動態波長分配技術在乙太被動光纖網路的應用

以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：122

、訪客IP：18.117.233.52

姓名

謝炳順(Bing-shun Shieh) 查詢紙本館藏

畢業系所

光電科學研究所碩士在職專班

論文名稱

動態波長分配技術在乙太被動光纖網路的應用
(Dynamic Wavelength Allocation Scheme for Applications of Ethernet Passive Optical Networks)

相關論文

★ 氮化鎵微光學元件之研究	★ 二維雙輸入雙輸出光子晶體分光器
★ 矽光波導元件光耗損研究	★ 矽晶片波導元件研究
★ 砷化鎵光子晶體共振腔研究	★ 應用奈米小球製作之波導模態共振器
★ 光子晶體異常折射之能流研究	★ 氮化鎵光子晶體共振腔
★ 分析BATC大視野多色巡天計畫中正常星系的質光比	★ 新型中空多模干涉分光器
★ 表面電漿對於半導體發光元件光萃取效率的影響之探討	★ 半導體光子晶體雷射之研究
★ 新型中空光波導研製與應用	★ 禁止頻帶材料的光學與聲波特性研究
★ 漸變式光子晶體透鏡研究	★ 光子晶體波導光束直進之研究

檔案

[Endnote RIS 格式]

[Bibtex 格式]

[相關文章]

[文章引用]

[完整記錄]

[館藏目錄]

[檢視]

[下載]

本電子論文使用權限為同意立即開放。
已達開放權限電子全文僅授權使用者為學術研究之目的，進行個人非營利性質之檢索、閱讀、列印。
請遵守中華民國著作權法之相關規定，切勿任意重製、散佈、改作、轉貼、播送，以免觸法。

摘要(中)

本論文提出一新穎的動態波長分配(DWA)機制，架構在乙太被動光纖網路系統，用以解決網路流量突增的問題，維持網路流量的穩定性。
乙太被動光纖網路近來被認為是接取網路最具有應用前景的技術，採用點對多點拓樸架構，動態波長分配提供頻寬分享且可跨越多重的被動光纖網路架構；由調變雷射、陣列波導、粗/細過濾器構成有彈性的光存取方式，可當TDM PON 與WDM PON的橋樑，此架構將廣泛為下一代光纖網路所採用。
本文架構由單模雷射、可調變波長雷射、陣列波導光柵、緩衝器等組成，經MATLAB模擬軟體計算出機率模型分佈，同時由模擬結果決定最佳的切換機制，此系統以模擬架設並實際經過校園網路實際測量，當網路負載增加到一定程度時，經由DWA機制的實施，所量測的網路反應時間或者是網路流量結果證實，本系統確實能夠達到疏解負載增加的問題，進而發揮機動性的網路流量支援設備功能，達到最經濟、最簡單的區域性網路架構。

摘要(英)

This work proposes the dynamic wavelength allocation mechanism to solve the problem of sudden traffic loading for the Ethernet passive optical networks(PON).
Ethernet PON has recently been considered as the most prospective application technology in access network. It is adopted the point-to-multi-point(P2MP) topology construction,Which can greatly reduce the amount of optical fiber and the disbursement.
Moreover the DWA mechanism provides the bandwidth sharing across multiple physical PONs. A flexible new optical access solution is reached by combing the tunable lasers, the arrayed waveguide gratings, and the coarse/fine filters. The excellent stability of the network can bridge the gap between conventional TDM PONs and WDM PONs, and the powerful architecture is a promising candidate of the optical access networks for the next generation.
This structure is composed of the single mode laser, the tunable laser, the array waveguide, and the buffer storage device. The probability model distribution is calculated by the MATLAB, and the mechanism of optimal separation is determined by the computer simulation. This system is tested through the measured reaction time or the flow capacity of network on campus network when the traffic load increases up to a loading level. It is shown that the DWA system, can effectively solve the problems when the load increases, Which is the most economical and simplest local network infrastructure for the PONs.

