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研究生:邱鄱碩
研究生(外文):Po-Shuo Chiu
論文名稱:使用積分球量測二階布拉格光纖光柵輻射損失
論文名稱(外文):Using Integrating Sphere to Measure the Radiation Loss of Second Fiber Bragg Grating
指導教授:孫迺翔孫迺翔引用關係
指導教授(外文):Nai-Hsiang Sun
口試委員:劉文豐蔣榮生于欽平
口試委員(外文):Wen-Fung LiuJung-Sheng ChiangChin-Ping Yu
口試日期:2022-01-25
學位類別:碩士
校院名稱:義守大學
系所名稱:電機工程學系
學門:工程學門
學類:電資工程學類
論文種類:學術論文
論文出版年:2022
畢業學年度:110
語文別:中文
論文頁數:213
中文關鍵詞:積分球二階光纖光柵輻射損失功率補償值輻射總功率
外文關鍵詞:Integrating Spheresecond-order FBGsradiation loss(ΔP)radiation total power
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本論文將了解積分球的特性與使用方式,與如何使用積分球量測總功率,利用積分球與ISU Test System (ISUTS系統),量測二階光纖光柵的總功率。積分球量測前須做光源輸出功率總量測,由積分球90° Port量測的功率值與總功率相比,可以求出90° Port量測功率與總功率之比值,亦即90° Port功率與總功率的補償值(ΔP),用此方式即可反推求得輻射總功率。我們將二階光纖光柵擺入積分球內量測輻射功率,光源傳播方向由0° Port輸入二階光纖光柵,180° Port輸出二階光纖光柵,90° Port為Photo Detector量測二階光纖光柵的輻射功率,利用本研究所量測求得的ΔP,最後我們成功量測求得二階光纖光柵的傳輸、反射與輻射總功率值。
We study how to use the integrating sphere in this thesis. The power of transmission, reflection and radiation of second-order fiber Bragg gratings (FBGs) are used to measure by ISU Test System (ISUTS system) with an integrating sphere. Firstly, the total power of a light source is measured. The power in the integrating sphere is detected in the 90° Port of the integrating sphere. We can obtain the total radiation power by calculating the ratio of the 90° Port power and the total power (ΔP). The second-order FBGs is set inside the center of the integrating sphere. By measuring the ratio ΔP of the integrating sphere, we obtain the power efficiencies of transmission, reflection and total radiation of second-order FBGs.
摘要 ⅴ
目錄 ⅷ
圖目錄 ⅹⅱ
表目錄 ⅹⅹⅴⅱ
第一章緒論 1
1.1前言 1
1.2研究目的與動機 2
1.3文獻回顧 3
1.4研究方法 6
1.5論文架構 7
第二章實驗架構與量測方法 8
2.1儀器與元件介紹 8
2.1.1可調式雷射光源(AGILENT /HP 8168F TUNABLE LASER SOURCE) 8
2.1.2摻鉺光纖放大器(ERBIUM-DOPED FIBER AMPLIFIER, EDFA) 9
2.1.3 桌上型光功率計(EXFO) 10
2.1.4可攜式光功率計(THORLABS) 10
2.1.5可攜式光功率計(NEWPORT) 11
2.1.6積分球(NEWPORT 819D-IS-5.3) 12
2.1.7步進馬達 16
2.1.8循環器(CIRCULATOR) 16
2.2 ISUTS量測系統 17
2.3 步進馬達量測系統 18
2.4布拉格光纖光柵與光電被動元件之損耗 19
2.5光纖光柵的製程 24
第三章積分球基本數據 26
3.1積分球架構 26
3.2積分球使用三種發光元件比較 28
3.3積分球洞口遮蔽對收光效果之影響 31
3.4積分球洞口發光實驗 34
3.4.1使用單模跳線與多模COLLIMATOR洞口發光之量測實驗 34
3.4.2單模跳線、單模FIBER0°PORT發光與內置壓克力板發光量測實驗 39
3.4.3多模跳線、多模FIBER0°PORT發光與內置壓克力板發光量測實驗 46
3.4.4積分球內置二階光纖光柵量測實驗 54
第四章積分球量測二階光纖光柵傳輸與反射與輻射特性 60
4.1積分球量測出來的輻射功率如何反推輻射總功率 60
4.1.1積分球量測曝光三分鐘二階光纖光柵(2ND-HL-03M)輻射且反推原始輻射值 61
4.1.2積分球量測曝光五分鐘二階光纖光柵(2ND-HL-05M)輻射且反推原始輻射值 66
4.1.3積分球量測曝光九分鐘二階光纖光柵(2ND-HL-09M)輻射且反推原始輻射值 71
4.1.4積分球量測曝光十一分鐘二階光纖光柵(2ND-HL-11M)輻射且反推原始輻射 76
4.2搭配積分球量測二階光纖光柵傳輸反射輻射特性 81
4.2.1二階光敏載氫曝光三分鐘光纖光柵(2ND-HL-03M) 82
4.2.2二階光敏載氫曝光五分鐘光纖光柵(2ND-HL-05M) 87
4.2.3二階光敏載氫曝光九分鐘光纖光柵(2ND-HL-09M) 92
4.2.4二階光敏載氫曝光十一分鐘光纖光柵(2ND-HL-11M) 97
4.3將二階光纖光柵朝下擺入積分球內發光實驗 102
4.3.1二階光敏載氫曝光三分鐘光纖光柵(2ND-HL-03M) 102
4.3.2二階光敏載氫曝光五分鐘光纖光柵(2ND-HL-05M) 108
第五章使用Newport(843-R)量測二階光纖光柵傳輸反射與輻射特性 113
5.1比較PM100D與843-R兩台功率計量測二階光敏載氫曝光五分鐘光纖光柵(2ND-HL-05M) 114
5.2二階光敏載氫曝光三分鐘光纖光柵(2ND-HL-03M) 120
5.3二階光敏載氫曝光五分鐘光纖光柵(2ND-HL-05M) 124
5.4二階光敏載氫曝光九分鐘光纖光柵(2ND-HL-09M) 127
5.5二階光敏載氫曝光十一分鐘光纖光柵(2ND-HL-11M) 130
第六章二階光纖光柵縱面與波長關係(PM100D與843R) 133
6.1二階光敏載氫曝光三分鐘+Z光纖光柵(2ND-HL-03M) 135
6.2二階光敏載氫曝光三分鐘-Z光纖光柵(2ND-HL-03M) 140
6.3二階光敏載氫曝光五分鐘+Z光纖光柵(2ND-HL-05M) 146
6.4二階光敏載氫曝光五分鐘-Z光纖光柵(2ND-HL-05M) 153
6.5二階光敏載氫曝光九分鐘+Z光纖光柵(2ND-HL-09M) 158
6.6二階光敏載氫曝光九分鐘-Z光纖光柵(2ND-HL-09M) 164
6.7二階光敏載氫曝光十一分鐘+Z光纖光柵(2ND-HL-11M) 170
6.8二階光敏載氫曝光十一分鐘-Z光纖光柵(2ND-HL-11M) 176
第七章結論 181
參考文獻 182
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[24] https://www.newport.com/p/819D-IS-5.3
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