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INTRO TO COURSE AND ARCHITECTURE MODELS Data Communications.

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Presentation on theme: "INTRO TO COURSE AND ARCHITECTURE MODELS Data Communications."— Presentation transcript:

1 INTRO TO COURSE AND ARCHITECTURE MODELS Data Communications

2 Intro to TDC 460 Masters degree is now called Network Engineering and Management Prereqs: Java, TDC 311 or CSC 373, TDC 261, TDC 363 Foundation: TDC 460 (updated), TDC 463, TDC 464 (updated) Advanced: TDC 477 (security), TDC 511 (practicum), TDC 560, TDC 563 Electives: 5 courses Capstone: TDC 594 2

3 System Architectures We have already been introduced to the various types of communications systems  Telephone  Internet  Television  Cable TV and modems  LANs (wired and wireless)  Wireless WAN 3

4 System Architectures Let’s look at these system architectures in more detail What are the models that support each architecture? What type of code conversions must be performed? What protocols support these models? Where is the convergence? 4

5 What is a Protocol? For two entities to communicate successfully, they must “speak the same language”. What is communicated, how it is communicated, and when it is communicated must conform to some mutually acceptable conventions. These conventions are referred to as a protocol. 5

6 Key Elements of a Protocol Syntax  Data formats  Signal levels Semantics  Control information for coordination  Error handling Timing  Speed matching (between sender and receiver)  Sequencing (the right commands in the right order – closely related to semantics) 6

7 Network Architecture The task of communication is broken up into modules For example, a file transfer could use many modules:  The file transfer interface that the user runs (FTP)  The module that makes sure the file arrives at the destination exactly the same as when it left the source  The module that gets the packets from one router to another  The module that get each packet from the user’s computer to the network  The module that converts 1s and 0s to voltages 7

8 TCP/IP Protocol Suite Dominant commercial protocol architecture Specified and extensively used before OSI Developed by research funded by U.S. Department of Defense Used by the Internet 8

9 TCP/IP Suite Architecture No official model, but a working one.  Application layer  Host to host or transport layer  Internet layer  Network access layer  Physical layer 9

10 TCP/IP Physical Layer Physical interface between data transmission device (e.g. computer) and transmission medium or network Characteristics of transmission medium Signal levels Data rates etc. 10

11 TCP/IP Network Access Layer Exchange of data between end system and network Frame created Destination address provided Error checking code provided Possible services like priority invoked 11

12 TCP/IP Internet Layer (IP) Systems may be attached to different networks Routing functions across multiple networks Implemented in end systems and routers 12

13 TCP/IP Transport Layer (TCP) Reliable delivery of data (error-free) Ordering of delivery Implemented in end systems only (not implemented in routers) 13

14 TCP/IP Application Layer Support for user applications e.g. HTTP, SMTP, FTP, SNMP 14

15 OSI Model Open Systems Interconnection Developed by the International Organization for Standardization (ISO) Seven layers A theoretical system delivered too late! TCP/IP is the de facto standard 15

16 OSI - The Model A layer model Each layer performs a subset of the required communication functions Each layer relies on the next lower layer to perform more primitive functions Each layer provides services to the next higher layer Changes in one layer should not require changes in other layers 16

17 OSI as Framework for Standardization 17

18 OSI Layers Application Presentation Session Transport Network Data Link Physical What is the function of each OSI layer? 18

19 The OSI Environment 19

20 Figure 2.16 TCP/IP and OSI model 20

21 Questions What TCP/IP layer handles addressing? What OSI layer handles voltage conversions? What TCP/IP layer handles email? What OSI layer handles routing? What TCP/IP layer handles end-to-end connections? What OSI layer handles session connections? What TCP/IP layer handles synchronization? 21

22 SNA IBM’s Systems Network Architecture Created in the 1970s Being replaced with TCP/IP but still out there a little bit Seven layers which map fairly closely to OSI Good website: http://www.cisco.com/univercd/home/home.ht m 22

