Lecture 3 & 4 Networking Standards and the OSI Model

Network+ Guide to Networks 5th Edition Chapter 2 Networking Standards and the OSI Model Objectives Identify organizations that set standards for networking Describe the purpose of the OSI model and each of its layers Explain specific functions belonging to each OSI model layer 2 Objectives (cont’d.) Understand how two network nodes communicate through the OSI model Discuss the structure and purpose of data packets and frames Describe the two types of addressing covered by the OSI model 3 Networking Standards Organizations Standard – Documented agreement – Technical specifications/precise criteria – Stipulates design or performance of particular product or service Standards are essential in the networking world – Wide variety of hardware and software Ensures network design compatibility Standards define minimum acceptable performance – Not ideal performance 4 Networking Standards Organizations (cont’d.) Many different organizations oversee computer industry standards – Organizations may overlap responsibilities Example: ANSI and IEEE set wireless standards Network professional’s responsibility – Be familiar with groups setting networking standards – Understand critical aspects of standards required by own networks 5 ANSI ANSI (American National Standards Institute) – 1000+ representatives from industry and government – Determines standards for electronics industry and other fields Requests voluntarily compliance with standards Obtaining ANSI approval requires rigorous testing ANSI standards documents available online 6 EIA and TIA EIA (Electronic Industries Alliance) – Trade organization Representatives from United States electronics manufacturing firms – Sets standards for its members – Helps write ANSI standards – Lobbies for favorable computer and electronics industries legislation 7 EIA and TIA (cont’d.) TIA (Telecommunications Industry Association) – Formed in 1988 EIA subgroup merged with former United States Telecommunications Suppliers Association (USTSA) – Focus of TIA Standards for information technology, wireless, satellite, fiber optics, and telephone equipment TIA/EIA 568-B Series – Guidelines for installing network cable in commercial buildings 8 IEEE IEEE (Institute of Electrical and Electronics Engineers) – International engineering professionals society Goal of IEEE – Promote development and education in electrical engineering and computer science fields Hosts symposia, conferences, and chapter meetings Maintains a standards board IEEE technical papers and standards – Highly respected 9 IEEE Student Chapter at CCSF Last semester, the chapter arranged a tour of a data center I'll let you know what's coming up this semester 10 ISO ISO (International Organization for Standardization) – Headquartered in Geneva, Switzerland – Collection of standards organizations Representing 57 countries Goal of ISO – Establish international technological standards to facilitate global exchange of information and barrier free trade Widespread authority 11 ITU ITU (International Telecommunication Union) – Specialized United Nations agency – Regulates international telecommunications – Provides developing countries with technical expertise and equipment – Founded in 1865 Joined United Nations in 1947 – Members from 191 countries Focus of ITU – Global telecommunications issues – Worldwide Internet services implementation 12 ISOC ISOC (Internet Society) – Founded in 1992 – Professional membership society – Establishes technical Internet standards Current ISOC concerns – Rapid Internet growth – Keeping Internet accessible – Information security – Stable Internet addressing services – Open standards 13 ISOC (cont’d.) ISOC oversees groups with specific missions – IAB (Internet Architecture Board) Technical advisory group Overseeing Internet’s design and management – IETF (Internet Engineering Task Force) Sets Internet system communication standards Particularly protocol operation and interaction Anyone may submit standard proposal Elaborate review, testing, and approval processes 14 IANA and ICANN IP (Internet Protocol) address – Address identifying computers in TCP/IP based (Internet) networks – Reliance on centralized management authorities IP address management history – Initially: IANA (Internet Assigned Numbers Authority) – 1997: Three RIRs (Regional Internet Registries) ARIN (American Registry for Internet Numbers) APNIC (Asia Pacific Network Information Centre) RIPE (Réseaux IP Européens) 15 IANA and ICANN (cont’d.) IP address management history (cont’d.) – Late 1990s: ICANN (Internet Corporation for Assigned Names and Numbers) Private nonprofit corporation Remains responsible for IP addressing and domain