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1 Introduction EECS 864 Optical Communications Networks Spring 2005 Victor S. Frost Dan F. Servey Distinguished Professor Electrical Engineering and Computer Science University of Kansas 2335 Irving Hill Dr. Lawrence, Kansas 66045 Phone: (785) 864-4833 FAX:(785) 864-7789 e-mail: frost@eecs.ku.edu http://www.ittc.ku.edu/
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2 Introduction EECS 864: Course Information n Text: WDM Optical Networks ä Authors: C. S. R. Murthy and M. Gutusamy n Class Web Site: http://www.ittc.ku.edu/EECS/EECS_864/ ä notes & useful links
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3 Introduction EECS 864: Course Information n Professor: Victor Frost ä e-mail: frost@eecs.ku.edu ä Home: Phone 841-3244 ä Nichols Hall: 864 4833 n Office hours: ä In 3016 Eaton Learned – 8:00 – 9:15 M & W ä All other times in Nichols Hall (room 208) ä Call or e-mail to insure that I am available before coming over the Nichols Hall
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4 Introduction EECS 864: Course Information n Student lecture on one (or more) topic(s) n Major semester team design project n Homework: problems will be assigned n One Tests
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5 Introduction EECS 864: Grading n Test = 100 points/test n Student lecture(s)= 125 points n Homework = 25 points n Semester Project = 200 points n Class participation= 50 points n Total = 500 points *Subject to modification
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6 Introduction EECS 864 Homework Rules n All work containing more than one page must be stapled - no paper clips and no folded corners. In order to facilitate grading of homework problems, homework shall meet the following specifications: 1. Written (single-sided) on 8.5"x11" paper. 2. For text and equations, typewriten or use an HB or No. 2 pencil (or darker), or blue or black ink. (Pencil is preferred.) No other colors please, except in diagrams or graphs. 3. All pages should be numbered i/j in top right hand corner, with your name appearing at the top of each page. It is O.K. to use your initials after the first page. 4. All work must be shown for full grade - be as thorough as possible. 5. Writing should be legible and literate - if the grader cannot read your handwriting,you will receive no credit for the problem.
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7 Introduction EECS 864 Homework Fromat 6. Answers are to be boxed and right justified, with the variables, values (if any) and units (if any), included in the box. Right justified means placed on the right side of the page. 7. Leave half an inch between consecutive parts of a question, and draw a line across the page at the end of each complete question. 8. No part of a question should appear in any margin of the paper. 9. Diagrams and graphs should be of a good size (say at least 3x5 sq. inch), and may contain colors. Diagrams and graphs must be titled, labeled, and clearly drawn. Tables should also be titled. 10. Graphs should be scaled (put number on axes), labeled (put names /units on axes), and titled at the bottom of the graph. Any graph which occupies an area of less than 3x5 sq. inch and which is not titled will not be graded. 11. Where possible use conventional units such as bits/sec, Hz and km
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8 Introduction
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9 EECS 864: Grading n Initial grading scale: ä 90 - 100 A ä 80 - 89 B ä 70 - 79 C ä 60 - 69 D
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10 Introduction EECS 864: Grading n Only under VERY extreme conditions will make up tests be given. n I MUST be notified BEFORE you miss a test otherwise you WILL get a 0. n No late homework will be accepted.
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11 Introduction Some Student Lecture Topics n Algorithms for optical network restoration(Chapter 7) n Algorithms for wavelength rerouting (Chapter 4) n Routing in wavelength conversion networks ( Section 3.4) n Performance of wavelength conversion networks (Section 3.5) n Sparse wavelength conversion networks (Section 3.6) n Placement of wavelength converters (Section 3.7) n Ethernet Passive Optical Networks (PONs) n Traffic Scheduling algorithms for PONs n Restoration in GMPLS n P-cycles for network protection n Algorithms for Traffic Grooming in Optical Networks
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12 Introduction Student Lectures n To be done in power point n To include specific examples to illustrate the concepts. n No overview only lectures, must include examples, must go beyond just summarizing a paper/algorithm. n Goal is to educate the class about the topic. n Each student will provide the class with references to their lecture material.
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13 Introduction Semester team design projects n Design of a Kansas IP/WDM Network ä You will be provided with fiber map ä General location of end points n Examples ä National Light Rail ä CalREN Optical –See www.internet2.edu/presentations/fall02/20021027-HENP-Reese.ppt ä I-Wire –See www.iwire.org
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14 Introduction National Light Rail n Dark Fiber National footprint n Serves very high-end Experimental and Research Applications n 4 - 10GB Wavelengths initially n Capable of 40 10Gb wavelengths http://www.internet2.edu/presentations/fall02/20021027-HENP-Reese.ppt
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NLR Footprint and Layer 1 Topology 15808 Terminal, Regen or OADM site (OpAmp sites not shown) Fiber route PIT POR FRE RAL WAL NAS PHO OLG ATL CHI CLE KAN OGD SAC BOS NYC WDC STR DAL DEN LAX SVL SEA SDG JAC http://www.internet2.edu/presentations/fall02/20021027-HENP-Reese.ppt
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Seattle Denver San Diego Sunnyvale Los Angeles Cleveland Pittsburgh New York City Boston DallasRaleigh Washington DC 10 Gig E 2 4 4 4 4 4 4 4 4 5 2 6 4 4 4 4 National Light Rail Lambda & Route Map Walnut Olga Stratford KansasOgden Sacramento Portland Pheonix Nashville 15808 LH System 15808 ELH System REGEN OADM 2 TERMINAL 4 4 2 Fresno 2 4 4 Salt Lake City 2 StarLight 6 Metro 10 Gig E OC192 15540 Metro System Chicago Atlanta Boise 2 http://www.internet2.edu/presentations/fall02/20021027-HENP-Reese.ppt
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17 Introduction NLR POP Architecture Long Haul OC48/OC192/10GigE DWDM Gig E 10 Gig E or OC192 NLR http://www.internet2.edu/presentations/fall02/20021027-HENP-Reese.ppt
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Calren/DC/HPR/NLR POP Architecture Long Haul OC48/OC192/10GigE DWDM Gig E 10 Gig E or OC192 CalRen DC HPR NLR Campus or Metro Interconnect 15500 CalREN/DC HPR NLR http://www.internet2.edu/presentations/fall02/20021027-HENP-Reese.ppt
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19 Introduction From: www.iwire.org
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20 Introduction From: www.iwire.org
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21 Introduction Hayes Salina Wichita
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22 Introduction Semester team design projects n Compare systems in terms of ä Power ä Space ä Capacity ä Cost ä Complexity
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23 Introduction Semester team design projects n Example: Juniper T640 (see www.juniper.net/products/dsheet/100051.html) n Capacity >.5 Tb/s n 770 Mpps n 1/2 rack n OC-12c/STM-4 to 10 Gbps n 6,500 watts
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24 Introduction Semester team design projects n Others? (Open to suggestions)
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25 Introduction Course Outline n Overview of Enabling Technologies- Physical Layer n Issues in WDM Networking n Optical Link Layer ä Gigbit and 10 Gigbit Ethernet ä Digital Wrapper ä Generic Framing Procedure
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26 Introduction Course Outline n Optical Control Plane ä Link Management Protocol (LMP) ä MPLS MP S ä GMLPS n Same basics of Graph Theory
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27 Introduction Course Outline n Some Basics of Mathematical Programming n Wavelength Routed Networks n IP over WDM n Network Survivability n Student Lectures
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28 Introduction Course Goals: Understand Concepts in Optical Networking n Transport- Framing n ON Control n ON facility management n ON topologies Leave the class with the tools to read and understand the literature on ONs.
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