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Internet Protocol (IP)

Internet Protocol (IP). ITEC 370 George Vaughan Franklin University. Sources for Slides. Material in these slides comes primarily from course text, Guide to Networking Essentials,Tomsho, Tittel, Johnson (2007). Other sources are cited in line and listed in reference section.

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Internet Protocol (IP)

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  1. Internet Protocol (IP) ITEC 370 George Vaughan Franklin University

  2. Sources for Slides • Material in these slides comes primarily from course text, Guide to Networking Essentials,Tomsho, Tittel, Johnson (2007). • Other sources are cited in line and listed in reference section.

  3. TCP/IP and OSI Models

  4. Subnetting with Classless IP Addressing: Example 1

  5. Subnetting with Classless IP Addressing: Example 1 (Continued)

  6. Subnet 0 194.10.3.0 - 194.10.3.31 Subnet 1 194.10.3.32 - 194.10.3.63 Subnet 2 194.10.3.64 - 194.10.3.95 Subnet 3 194.10.3.96 - 194.10.3.127 Subnet 4 194.10.3.128 - 194.10.3.159 Subnet 5 194.10.3.160 - 194.10.3.191 Subnet 6 194.10.3.192 - 194.10.3.223 Subnet 7 194.10.3.224 - 194.10.3.255 Network Diagram of Subnets

  7. IP Packet Structure(IP Structure, n.d.)

  8. IP Packet Structure (Cont.) (IP Structure, n.d.) • Version (4 bits) • IP Version (e,g, IPv4) • IHL (4 bits) • Internet header length in 32 bit words • Minimum length is 5 (32 bit words) • Type of Service (8 bits) • A set of values used to specify desired Quality of Service (QoS). • Total Length (16 bits) • Length of datagram in octets, including header (max 65, 535)

  9. IP Packet Structure (Cont.) (IP Structure, n.d.) • Identification (16 bits) • A unique value for sender, receiver to aid in assembling fragments of a datagram • Flags (3 bits) • Fragmentation control flags • Fragment Offset (13 bits) • Fragment position in datagram • Time to Live (8 bits) • Time to live in seconds • Each hop decrements this field be at least 1 (even if less than a second per hop) • Prevents packets from floating around forever in a misconfigured network.

  10. IP Packet Structure (Cont.) (IP Structure, n.d.) • Protocol (8 bits) • The upper layer protocol that generated this datagram • Examples: ICMP, TCP, UDP, GRE, etc. • Header Checksum (16 bits) • Used to detect errors in IP header only • Since ‘Time to Die’ changes at each hop, checksum is also recomputed at each hop. • Source IP Address (32 bits) • Destination IP Address (32 bits) • Options (Variable in bit size) • Padding (Variable in bit size) • Enough bits to round out the last word to 32 bits.

  11. Internet Protocol (IP) • Network Layer • Supports packet data communication across an internetwork. • Source and Destination logical addressing, routing • IP addresses (not layer 2 MAC addressing) • Connectionless • No circuit setup before use • Fast but not reliable • Best effort delivery

  12. Internet Control Message Protocol (ICMP) • Network Layer • Used to send error and control messages • Used by ‘Ping’ utility • Used when ‘Time to Live’ (TTL) value reaches zero • An ICMP message is sent back to the source

  13. Address Resolution Protocol (ARP) • Network Layer • Used to resolve logical (IP) address to physical (MAC) address • Can only be used for two systems in same network (subnet).

  14. ARP Example • Device A needs to send a message to Device B • Before device A can send message, it needs the following addresses for device B: • IP (logical address) • MAC (physical address) • Device A sends out ARP broadcast message to all devices in same network as Device A. • Device B recognizes IP address in ARP and sends back MAC address to Device A • Device A now has 2 addresses necessary for send message to device B.

