Wednesday, 29 June 2011

OSI Model Concepts

OSI Model Concepts:

The standard model for networking protocols and distributed applications is the International Standard Organization's Open System Interconnect (ISO/OSI) model. It defines seven network layers. 
Short for Open System Interconnection, an ISO standard for worldwide communications that defines a networking framework for implementing protocols in seven layers. Control is passed from one layer to the next, starting at the application layer in one station, proceeding to the bottom layer, over the channel to the next station and back up the hierarchy. 

At one time, most vendors agreed to support OSI in one form or another, but OSI was too loosely defined and proprietary standards were too entrenched. Except for the OSI-compliant X.400 and X.500 e-mail and directory standards, which are widely used, what was once thought to become the universal communications standard now serves as the teaching model for all other protocols.
Control is passed from one layer to the next, starting at the application layer in one station, proceeding to the bottom layer, over the channel to the next station and back up the hierarchy.

Understanding how the OSI Model works is not only useful for taking certification exams, but also for real life scenarios. Read How to use the OSI Model to Troubleshoot Networks for more info.


Layer 1 - Physical
Physical layer defines the cable or physical medium itself, e.g., thinnet, thicknet, unshielded twisted pairs (UTP). All media are functionally equivalent. The main difference is in convenience and cost of installation and maintenance. Converters from one media to another operate at this level. 

Layer 2 - Data Link
Data Link layer defines the format of data on the network. A network data frame, aka packet, includes checksum, source and destination address, and data. The largest packet that can be sent through a data link layer defines the Maximum Transmission Unit (MTU). The data link layer handles the physical and logical connections to the packet's destination, using a network interface. A host connected to an Ethernet would have an Ethernet interface to handle connections to the outside world, and a loopback interface to send packets to itself.
Ethernet addresses a host using a unique, 48-bit address called its Ethernet address or Media Access Control (MAC) address. MAC addresses are usually represented as six colon-separated pairs of hex digits, e.g., 8:0:20:11:ac:85. This number is unique and is associated with a particular Ethernet device. Hosts with multiple network interfaces should use the same MAC address on each. The data link layer's protocol-specific header specifies the MAC address of the packet's source and destination. When a packet is sent to all hosts (broadcast), a special MAC address (ff:ff:ff:ff:ff:ff) is used. 

Layer 3 - Network
NFS uses Internetwork Protocol (IP) as its network layer interface. IP is responsible for routing, directing datagrams from one network to another. The network layer may have to break large datagrams, larger than MTU, into smaller packets and host receiving the packet will have to reassemble the fragmented datagram. The Internetwork Protocol identifies each host with a 32-bit IP address. IP addresses are written as four dot-separated decimal numbers between 0 and 255, e.g., 129.79.16.40. The leading 1-3 bytes of the IP identify the network and the remaining bytes identifies the host on that network. The network portion of the IP is assigned by InterNIC Registration Services, under the contract to the National Science Foundation, and the host portion of the IP is assigned by the local network administrators. For large sites, the first two bytes represents the network portion of the IP, and the third and fourth bytes identify the subnet and host respectively.
Even though IP packets are addressed using IP addresses, hardware addresses must be used to actually transport data from one host to another. The Address Resolution Protocol (ARP) is used to map the IP address to it hardware address. 

Layer 4 - Transport
Transport layer subdivides user-buffer into network-buffer sized datagrams and enforces desired transmission control. Two transport protocols, Transmission Control Protocol (TCP) and User Datagram Protocol (UDP), sits at the transport layer. Reliability and speed are the primary difference between these two protocols. TCP establishes connections between two hosts on the network through 'sockets' which are determined by the IP address and port number. TCP keeps track of the packet delivery order and the packets that must be resent. Maintaining this information for each connection makes TCP a stateful protocol. UDP on the other hand provides a low overhead transmission service, but with less error checking. NFS is built on top of UDP because of its speed and statelessness. Statelessness simplifies the crash recovery. 

Layer 5 - Session
The session protocol defines the format of the data sent over the connections. The NFS uses the Remote Procedure Call (RPC) for its session protocol. RPC may be built on either TCP or UDP. Login sessions uses TCP whereas NFS and broadcast use UDP. 

Layer 6 - Presentation
External Data Representation (XDR) sits at the presentation level. It converts local representation of data to its canonical form and vice versa. The canonical uses a standard byte ordering and structure packing convention, independent of the host. 

Layer 7 - Application
Provides network services to the end-users. Mail, ftp, telnet, DNS, NIS, NFS are examples of network applications. 

