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研究生: 朱培源
Pei Yuan Chu
論文名稱: 環形諧波鎖模光纖雷射之研究與應用
Study of Fiber Ring Harmonic Mode-Locked Laser and Applications
指導教授: 曹士林
Tsao, Shyh-Lin
學位類別: 碩士
Master
系所名稱: 光電工程研究所
Graduate Institute of Electro-Optical Engineering
論文出版年: 2007
畢業學年度: 95
語文別: 英文
論文頁數: 109
中文關鍵詞: 環形雷射高速脈衝
英文關鍵詞: fiber laser, high pulse train
論文種類: 學術論文
相關次數: 點閱:129下載:2
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  • 本文提出利用不同調變器於環形光纖雷射架構做調變,並利用振幅調變器外加調變信號對共振腔內部做振幅調變產生高速脈衝信號並放入半導體光放大器於架構中以達到振幅鎖模與脈衝穩定的效果,之後我們再利用相位調變器外加調變信號使其共振腔內部的縱像模態做相位的鎖模,最後使用外加信號激發極化鍵控調變器利用極化的變化以達到高速脈衝鎖模的效果。在本實驗中使用三種不同的調變器,並加調變信號加以分析,脈衝重複率、脈衝抖動、上升時間的影響。

    In this thesis, we propose a fiber ring harmonic mode-locked fiber laser and detuning modulation frequency. We generate amplitude modulation by exciting outside RF modulation signal. In case of producing high speed pulse train signal, we also drive SOA in the fiber ring cavity system to stable the output high speed pulse train. Then we also generate phase modulation by exciting outside RF signal to make the phase longitudinal modes locking. At the last, we utilize polarization shift keying technique to produce high speed pulse train in the fiber ring cavity system.
    In this fiber ring cavity system, we use three different kinds component to produce high speed pulse train and detuning the RF modulation frequency to analyze the repetition rate, RMS jitter, and rise time, respectively.

    Chapter 1 Introduction....................................1 Chapter 2 Amplitude Modulated Harmonic Mode-Locked Fiber Laser.....................................................4 2-1 Introduction..........................................4 2-2 Theory of Mode-Locking................................7 2-2-1 Active mode locked.................................10 2-2-2Amplitude Modulation Mode Locking...................11 2-2-3 Rational Harmonic Mode-Locking.....................12 2-3Experimental Amplitude Analysis of Harmonic Mode-Locked Fiber Laser with SOA.....................................14 2-3-1 Theory of SOA..................................14 2-3-2 Experimental Setup.............................17 2-3-3 Analysis of Results............................18 2-3-3-1 5 GHz Pulse Train Generation............19 2-3-3-2 10 GHz Pulse Train Generation....................19 2-3-3-3 15 GHz Pulse Train Generation....................19 2-3-3-4 25 GHz Pulse Train Generation....................20 2-3-3-5 30 GHz Pulse Train Generation....................20 2-3-3-6 40 GHz Pulse Train Generation....................20 2-4 Discussion and Summary...............................20 Chapter 3 Apply Phase Modulation Harmonic Mode-Locked Fiber Ring Laser...............................................35 3-1 Introduction ........................................35 3-2 Phase Modulation Mode Locking........................38 3-2-1 Harmonic Mode-Locking..............................40 3-2-2 Noise Source of Active Mode-Locking................43 3-3 Experimental Phase Analysis of Harmonic Mode-Locked Fiber Laser..............................................43 3-3-1 Experimental Setup.............................44 3-3-2 Experimental Results...........................44 3-3-2-1 5 GHz Pulse Train Generation.....................46 3-3-2-2 10 GHz Pulse Train Generation....................46 3-3-2-3 20 GHz Pulse Train Generation....................47 3-3-2-4 50 GHz Pulse Train Generation....................47 3-4 Summary..............................................48 Chapter 4 PolSK Modulated Harmonic Mode-Locked Fiber Ring Laser................................................... 60 4-1 Introduction.........................................60 4-2 Theory of PolSK......................................63 4-2-1 Performance of PolSK Modulation Schemes............73 4-2-2 Principles of Operation – Optical.................78 4-2-3 Principles of Operation – Electrical..............80 4-3 PolSK of Harmonic Mode-Locked Fiber Ring Laser Experiment...............................................80 4-3-1Experimental Setup..................................81 4-4 Experimental Result..................................82 4-4-1 5 GHz Pulse Train Generation.......................83 4-4-2 7.5 GHz Pulse Train Generation.....................83 4-4-3 10 GHz Pulse Train Generation......................84 4-4-4 20 GHz Pulse Train Generation......................84 4-5 Summary..............................................85 Chapter 5 Conclusions....................................97 Reference................................................99

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