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研究生: 李岳峯
Lee, Yueh-Feng
論文名稱: 使用主動Q-調制環型共振雷射於以光時域反射儀為架構之光纖入侵感測系統
Distributed Fiber-Optic OTDR-Based Intrusion Sensor System Using Actively Q-Switched Ring Laser
指導教授: 王立康
Wang, Li-Karn
口試委員: 馮開明
劉文豐
學位類別: 碩士
Master
系所名稱: 電機資訊學院 - 光電工程研究所
Institute of Photonics Technologies
論文出版年: 2018
畢業學年度: 106
語文別: 中文
論文頁數: 50
中文關鍵詞: 入侵光時域反射儀Q調制馬克詹德干涉儀
外文關鍵詞: intrusion, opticaltimedomainreflectometer, qswitch, mach-zehnderinterfermeter
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    • 本論文利用實驗室自製馬克詹德干涉儀搭配環形共振腔產生的脈衝打進八點八公里的長光纖,來測量背向雷利散射。由於馬克詹德干涉儀會因為光纖震動所產失的相位變化發生建設性干涉或破壞性干涉,就可以利用此機制來產生脈衝。當產生破壞性干涉時,共振腔裡無能量產生。當為建設性干涉時,共振腔裡有極高的能量,就會形成脈衝。而我們將此脈衝打入感測光纖裡,來產生背向的雷利散射。雷利散射也會因為光纖的震動或是拍擊所產生的相位變化而有能量強度的高低變化。利用此散射的強度變化,我們可以來推測出光纖中的扭曲抑或是經由入侵引起之相位變化造成的干涉,即可反推出入侵訊號在光纖中的位置,以此來達到防區的效果。

    In this paper, we use a pulse laser, formed by incorporating a Mach-Zehnder interferometer in a ring resonator of a fiber laser, and launch the pulse into an 8.8 kilometer bare fiber, to detect backward Rayleigh scattering. The Mach-Zehnder interferometer is very sensitive to the phase difference caused by the perturbation on the fiber. So when it is destructive interference, it means there is no power in the cavity. On the contrary, there will be lots of energy when constructive interference occurs. Backward Rayleigh scattering is also sensitive to the phase difference caused by the perturbation on the fiber. So it means that when there is a phase difference caused by the perturbation on the fiber, the power of backward Rayleigh scattering would change. We can then determine whether the fiber is bent or vibrated by inspecting the power variation of the backward Rayleigh scattering. So this system can be used for security of perimeter zones.

    第一章 序論 1 1.1 研究背景 1 1.2 研究目的與動機 2 1.3 文獻回顧 3 1.3.1 同調耦合之Q-調制光纖雷射 3 1.3.2 以干涉儀進行Q-調制之系統 4 1.3.3 分析與設計利用雙臂干涉儀製作高輸出光纖雷射 5 1.3.4 光時域反射儀(Optical time domain reflectometer, OTDR) 6 1.3.5 拉曼光時域反射系統 7 1.4 論文架構 8 第二章 原理與介紹 9 2.1 光纖(Optical fiber) 9 2.2 光纖耦合器(Fiber coupler) 10 2.3 光纖循環器(Fiber circulator) 11 2.4 極化控制器(Polarization controller) 12 2.5 摻鉺光纖以及摻鉺光纖放大器(EDF and EDFA) 13 2.6 雷射共振腔(Laser cavity) 15 2.7 馬克詹德干涉儀(Mach-Zehnder Interferometer) 16 2.8 雷利散射(Rayleigh scattering) 18 2.9 干涉儀Q-調製雷射 20 第三章 實驗架構 21 3.1 環形共振腔雷射光源 21 3.2 訊號產生器驅動PZT產生脈衝 22 3.3 脈衝雷射進入OTDR系統 24 3.4 入侵位置推算法 25 第四章 實驗結果與分析 28 4.1 光源量測 28 4.1.1 泵激光源與雷射之關係 28 4.1.2 脈衝的基本數值 32 4.2 模擬入侵結果 35 第五章 結論與未來方向 43 5.1 結論 43 5.2 未來方向 44 參考文獻 45

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