  15. Transmission Control Protocol (TCP) • Transport Layer • Accepts messages of any length from upper layers • Connection-Oriented • Uses 3-way handshake to establish connection • A sends ‘Synchronize’ (SYN) message to B • B sends ‘Synchronize Acknowledgement’ (SYN-ACK) message back to A • A sends a ‘Forward Acknowledgment’ (ACK) to B • Connection between A and B is now established. • TCP is responsible for fragmenting application into segments • TCP is responsible for reassembling the application data from segments. • TCP uses Acknowledgment messages to: • Ensure that data is properly received. • Manage flow control

  16. User Datagram Protocol (UDP) • Transport Layer • Connectionless • Similar to IP, but operates at Transport Layer, therefore, directly accessible to applications • Faster, but less reliable than TCP • UDP itself does not segment application data • UDP does not use acknowledgements • UDP is used by some higher layer protocols such as NFS and DNS.

  17. Domain Name System (DNS) • Application Layer • Domain Name-to- IP Address resolution system • Used for translating domain name based URLs and email addresses into IP addresses • einstein.franklin.edu  65.24.7.3 (try ‘nslookup einstein.franklin.edu’) • Once a name has been resolved, it is often cached to limit traffic on Domain Name Servers • Cache has figured value for ‘Time To Live’. • When an IP to Domain Name mapping is changed, it may take on the order of hours for caches to catch up

  18. Hypertext Transport Protocol (HTTP) • Application Layer • Web-pages, browsers, servers • Runs on top of TCP

  19. File Transfer Protocol (FTP) • Application Layer • Runs on top of TCP • Used to send and/or manipulate text and binary files from one computer to another. • Example FTP Application: WinSCP

  20. Telnet Protocol • Application Layer • Runs on top of TCP • Used to establish a remote, text-based session from one computer to another • Example Telnet application: PuTTY.

  21. Simple Mail Transport Protocol (SMTP) • Application Layer • Runs on top of TCP • De facto standard protocol for email programs.

  22. Dynamic Host Configuration Protocol (DHCP) • Application Layer • UDP Based • Allows a device to obtain a temporary IP address from a DHCP server. • Server must be configured with a block of IP available IP addresses. • In addition to providing a temporary IP address, DHCP can also provide the following information: • Default Gateway • Subnet Mask • Broadcast based protocol sent during boot: • Client leases the address the server assigns to it • If no answer is received, in an APIPA-enabled OS, the computer assigns itself an address (169.254.x.x)

  23. Network Address Translation (NAT) • Allows a company to use private IP addresses within the company. • Router maps private IP addresses to a smaller pool of public IP addresses. • Home routers use this technique for private IP addresses such as 192.168.1.x • Also provides security since devices outside of private network can’t see private IP addresses. • NAT has greatly extended the life of IPv4 • IPv4 supports less than 4 billion IP addresses • NAT uses these IP addresses very efficiently.

  24. Port Address Translation (PAT) • PAT extends the efficiency of NAT • PAT maps private IP address, port combination to public IP address, public port. • Example: • 192.168.1.3, port 5005 -> 201.35.2.33 port 80 • 192.168.1.4, port 5006 -> 201.35.2.33 port 23 • PAT can allow thousands of workstations to reuse the same IP address. • Ports 1024 through 65535 can be used by router for remapping

  25. IP Addressing Tools • Looking up an IP address: • http://psacake.com/web/eg.asp • Subnetting: • http://ccna.exampointers.com/subnet.phtml

  26. IPv6 Address Scheme • Hexidecimal grouped in 16 bit sections: • 2001:1b20:302:442a:110:2fea:ac4:2b • Leading zeroes are eliminated • 2 or more 16 bit fields of all zeros can be ignored, as long as there is only one double colon in the address: • 2001:260:0:0:0:2ed3:340:ab (long form) • 2001:260::2ed3:340:ab (short form) • IPv6 has 3 parts:

  27. References Tomsho, Tittel, Johnson (2007). Guide to Networking Essentials. Boston: Thompson Course Technology. Odom, Knott (2006). Networking Basics: CCNA 1 Companion Guide. Indianapolis: Cisco Press Wikipedia (n.d.). OSI Model. Retrieved 09/12/2006 from http://en.wikipedia.org/wiki/OSI_Model IP Structure (n.d.). IP Packet Structure. Retrieved 03/04/07 from http://www.freesoft.org/CIE/Course/Section3/7.htm

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