name management IANA performs system administration Users and business obtain IP addresses from ISP (Internet service provider) 16 ICANN's Stormy History 2002: ICANN was sued by one of their own board members to force them to disclose financial documents 2003: ICANN sued Verisign to make them shut down their "Site Finder" service, which captured all mistyped URLs and showed them Verisign ads 2004 Verisign sued ICANN saying they had overstepped their authority 2008 Ten worst spam offenders notified by ICANN – Links Ch 2a, 2b, 2c 17 The OSI Model Model for understanding and developing network computer-to-computer communications Developed by ISO (1980s) Divides network communications into seven layers – Physical, Data Link, Network, Transport, Session, Presentation, Application 18 The OSI Model (cont’d.) Protocol interaction – Layer directly above and below Application layer protocols – Interact with software Physical layer protocols – Act on cables and connectors 19 The OSI Model (cont’d.) Theoretical representation describing network communication between two nodes Hardware and software independent Every network communication process represented PDUs (protocol data units) – Discrete amount of data – Application layer function – Flow through layers 6, 5, 4, 3, 2, and 1 Generalized model and sometime imperfect 20 Figure 2.1 Flow of data through the OSI model 21 Mnemonics for the OSI Model Bottom Up Top Down – Please – All – Do – People – Not – Seem – Throw – To – Sausage – Need – Pizza – Data – Away – Processing 22 Application Layer Top (seventh) OSI model layer No software applications Protocol functions – Facilitates communication Between software applications and lower-layer network services – Network interprets application request – Application interprets data sent from network 23 Presentation Layer Protocol functions – Accept Application layer data – Formats data to make it understandable to different applications and hosts Examples – Text encoding methods ASCII and ANSI – Compression methods like JPEG and MP3 – Data encryption and decryption 24 Session Layer Protocol functions – Coordinate and maintain communications between two nodes Session – Connection for ongoing data exchange between two parties Example: between Web browser client and Web server Functions – Establishing and keeping alive communications link For session duration – Determining if communications ended Determining where to restart transmission – Terminating communications 25 Transport Layer Protocol functions – Accept data from Session layer – Provides flow control, segmentation, and error control Primary Transport Layer Protocols: TCP and UDP Transmission control protocol (TCP) and user datagram protocol (UDP) 26 Transport Layer TCP Connection-oriented – Establishes a connection before transmitting data – Three-way handshake SYN SYN/ACK ACK 27 Transport Layer TCP – Require acknowledgements from receiver to ensure data was received correctly – Checksum Unique character string allowing receiving node to determine if arriving data unit exactly matches data unit sent by source Ensures data integrity Send data, wait for ACK ACK Send more data, wait for ACK 28 Transport Layer UDP: A connectionless protocol – Do not establish connection with another node before transmitting data—no handshake – Make no effort to ensure data is delivered free of errors – Faster than connection-oriented protocol – Useful when data must be transferred quickly, such as streaming music or video 29 Transport Layer Segmentation – Breaking large data units received from Session layer into multiple smaller units called segments – Increases data transmission efficiency MTU (maximum transmission unit) – Largest data unit network will carry – Ethernet default: 1500 bytes – Discovery routine used to determine MTU 30 Transport Layer (cont’d.) Reassembly – Process of reconstructing segmented data units Sequencing – Method of identifying segments belonging to the same group of subdivided data 31 Transport Layer (cont’d.) Figure 2-2 Segmentation and reassembly 32 Error in Textbook On page 50, the textbook says that the Network layer translates IP addresses like 147.144.51.121 into MAC addresses like 00-30-48-82-11-BD That is false. MAC addresses are used at layers 2 and 1 only. Layer 3 works with IP packets which have had the MAC addresses removed from them. 33 Network Layer Packet formation – Transport layer segment is encapsulated by a Network layer packet Network layer adds logical addressing information—IP address Routing – Determine path from point A on one network to point B on another network Routing considerations – Delivery priorities, network congestion, quality of service, cost of alternative routes 34 Network