關鍵字(中)

★ 動態波長分配
★ 以太被動光纖網路
★ 可調變雷射
★ 點對多點拓樸架構，波長分配多工被動光纖網路
★ 陣列波導光柵

關鍵字(英)

★ TDM PON
★ WDM PON
★ EPON
★ DWA
★ P2MP

論文目次

中文摘要 .…………………………………………………………….…i
英文摘要 ..…………………………………………………………….. ii
目錄 ………………………………………………………………….…iv
圖表目錄 ………………………………………………………………. v
第一章緒論 ……..……………………………………………….….1
1-1 前言 ……………………………………………………...1
1-2 研究動機與目的 …………………………………………..4
1-3 論文架構……………………………………………………4
第二章被動式光纖網路…….……………………………......................5
2-1 被動式光纖網路(PON)發展現況…………….………….....5
2-2 PON技術發展之多元化….………………………………10
2-3 被動式光纖網路的未來遠景 ……………...…………….13
第三章 DWA PON系統設計 ………………………………………....14
3-1 DWA系統架構…………………………………………....14
3-2 DWA系統原理……………………………………………17
3-3 網路流量模型分析及模擬..………………………………23
第四章量測結果與討論 ……………………………….……………..26
4-1 學術網路量測……. ……………………………………...26
4-2 學術網路流量取樣工具與實測結果……. ………….…...31
4-3 網路流量模擬與實測結果分析…..………………….…...33
4-4 相關文獻比較……………………..………………….…...43
第五章結論與未來研究方向...………………………………….…….46
參考文獻....…………………..………………………………………….48

