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研究生: 劉志祥
Chih-Shang Liu
論文名稱: 應用相位調變八字形光纖鎖模雷射於光纖與衛星光通訊系統整合之研究
Study of Integrating Fiber and Optical Satellite Communication System with Applying Phase Modulated Figure Eight Mode-Locked Fiber Laser
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: 2004
畢業學年度: 92
語文別: 英文
論文頁數: 117
中文關鍵詞: 鎖模超快光學脈衝產生器八字形光纖通訊衛星通訊主動鎖模
英文關鍵詞: mode-locked, ultrafast optics, pulse generator, figure eight, fiber communication, satellite communication, active mode locking
論文種類: 學術論文
相關次數: 點閱:177下載:1
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  • 本文提出高速相位調變鎖模雷射與傳輸系統之整合,於高速雷射光源之共振腔部份,是利用一個相位調變器,注入外加調變訊號,使共振腔內之縱模產生建設性干涉,近而達到以低頻外加調變訊號,倍增其光訊號之重複率的諧波鎖模雷射。此外,我們微調外加調變訊號,以分析外加調變訊號對脈衝寬度、脈衝重複率、脈衝抖動、週期、上升時間和下降時間等因數的影響。於傳輸系統方面,我們設計長距離光纖傳輸和無線衛星光通訊系統之整合。在光纖長距離傳輸部分,我們以長距離單模光纖搭配色散補償光纖光柵,使色散得以補償,並以摻鉺光纖放大器補償長距離傳輸的損失,於此系統,我們會試圖改變模擬與理論參數,以眼圖評估其最佳傳輸效能。於無線衛星光通訊部分,採頻移鍵控式調變訊號,並考慮氣候、發散角等因素,及納入高速鎖模雷射頻寬之考量,以評估整合光纖及衛星光通信之整體系統效能。

    In this thesis, we propose a fiber-satellite integration using a high speed phase-modulated mode-locked figure-eight laser and transmission system. In the cavity of high speed laser source, we utilize a phase modulator to inject additive modulation signal. The modulation signal can let the longitudinal mode in cavity produce constructive interference, and then, achieve small modulation signal to excite harmonic and rational mode-locked laser in high repetition rate. After producing high speed mode-locked laser, we do detuning the modulation parameters to analyze the effect of repetition rate, pulsewidth, rise time, falling time and jitter. In optical transmission systems, we consider the integration of long-distance fiber transmission and wireless optical satellite communication. 100 km long single mode fiber is used in the long-distance fiber transmission analysis. We also insert the fiber Bragg grating to compensate chromatic dispersion. In optical satellite communication system, we consider the impact of weather, beam divergence angle and so on. We evaluate the conditions and search the optimal parameters in long-distance and optical satellite integrated transmission for looking for the optimum efficiency.

    Chinese Abstract...............................................i English Abstract..............................................ii Acknowledgment................................................iv Contents.......................................................v List of Figures.............................................xiii List of Tables................................................xv Chapter 1 Introduction.........................................1 Chapter 2 Theoretical and Experimental Analysis of A Phase Modulated Mode-Locked Figure Eight Fiber Laser.......4 2-1 Introduction...............................................4 2-2 System Description........................................11 2-3 Theoretical Model.........................................12 2-3-1 Time-Domain ABCD Matrix.................................13 2-3-2 Theoretical Model of A Phase-Modulated Model Locked F8L.....................................................15 2-4 Analysis of Results.......................................17 2-4-1 5 Gb/s Pulse Train Generation.......................18 2-4-2 10 Gb/s Pulse Train Generation......................19 2-4-3 20 Gb/s Pulse Train Generation......................20 2-4-4 40 Gb/s Pulse Train Generation......................21 2-5 Summary...................................................21 Chapter 3 Long-Distance Transmission of Mode-Locked Laser with Fiber Bragg Grating................................53 3-1 Introduction..............................................53 3-2 Single Channel Fiber Long-Transmission System.............55 3-2-1 Unreaptered Transmission System.........................55 3-2-2 Dispersion Mapping System...............................56 3-3 Theoretical Analysis of The System........................56 3-3-1 Power Penalty Induced by Dispersion.................57 3-3-2 Bit Error Rate......................................59 3-4 Summary and Discussion....................................64 Chapter 4 Coherent Satellite Optical Communication Networks...........................................88 4-1 Introduction..............................................89 4-2 Design of The System......................................91 4-3 Theoretical Model.........................................92 4-3-1 Transmitter, Receiver and AFC........................92 4-3-2 Scattering and Absorption of Atmosphere..............94 4-3-3 Beam Divergence......................................95 4-3-4 Vibration of Satellite...............................97 4-3-5 The Received Signal..................................98 4-3-6 BER of FSK Baseband Data.............................99 4-4 Numerical Analysis.......................................102 4-5 Summary and Discussion...................................103 Chapter 5 Conclusions........................................115 References...................................................118 Publication Lists...........................................xvii

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