Layer Common Network layer protocol – IP (Internet Protocol) Fragmentation – Network layer protocol (IP) subdivides Transport layer segments received into smaller packets – This is usually avoided by adjusting the Maximum Segment Size in the Transport layer, because it makes data transfer inefficient Link Ch 2e 35 Data Link Layer Function of protocols – Divide data received into distinct frames for transmission in Physical layer – Add Physical address to the frame: MAC addresses like 00-30-48-82-11-BD Frame – Structured package for moving data Includes raw data (payload), sender’s and receiver’s physical addresses, error checking and control information 36 Data Link Layer (cont’d.) Frames may be damaged as they pass through the Physical layer, so the Data Link layer has error- checking – Error checking Frame check sequence CRC (cyclic redundancy check) Possible glut of communication requests – Data Link layer controls flow of information Allows NIC to process data without error 37 Data Link Layer (cont’d.) Two Data Link layer sublayers – LLC (Logical Link Control) sublayer – MAC (Media Access Control) sublayer MAC address components – Block ID Six-character sequence unique to each vendor – Device ID Six-character number added at vendor’s factory MAC addresses frequently depicted in hexadecimal format 38 Example of MAC Address Whole MAC address: 00-30-48-82-11-BD – Block ID 00-30-48 Identifies the vendor – Device ID 82-11-BD Different for each NIC from the same vendor If two NICs have the same MAC address, they have problems networking – This can happen with cheaply made refurbished NICs, or with copied virtual machines 39 Data Link Layer (cont’d.) Figure 2-5 The Data Link layer and its sublayers 40 Data Link Layer (cont’d.) Figure 2-6 A NIC’s Mac address 41 Finding Your MAC Address Start, CMD, Enter MAC Address (also IPCONFIG /ALL called "Physical Scroll up to see the first entry Address") IP Address 42 43 44 Physical Layer Functions of protocols – Accept frames from Data Link layer – Generate signals as changes in voltage at the NIC Copper transmission medium – Signals issued as voltage Fiber-optic cable transmission medium – Signals issued as light pulses Wireless transmission medium – Signals issued as electromagnetic waves 45 Physical Layer (cont’d.) Physical layer protocols responsibility when receiving data – Detect and accept signals – Pass on to Data Link layer – Set data transmission rate – Monitor data error rates – No error checking Devices operating at Physical layer – Hubs and repeaters NICs operate at both Physical layer and Data Link layers 46 Applying the OSI Model Table 2-1 Functions of the OSI layers 47 Communication Between Two Systems Data transformation – Original software application data differs from the bits sent onto the cable by the NIC Header data added at each layer Each layer has a different data structure, called a Protocol Data Unit (PDU) Segments – Generated in Transport layer – Unit of data resulting from subdividing larger PDU from the Session layer – Addressed with TCP Ports (when using TCP) 48 Communication Between Two Systems (cont’d.) Packets – Generated in Network layer – Data with logical addressing information added to segments – Addressed with IP addresses Frames – Generated in Data Link layer – Composed of several smaller components or fields – Addressed with MAC addresses 49 Communication Between Two Systems (cont’d.) Encapsulation – Occurs in each layer – Process of wrapping one layer’s PDU with protocol information Allows interpretation by lower layer 50 Communication Between Two Systems (cont’d.) Figure 2-7 Data transformation through the OSI model 51 Frame Specifications Frames – Composed of several smaller components or fields Frame characteristic dependencies – Network type where frames run – Standards frames must follow Ethernet – Developed by Xerox – Four different types of Ethernet frames – Most popular: IEEE 802.3 standard 52 Frame Specifications (cont’d.) Token ring – Developed by IBM – Relies upon direct links between nodes and ring topology – Nearly obsolete – Defined by IEEE 802.5 standard Ethernet frames and token ring frames differ – Will not interact with each other – Devices cannot support more than one frame type per physical interface or NIC 53 IEEE Networking Specifications IEEE’s Project 802 – Effort to standardize physical and logical network elements Frame types and addressing Connectivity Networking media Error-checking algorithms Encryption Emerging technologies 802.3: Ethernet 802.11: Wireless 54 IEEE Networking Specifications (cont’d.) Table 2-2 IEEE 802 standards 55

Lecture 3 & 4 Networking Standards and the OSI Model

Document Details

Tags

Related

Summary

Full Transcript