參考文獻

[1] Yu-Li Hsueh; et,al,” SUCCESS-DWA: a highly scalable and cost-effective optical access network” IEEE Optical communication,Volume 42,Issue 8, Page(s):S24 - S30, Aug. 2004
[2] C. R. Giles, et,al,”Access PON Using Downstream 1550-nm WDM Routing and Upstream 1300-nm SCMA Combing Through a Fiber-Grating Router”IEEE PHOTONICS TECHNOLOGY LETERS, VOL 8,NO 11,P.P.1549 - 1551,NOVEMBER 1996
[3] S. L. Woodward, Senior Member, IEEE, P. P. Iannone, Member, IEEE, K. C. Reichmann, Member, IEEE,and N. J. Frigo, Member, IEEE,”A Spectrally Sliced PON Employing Fabry–Perot Lasers” IEEE PHOTONICS TECHNOLOGY LETERS, VOL 10,NO 9,P.P.1337 – 1339,SEPTEMBER 1998
[4] Chang-Joon Chae, et,al,”A PON System Suitable for Internetworking Optical Network Units Using a Fiber Bragg Grating on the Feeder Fiber” IEEE PHOTONICS TECHNOLOGY LETTERS, VOL. 11, NO. 12,P.P.1686 – 1688, DECEMBER 1999
[5] Chang-Joon Chae, Member, IEEE, and Nam-Hyun Oh,”WDM/TDM PON System Employing a Wavelength-Selective Filter and a Continuous-Wave Shared Light Source”IEEE PHOTONICS TECHNOLOGY LETTERS, VOL. 10, NO. 9,P.P.1325 – 1327, SEPTEMBER 1998
[6] Soo-Jin Park, et,al, ”Fiber-to-the-Home Services Based on Wavelength-Division-Multiplexing Passive Optical Network” Journal of Lightwave Technology, Vol. 24, Issue 12, pp. 4568-4583 December 2006
[7] Giles, et,al, ”Single-Fiber Access PON using Downstream 1550 nm WDM Routing and Upstream 1300nm Power Combining through a Fiber-Grating Router”Optical Communication, 1996. ECOC '96. 22nd European Conference on Publication Date: 15-19 Sept. 1996, Volume: 3, On page(s): 27- 30
[8] U.Hilbk, et,al,”HIGH-CAPACITY UPGRADE OF A PON BY MEANS OF WAVELENGTH-ROUTERS AND WDM TECHNIQUES ” WDM Technology and Applications (Digest No. 1997/036), IEE Colloquium on page(s): 3/1-3/5, 6 Feb 1997
[9] J.B. Stark, et.al, ”Cascaded WDM Passive Optical Network With a Highly Shared Source ”Photonics Technology Letters,IEEE, Vol 9,issue 8 On page(s): 1170-1172, Aug.1997
[10] Westphal, et,al, ”AWG based WDM Upgrade of a PON ” Lasers and Electro-Optics Society Annual Meeting, 1996.LEOS 96.IEEE Vol 2,On page(s): 183-184, 18-21, Nov 1996
[11] B. Kuhlow, et,al, ”AWG-Based Device for a WDM Overlay PON in the 1.5-μm Band ” Photonics Technology Letters,IEEE, Volume: 11,Issue 2 On page(s): 218-220, Feb 1999
[12]G.Przyrembel,et,al,”Multichannel1.3μm/1.5μmAWGmultiplexer/demultiplexer for WDM-PONs ”Electronics Letters vol 34, February 1998
[13] Desai, B.N. et. al, ”An optical implementation of a packet-based(Ethernet) MAC in a WDM passive optical network overlay ” Optical Fiber Communication Conference and Exhibit,2001.OFC 2001, Vol 3, On page(s): WN5-1- WN5-3, 2001
[14] Lee, C.-H. et,al,” Fiber to the Home Using a PON Infrastructure” IEEE JNL, Volume 24, Page(s):4568 – 4583, Dec. 2006
[15] Yen, Wei; Tseng, Shih-Wei,” Delay Sensitive EPON Dynamic Bandwidth Allocation Mechanism” IEEE CNF, Volume 1, Page(s):1 – 4, Oct. 2006
[16] Lei Bin; Xue Chen; Rong Gao; Xiaguang Lu;” A Dynamic Bandwidth Allocation Scheme with Two Threshold Reporting and Strict Priority Scheduling for Milti-Service EPONs” IEEE CNF, Page(s):1 – 5, 25-27 Oct. 2006
[17] Yu-Li Hsueh, et,al,”A Highly Flexible and Efficient Passive Optical Network Employing Dynamic Wavelength Allocation” JOURNAL OF LIGHTWAVE TECHNOLOGY, VOL. 23, NO. 1,P.P.277 – 286, JANUARY 2005
[18] Kyeong Soo Kim, Advanced System Technology, STMicroelectronics, Stanford Networking Research Center, Packard Building, Room 073, Stanford, CA 94305, USA,”On The Evolution of PON-Based FTTH Solutions”Information Sciences 149,P.P. 21 – 30, 2003,Preprint submitted to Information Sciences, 31 May 2002
[19] Anestis Karasaridis and Dimitrios Hatzinakos Electrical 〝A NON-Gaussian SELF-SIMILAR PROCESS FOR BROADBAND HEAVY TRAFFIC MODELING〞University of Toronto , IEEE Volume 5 , 8-12 Nov. 1998 Page(s):2995 - 3000
[20] Jeong-Ju Yoo, et,al, ”A WDM-Ethernet hybrid passive optical network architecture” Volume: 3, On page(s): 4 pp. Publication Date: 20-22 Feb. 2006
[21] Richard Durrett , Probability：Theory and Examples 2nd, Cole publishing Company , 2004
[22] 鍾沛璟,美國光纖大夢—光纖到家,光連雙月刊第54期,2004年11月
[23] 郭巍劉冬孫署陳雪,面向FTTH的EPON系統應用與管理,通信世界,2005年8月31日
[24] 工研院作(譯)者范國寶,乙太被動式光纖網路—加速光纖到家發展,創新第132期,94年12月
[25] 賴映杰,光纖通訊元件與模組技術之最新發展趨勢,物理雙月刊二十三卷二期,2001年4月
[26] 國際編譯館,日本光纖到路發展值得關注,台灣通訊 No.134,2005年2月
[27] 李志祥曹世強林盈達,網路測試：標準、工具與測試中心,國立交通大學資訊科學系
[28] 吳明蔚林盈達,網路實驗工具, 國立交通大學資訊科學系
[29] 林盈達郭以謙姚長利陳育良吳政璟,骨幹路由交換器測試評比：功能、效能、符合性與互通性,工研院交大網路測試中心
[30] 林盈達林伯青林毓達溫碩彥歐陽銘康詹智為林權宏黃福祥,網路安全產品測試評比；功能與效能, 工研院交大網路測試中心

指導教授

陳啟昌、林炆標
(Chii-Chang Chen、Wen-Piao Lin)

審核日期

2008-1-15

推文