K. Kawano, “A New Confocal Lens Method for a Laser-Diode Module Using a Single-Mode Fiber,” Journal of Lightwave Technology, Vol. 3, No. 4, pp.739-745, 1985.14.Y. Makita, “GRIN Lenses for High Efficiency Coupling of Laser Diode to Single Mode Fiber,” Fiber and Integrated Optics, pp. 27-33, 1988.15.L. A. Reith, “Relaxed-Tolerance Optoelectronic Device Packaging,” Journal of Lightwave Technology, Vol. 7, No. 4, pp.477-484, April 1991.16.C. A. Edwards, “Ideal Microlenses for Laser to Fiber Coupling,” Journal of Lightwave Technology, Vol. 11, No. 2, pp. 252-257, Feb 1993.17.H. M. Presby, “Asymmetric Fiber Microlenses for Efficient Coupling to Elliptical Laser Beams,” IEEE Photonics Technology Letters, Vol. 5, No. 2, pp. 184-186, Feb 1993.18.C. A. Edwards, “Coupling-Sensitivity Comparison of Hemispheric and Hyperbolic Microlenses,” Applied Optics, pp.1573-1577, 1993.19.A. Ogura, “Efficient Coupling Between Laser Diodes with a Highly Elliptic Field and Single-Mode Fibers by Means of GIO Fibers,” IEEE Photonics Technology Letters, Vol. 13,No. 11, pp. 1191-1193, Nov 2001.20.G. V. Reklatis, “Engineering Optimization Methods and Applications,” John Wiley & Sons, Inc., 1983.21.徐業良，「工程最佳化設計」，宏明書局，民國84年10月初版。22.黃見裕 ，「光纖陣列的製造與構裝」，國立台灣大學光電科學研究所，民國82年。23.陳伯睿，「光纖自動對準組裝技術研發」，國立台灣大學機械工程研究所碩士論文，民國90年6月。24.莊育樹，「應用光纖透鏡與矽蝕刻方法於半導體雷射被動定位構裝之研究」，國立台灣科技大學機械工程研究所碩士論文，民國91年6月。
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 1 光纖自動對準組裝技術研發 2 光纖陣列的製造與構裝 3 應用透鏡光纖與矽蝕刻方法於半導體雷射被動定位構裝之研究 4 以蝕刻保護層製作大錐度比光纖透鏡研究 5 光纖陣列尋光對準的耦合技術 6 光纖套管扣件創新設計之研究 7 新型四角錐形光纖透鏡 8 光纖與鈮酸鋰光波導直接耦合之研究 9 利用Expanded-Core結構耦合光纖與矽通道波導 10 光纖通訊的架構分析與田氏法之應用 11 側磨型光纖耦合器 12 光纖與鈮酸鋰光波導耦合效率之改良 13 光纖耦合器的探討及製作

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 1 光纖自動對準組裝技術研發 2 光纖陣列尋光對準的耦合技術 3 應用於一維光纖陣列的主動式對準技術 4 光接收器次模組(ROSA)尋光對位系統之研發與自動化 5 光纖套管扣件創新設計之研究 6 光通訊元件對位系統之設計與建立 7 裸光纖研磨機之線上檢測系統開發 8 多自由度光纖自動對準技術之研究 9 運用最佳化理論於主動式光纖多蕊對位之研究 10 塑膠透鏡光纖之新型構裝方式 11 光開關自動對位與封裝測試之研究 12 楔形光纖陣列的製造 13 運用最佳化理論於光纖對位之研究 14 光纖套管之主動式灌錫機制開發 15 高精度之光纖套管構裝與檢測系統

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