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CMPE 150 – Winter 2009 Lecture 3 January 13, 2009 P.E. Mantey
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CMPE 150 -- Introduction to Computer Networks Instructor: Patrick Mantey mantey@soe.ucsc.edu http://www.soe.ucsc.edu/~mantey/ mantey@soe.ucsc.edu Office: Engr. 2 Room 595J Office hours: Tuesday 3-5 PM TA: Anselm Kia akia@soe.ucsc.edu Web site: http://www.soe.ucsc.edu/classes/cmpe150/Winter09/ Text: Tannenbaum: Computer Networks (4 th edition – available in bookstore, etc. )
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Syllabus
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Today’s Agenda Standards Layered Network Architecture - review Networks and History Physical Layer Signals and Systems Fourier Analysis Communication Theory
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Standards Required to allow for interoperability between equipment Advantages Ensures a large market for equipment and software Allows products from different vendors to communicate Disadvantages Freeze technology May be multiple standards for the same thing
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Standards Organizations IEEE ANSI Internet Society ISO ITU-T (formally CCITT) ATM forum
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Network Standardization Who’s Who in the Telecommunications World Who’s Who in the International Standards World Who’s Who in the Internet Standards World
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ITU Main sectors Radiocommunications Telecommunications Standardization Development Classes of Members National governments Sector members Associate members Regulatory agencies
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IEEE 802 Standards The 802 working groups. The important ones are marked with *. The ones marked with are hibernating. The one marked with † gave up.
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Metric Units The principal metric prefixes.
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Reference Models The TCP/IP reference model.
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Reference Models Protocols and networks in the TCP/IP model initially.
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Comparing OSI and TCP/IP Models Concepts central to the OSI model Services Interfaces Protocols
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A Critique of the OSI Model and Protocols Why OSI did not take over the world Bad timing Bad technology Bad implementations Bad politics
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Bad Timing “The apocalypse of the two elephants.”
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A Critique of the TCP/IP Reference Model Problems: Service, interface, and protocol not distinguished Not a general model Host-to-network “layer” not really a layer No mention of physical and data link layers Minor protocols deeply entrenched, hard to replace
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Hybrid Model The hybrid reference model used by Tannenbaum
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Internet Layering Level 5 -- Application Layer (rlogin, ftp, SMTP, POP3, IMAP, HTTP..) Level 4-- Transport Layer(a.k.a Host-to-Host) (TCP, UDP, ARP, ICMP, etc.) Level 3-- Network Layer (a.k.a. Internet) (IP) Level 2-- (Data) Link Layer / MAC sub-layer (a.k.a. Network Interface or Network Access Layer) Level 1-- Physical Layer
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Example Networks The Internet Connection-Oriented Networks: X.25, Frame Relay, and ATM Ethernet Wireless LANs: 802:11
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Architecture of the Internet
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TCP/IP Reference Model Protocols and networks in the TCP/IP model initially.
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Characteristics Internet Layer Connectionless Internet Protocol (IP) Task is to deliver packets to destination Transport Layer Transmission Control Protocol (TCP) Connection-oriented Reliable User Datagram Protocol (UDP) Connectionless Unreliable
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TELCO Networks Connection-Oriented Networks X.25 Frame Relay ATM Fixed Route (set up at start of call) Quality of Service Billing – for connection time
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T’s and D’s http://www.netstreamsol.com.au/networking/notes/general/t1_e1_t3_e3_ds0_ds1_ds3.html
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T1 Time-division multiplexed stream of 24 telephone channels The basic technology upon which all T-carrier facilities are based Uses a full-duplex digital signal over two wire pairs. Bandwidth of 1.544 Mbps through telephone- switching network Uses AMI or B8ZS coding.
