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研究生:陳信昌
研究生(外文):Shin-Chang Chen
論文名稱:植基於微環形耦合共振腔全光式元件之研究
論文名稱(外文):All-Optical Devices Base on Microring Coupled Resonator Optical Waveguides
指導教授:吳曜東吳曜東引用關係
指導教授(外文):Yaw-Dong Wu
學位類別:碩士
校院名稱:國立高雄應用科技大學
系所名稱:電子工程系
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:2009
畢業學年度:97
語文別:英文
論文頁數:90
中文關鍵詞:全光式元件分光器光延遲裝置邏輯閘
外文關鍵詞:all optical devicessplitterdelay linelogic gate
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本論文中,吾人探討微環形耦合共振光波導的特性,來加以設計結構,主因莫過於平面光波導十分適合應用在光學的各方面領域。吾人藉由環形光波導的特性、平面波展開法與有限時域差分法等的模擬,來設計出數種全光式元件。
首先,吾人藉由環形光波導之特殊排列方式,來改變光波之傳播方向,以設計一全光式光延遲裝置,且其時間達2.91ps,傳輸率達97%。接著再利用對稱性排列之環形光波導,來達成破壞性或建設性干涉,以設計全光式邏輯閘。最後,再利用環形光波導之寬度和波導間之距離,來達到不同的耦合效果,以設計一八應用波長之全光式分光器,且傳輸率皆達80%。
數值結果顯示,吾人所提出的微環形光波導結構,的確可作為全光式光延遲裝置、邏輯閘、及分光器的應用。在超高速與超高容量的光通與光資訊處理應用中,這些結構將扮演極重要的關鍵元件。
In this study, we discussed the properties of microring coupled resonator optical waveguides. We analyze the microring coupled resonator optical waveguides. Microring coupled resonator optical waveguides mean that the optical wave in the straight waveguide will be partially coupled into the circular waveguide. By using the properties of the microring coupled resonator optical waveguide, plane-wave expansion method and finite-difference time-domain method, the new all-optical delay line device, logic gate device and beam splitter device are proposed.
Firstly, we demonstrate a new all optical delay line structure by using the special arrangement of microring resonator waveguides to change wave propagation direction. We clearly obtained that the novel structure’s delay time is 2.91 ps, its power transmission is 97% and its operating wavelength is at 1.55 μm Second, we demonstrate new all optical logic gate structures including Not, Or, And, Nor and Nand gate by using symmetrical microring coupled resonator waveguides to control interference between straight waveguides and microring coupled resonator optical waveguides. Finally, we demonstrate a new all optical beam splitter structure by using special waveguides width to split TE and TM mode.
The numerical results show that the proposed structures really could function as an all-optical delay light device, logic gate devices, and an all-optical beam splitter device. These would be potential key component in the applications of ultra-high-speed and ultra-high-capacity optical communications and optical data processing systems.
Abstract
Chapter 1: Introduction 1
Chapter 2: Principles of Coupled Resonator Optical Waveguides
2.1. Cylindrical Microresonators 5
2.2. Analysis of coupled resonator optical waveguide 6
Chapter 3: Novel All-Optical Delay Line Containing Circular Arrangement Micro-ring Coupled Resonator Optical Waveguides
3.1. Introduction 17
3.2. Analysis Process 19
3.3. Numerical Results and Discussions 20
3.4. Summary 21
Chapter 4: Novel All-Optical Logic Gate Devices Based On Symmetric Microring Coupled Resonator Optical Waveguides
4.1. Introduction 26
4.2. Analysis Process 27
4.3. Numerical Results and Discussions 29
4.4. Summary 31
Chapter 5: Novel All-Optical Polarization Beam splitter Based on Microring Coupled Resonator Optical Waveguides
5.1. Introduction 49
5.2. Analysis Process 50
5.3. Numerical Results and Discussions 52
5.4. Summary 53
Chapter 6: Conclusions 67
References 69
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