中大機構典藏-NCU Institutional Repository-提供博碩士論文、考古題、期刊論文、研究計畫等下載:Item 987654321/69205
English  |  正體中文  |  简体中文  |  全文笔数/总笔数 : 80990/80990 (100%)
造访人次 : 41247962      在线人数 : 90
RC Version 7.0 © Powered By DSPACE, MIT. Enhanced by NTU Library IR team.
搜寻范围 查询小技巧:
  • 您可在西文检索词汇前后加上"双引号",以获取较精准的检索结果
  • 若欲以作者姓名搜寻,建议至进阶搜寻限定作者字段,可获得较完整数据
  • 进阶搜寻


    jsp.display-item.identifier=請使用永久網址來引用或連結此文件: http://ir.lib.ncu.edu.tw/handle/987654321/69205


    题名: 以鈮酸鋰晶體為基板製作3Gbps頻寬之快速光學調製器;Optical Modulator of 3Gbps bandwidth based on LiNbO3 Crystal
    作者: 吳宗霖;Wu,Tsung-Lin
    贡献者: 光電科學與工程學系
    关键词: 鈮酸鋰;鈦擴散;光調製器;lithium niobate;titanium indiffused process;optical modulator
    日期: 2015-10-23
    上传时间: 2015-11-04 17:28:57 (UTC+8)
    出版者: 國立中央大學
    摘要: 現今資訊時代的快速爆炸發展,資訊的傳輸量越趨龐大,並因世界網路
    的發展,國與國之間的訊息交換也越趨重要,大量的光纖海底電纜陸續被建
    造,而鈮酸鋰晶體憑藉其優異的晶體光學性質,且與電訊號傳輸相比,較難
    被竊取與竄改且所需之驅動能源也較低,符合世界的能源降低趨勢,被大量
    的被應用在其中,而隨著光通訊時代的來臨,各國無不重視光通訊的發展。
    快速電光調製器,為光通訊產業中不可或缺的一項元件,其藉由鈦波導
    擴散製程的優勢,具有低的傳播損耗,高的位元率、高發展應用性,以及低
    驅動電壓與低訊噪比、低環境溫度影響的優勢,逐漸在美洲、歐洲、日
    本……等之本島或跨國的光纖網路、海底電纜的相關設備中被採用。而我國
    也透過產學合作的方式與各單位進行相關的研究與發展,以其可以開發出相
    關商品,並完成國家自主研究之目標,並期望國家跟上世界各國光通訊世代
    的腳步,完成各種相關的產業升級與發展。
    本文製作出使用1550nm 光源之3Gbps 電光快速調製器。我們採用Z 切
    (Z-Cut)鈮酸鋰晶體,藉以使用鈮酸鋰晶體極高的電光系數,並依電光效應
    原理來達成,馬氏干涉儀波導的設計採用商用軟體R-Soft 來輔助完成,波
    導製作以金屬鈦擴散製程為主,完成設計波導寬度為7μm、間距寬度為60
    μm、S-Bend 長度為6000μm 單模傳輸之馬氏干涉儀(Mach-Zehnder)結構。
    電極設計使用高頻模擬軟體(High Frequency Structure Simulator,
    HFSS),並以高頻電訊號傳輸中常使用的共平面波導(Co-Planar Waveguide)
    電極結構,並以黃金為材料,當作調製器的驅動電極,得到電傳輸訊號頻寬
    (S21)達40GHz 以上,電傳輸反射訊號(S11)低於-18dB。緩衝層我們使用傳統
    半導體常見的二氧化矽,並以原子蒸鍍設備輔以製作,以期達成我們速度匹
    配的條件,並採用1μm 的厚度來搭配調製器的設計。且為了能夠在與速度
    匹配達成更佳的條件,我們必須採用厚電極的設計,所以我們也搭配電鍍系
    統,並使用對環境較無害的環保型金電鍍液為材料,在環境溫度35℃下,
    成功製作電極厚度高達21μm 的厚黃金電極。
    最後完成全長為3.4cm,直波導在TM 模態下的傳播損耗為
    0.8735dB/cm,而馬氏干涉儀於TM 模態下的傳播損耗為0.9911 dB/cm,厚
    金屬電極之特性,在網路分析儀的量測下其電傳輸訊號頻寬(S21)達
    21.3GHz、電傳輸反射訊號(S11)皆低於-15dB,光電轉換訊號於眼圖儀的量測
    下具有3Gbps 之頻寬響應,而其驅動電壓經量測為6V。;Today the era of the information explosion are rapid development, data
    transportation increasingly more large, and because the development of network
    of information exchanging between countries are more important, a large
    number of undersea fiber transportation system have been built, and lithium
    niobate with its excellent optical properties, and compared with telecom
    transmission, it’s more difficult to stolen and tampered, with the low driving
    energy required it’s in line with the policy of world energy trends and applies in
    many regions. With the advent of optical communication era, none of countries
    not to attach this regions.
    Ultra‐fast electro‐optical modulator for optical communication industry is an
    essential element, which is made by the advantages of titanium in:diffused
    process, with low propagation loss, high bit rate, highly application, low driving
    energy, and low signal to noise ratio, low ambient temperature affect being