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O’s
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SONET Synchronous Optical NETwork Synchronous Digital Hierarchy (SDH) Europe Internet for CARRIERS Worldwide standard Multiplex multiple digital channels Management support for –Operations –Administration –Maintenance
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X.25 and Frame Relay X.25 -- First Public Data Network – 1970s –Call and connect “Data Terminal Equipment” –Simple packet structure –Implemented “virtual circuit” connections –Flow control, hop-by-hop error control –Multiplexing – up to 4095 circuits at a time Frame Relay – 1980s (up to 2Mbps) –Limited error control, flow control –VC based packet switching --“wide area LAN”
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Asynchronous Transfer Mode Vintage mid -1980s Goal to unify voice networks and data networks Packet Switching with virtual circuits (“channels”) Fixed-length packets (“cells”) - @ 53 bytes –5 byte header, 48 byte “payload” –Virtual channel header (VCI) –No retransmission link-by-link Error correction codes only Envisioned to reach the end user Used widely today for backbones
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ATM Virtual Circuits A virtual circuit.
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ATM Virtual Circuits (2) An ATM cell.
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The ATM Reference Model The ATM reference model.
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The ATM Reference Model (2) The ATM layers and sublayers and their functions
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Ethernet Architecture of the original Ethernet.
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Wireless LANs (a) Wireless networking with a base station. (b) Ad hoc networking.
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Wireless LANs (2) The range of a single radio may not cover the entire system.
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Wireless LANs (3) A multicell 802.11 network.
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The ARPANET (a) Structure of the telephone system. (b) Baran’s proposed distributed switching system.
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The ARPANET (2) The original ARPANET design. IMP = Interface Message Processor (Honeywell DDP-316)
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The ARPANET (3) Growth of the ARPANET (a) December 1969. (b) July 1970.(c) March 1971. (d) April 1972. (e) September 1972.
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NSFNET The NSFNET backbone in 1988.
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http://www.internet2.edu/pubs/networkmap.pdf
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http://www.nlr.net/services/map/
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http://doc.cenic.org/tools/topology_map.pl?network=uc UC CENIC January 2009
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SIGNALS and SYSTEMS
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What is a signal?
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SIGNALS and SYSTEMS What is a signal? What is a system?
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SIGNALS and SYSTEMS What is a signal? What is a system?
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SIGNALS and SYSTEMS What is a signal? What is a system? Signal: time varying function produced by physical device (voltage, current, etc.)
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SIGNALS and SYSTEMS What is a signal? What is a system? Signal: time varying function produced by physical device (voltage, current, etc.) System: device or process (algorithm) having signals as input and output Input x(t) output y(t)
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SIGNALS and SYSTEMS
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ax(t) ay(t) a 1 x 1 (t) + a 2 x 2 (t) a 1 y 1 (t) + a 2 y 2 (t) Superposition
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SIGNALS and SYSTEMS Periodic signals -- f(t+T) = f(t) Period = T (seconds) Frequency = 1/ Period (“cycles” / sec. = Hertz (Hz)
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SIGNALS and SYSTEMS Periodic signals -- f(t+T) = f(t) Period = T (seconds) Frequency = 1/ Period (“cycles” / sec. = Hertz (Hz) Radian frequency: (radians/sec.)
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SIGNALS and SYSTEMS Reference: Signals, Systems and Tranforms Leland B. Jackson Addison Wesley
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SIGNALS and SYSTEMS
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100MHz square wave What bandwidth required for transmission?
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SIGNALS and SYSTEMS Periodic Signal --- Composed of sinusoids MATLAB Demo
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SIGNALS and SYSTEMS Periodic Signal --- Composed of sinusoids
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Fourier Series is the “fundamental frequency”
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Fourier Series Integration limits: when, then so we get:
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Fourier Series Euler:
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Fourier Series We can show ; recall that
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Phasors: Phasors
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References Stallings, W. Data and Computer Communications (7th edition), Prentice Hall 2004 chapter 1 Web site for Stallings book http://williamstallings.com/DCC/DCC7e.html Web sites for IETF, IEEE, ITU-T, ISO Internet Requests for Comment (RFCs) Usenet News groups comp.dcom.* comp.protocols.tcp-ip
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