23 Novell Novell NetWare’s architecture used to rely heavily on IPX and SPX protocols Starting with NetWare version 5, IP became the default protocol replacing IPX NetWare protocol suite maps to the following OSI layers: 23

24 24

25 Telephony Architecture Subscribers Lines Central offices Trunks LATAs SS7 Switching centers 25

26 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 26

27 Standards Organizations Internet Society ISO ITU-T (formally CCITT) IEEE ANSI 27

28 Functions of Standards 1. Encapsulation 2. Segmentation and reassembly 3. Connection control 4. Ordered delivery 5. Flow control 6. Error control 7. Addressing 8. Multiplexing 9. Transmission services 28

29 Encapsulation Addition of control information to data  Address information  Error-detecting code  Protocol control 29

30 Segmentation (Fragmentation) Data blocks are of bounded size Application layer messages may be large Network packets may be smaller Splitting larger blocks into smaller ones is segmentation (or fragmentation in TCP/IP)  ATM blocks (cells) are 53 octets long  Ethernet blocks (frames) are up to 1526 octets long Checkpoints and restart/recovery 30

31 Why Fragment? Advantages  More efficient error control  More equitable access to network facilities  Shorter delays  Smaller buffers needed Disadvantages  Overheads  Increased interrupts at receiver  More processing time 31

32 Connection Control Connection Establishment Data transfer Connection termination May be connection interruption and recovery Sequence numbers used for  Ordered delivery  Flow control  Error control 32

33 Connection Oriented Data Transfer 33

34 Ordered Delivery Packets may traverse different paths through network Packets may arrive out of order Sequentially number packets to allow for ordering 34

35 Flow Control Done by receiving entity Limit amount or rate of data Stop and wait Credit systems  Sliding window Needed at application as well as network layers 35

36 Error Control Guard against loss or damage Error detection  Sender inserts error detecting bits  Receiver checks these bits  If OK, acknowledge  If error, discard packet Retransmission  If no acknowledge in given time, re-transmit Performed at various levels 36

37 Addressing Level Level in architecture at which entity is named Unique address for each end system (computer) and router Network level address  IP or internet address (TCP/IP)  Network service access point or NSAP (OSI) Process within the system  Port number (TCP/IP)  Service access point or SAP (OSI) 37

38 Figure 2.18 Relationship of layers and addresses in TCP/IP 38

39 Figure 2.19 Physical addresses 39

40 Figure 2.20 shows a part of an internet with two routers connecting three LANs. Each device (computer or router) has a pair of addresses (logical and physical) for each connection. In this case, each computer is connected to only one link and therefore has only one pair of addresses. Each router, however, is connected to three networks (only two are shown in the figure). So each router has three pairs of addresses, one for each connection. Example 2.3 40

41 Figure 2.20 IP addresses 41

42 Figure 2.21 shows two computers communicating via the Internet. The sending computer is running three processes at this time with port addresses a, b, and c. The receiving computer is running two processes at this time with port addresses j and k. Process a in the sending computer needs to communicate with process j in the receiving computer. Note that although physical addresses change from hop to hop, logical and port addresses remain the same from the source to destination. Example 2.4 42

43 Figure 2.21 Port addresses 43

44 Addressing Mode Usually an address refers to a single system  Unicast address  Sent to one machine or person May address all entities within a domain  Broadcast  Sent to all machines or users May address a subset of the entities in a domain  Multicast  Sent to some machines or a group of users 44

45 Multiplexing Supporting multiple connections on one machine Mapping of multiple connections at one level to a single connection at another  Carrying a number of connections on one fiber optic cable  Aggregating or bonding ISDN lines to gain bandwidth 45

46 Transmission Services Priority  e.g. control messages Quality of service  Minimum acceptable throughput  Maximum acceptable delay Security  Access restrictions 46

47 Review Questions What are the layers of the TCP/IP protocol suite? The OSI model? What is meant by encapsulation? Trace an FTP command as it moves down through the layers, across the medium, and up the layers on the receiving side. What are the functions of standards? 47


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