    adopted in the relevant countries, like Americas, Europe, Japan, etc....... the
    island or cross‐border fiber‐optic network in submarine cables. And Taiwan has
    also carried out related research and development by way of industry‐university
    cooperation, achieved its related products can be developed independently,
    keeping up with the world countries, wish to complete a variety upgrading and
    development of related industries.
    In this thesis using the 1550nm light source to produce a ultra‐fast electrooptic
    modulator with 3Gbps bandwidth. We used a Z‐cut lithium niobate crystal,
    using its high electro‐optic coefficient, and in accordance with the principles of
    electro‐optic effect, Mach‐Zehnder interferometer waveguide is designed by
    using commercial software R‐Soft, the type of waveguide was produced with
    titanium in:diffused process, to design the waveguide width of 7μm, arm gap
    width of 60μm, S‐Bend length of 6000μm single‐mode transported in Mach‐
    Zehnder interferometer structure. Electrode design using a commercial software
    “High Frequency Structure Simulator, HFSS” and layout the coplanar waveguide
    electrode structure which suit on high‐frequency electrical signal transmission,
    driving electrode of modulator was made by gold achieved the bandwidth(S21)
    of electrical transmission to 40GHz or more, the reflection signal (S11) of
    electrical transmission and less than ‐18dB. We use silicon dioxide as
    conventional buffer layer on semiconductor industry with atomic vapor
    deposition equipment, in order to reach our velocity matching conditions and
    thickness of buffer layer is 1μm to suit the modulator design. And we try to reach
    a better velocity matching conditions, we must use thicker electrodes structure,
    so we developed the electroplating systems, using eco‐friendly gold plating
    solution as material, successfully fabricated thickness of electrode up to 21μm
    at ambient temperature at 35 ℃
    Finally we achieved the total length of 3.4cm, the propagation loss of
    straight waveguide under TM mode transmission is 0.8735dB / cm, while Mach‐
    Zehnder interferometer propagation loss is 0.9911 dB / cm under TM mode, we
    use Network Analyzer to measure the S‐parameter which bandwidth(S21) up to
    21.3GHz and reflection(S21) signal are lower than ‐15dB, and achieved the
    frequency response of 3Gbps bandwidth under driving voltage is 6V with the Eye‐
    Diagram.
    显示于类别:[光電科學研究所] 博碩士論文

    文件中的档案:

    档案 描述 大小格式浏览次数
    index.html0KbHTML549检视/开启


    在NCUIR中所有的数据项都受到原著作权保护.

    社群 sharing

    ::: Copyright National Central University. | 國立中央大學圖書館版權所有 | 收藏本站 | 設為首頁 | 最佳瀏覽畫面: 1024*768 | 建站日期:8-24-2009 :::
    DSpace Software Copyright © 2002-2004  MIT &  Hewlett-Packard  /   Enhanced by   NTU Library IR team Copyright ©   - 隱私權政策聲明