OSI Model Reference Table
Layer
Function
Protocols
Network Components
Application
User Interface
  • Used for applications specifically written to run over the network
  • Allows access to network services that support applications;
  • Directly represents the services that directly support user applications
  • Handles network access, flow control and error recovery
  • Example apps are file transfer,e-mail, NetBIOS-based  applications           
DNS; FTP; TFTP; BOOTP; SNMP;RLOGIN; SMTP; MIME; NFS; FINGER; TELNET; NCP; APPC; AFP; SMB
Gateway
Presentation

Translation
  • Translates from application to network format and vice-versa
  • All different formats from all sources are made into a common uniform format that the rest of the OSI model can understand
  • Responsible for protocol conversion, character conversion,data encryption / decryption, expanding graphics commands, data compression
  • Sets standards for different systems to provide seamless communication from multiple protocol stacks
  • Not always implemented in a network protocol

Gateway
Redirector
Session
Syncs and Sessions
  • Establishes, maintains and ends sessions across the network
  • Responsible for name recognition (identification) so only the designated parties can participate in the session
  • Provides synchronization services by planning check points in the data stream => if session fails, only data after the most recent checkpoint need be transmitted
  • Manages who can transmit data at a certain time and for how long
  • Examples are interactive login and file transfer connections, the session would connect and re-connect if there was an interruption; recognize names in sessions and register names in history
NetBIOS
Names Pipes
Mail Slots
RPC
Gateway
Transport
Packets; Flow control & Error-handling
  • Additional connection below the session layer
  • Manages the flow control of data between parties across the network
  • Divides streams of data into chunks or packets; the transport layer of the receiving computer reassembles the message from packets
  • A train is a good analogy => the data is divided into identical units
  • Provides error-checking to guarantee error-free data delivery, with on losses or duplications
  • Provides acknowledgment of successful transmissions; requests retransmission if some packets don’t arrive error-free
  • Provides flow control and error-handling
TCP, ARP, RARP;
SPX
NWLink
NetBIOS / NetBEUI
ATP
Gateway
Advanced Cable Tester
Brouter
Network
Addressing; Routing
  • Translates logical network address and names to their physical address (e.g. computername ==> MAC address)
  • Responsible for
    • addressing
    • determining routes for sending
    • managing network problems such as packet switching, data congestion and routing
  • If router can’t send data frame as large as the source computer sends, the network layer compensates by breaking the data into smaller units. At the receiving end, the network layer reassembles the data
  • Think of this layer stamping the addresses on each train car
IP; ARP; RARP, ICMP; RIP; OSFP;
IGMP;
IPX
NWLink
NetBEUI
OSI
DDP
DECnet
Brouter
Router
Frame Relay Device
ATM Switch
Advanced Cable Tester
Data Link
Data frames to bits
  • Turns packets into raw bits 100101 and at the receiving end turns bits into packets.
  • Handles data frames between the Network and Physical layers
  • The receiving end packages raw data from the Physical layer into data frames for delivery to the Network layer
  • Responsible for error-free transfer of frames to other computer via the Physical Layer
  • This layer defines the methods used to transmit and receive data on the network. It consists of the wiring, the devices use to connect the NIC to the wiring, the signaling involved to transmit / receive data and the ability to detect signaling errors on the network media
Logical Link Control
  • error correction and flow control
  • manages link control and defines SAPs
802.1 OSI Model
802.2 Logical Link Control
Bridge
Switch
ISDN Router
Intelligent Hub
NIC
Advanced Cable Tester
Media Access Control
  • communicates with the adapter card
  • controls the type of media being used:
802.3 CSMA/CD (Ethernet)
802.4 Token Bus (ARCnet)
802.5 Token Ring
802.12 Demand Priority
Physical
Hardware; Raw bit stream
  • Transmits raw bit stream over physical cable
  • Defines cables, cards, and physical aspects
  • Defines NIC attachments to hardware, how cable is attached to NIC
  • Defines techniques to transfer bit stream to cable
IEEE 802
IEEE 802.2
ISO 2110
ISDN
Repeater
Multiplexer
Hubs
  • Passive
  • Active
TDR
Oscilloscope
Amplifi

Tuesday, 28 June 2011

TCP / IP Reference Page



Protocols according to layers:
 
Data Link Layer
Network Layer
Transport Layer
Session Layer
Application Layer
Routing
Tunneling
Security.

The Defense Advance Research Projects Agency (DARPA) originally developed Transmission Control Protocol/Internet Protocol (TCP/IP) to interconnect various defense department computer networks. The Internet, an international Wide Area Network, uses TCP/IP to connect government and educational institutions across the world. TCP/IP is also in widespread use on commercial and private networks. The TCP/IP suite includes the following protocols.


Data Link Layer
ARP/RARP
Address Resolution Protocol/Reverse Address
DCAP
Data Link Switching Client Access Protocol

Network Layer
DHCP
Dynamic Host Configuration Protocol
DVMRP
Distance Vector Multicast Routing Protocol
ICMP/ICMPv6
Internet Control Message Protocol
IGMP
Internet Group Management Protocol
IP
Internet Protocol version 4
IPv6
Internet Protocol version 6
MARS
Multicast Address Resolution Server
PIM
Protocol Independent Multicast-Sparse Mode (PIM-SM)
RIP2
Routing Information Protocol
RIPng for IPv6
Routing Information Protocol for IPv6
RSVP
Resource ReSerVation setup Protocol
VRRP
Virtual Router Redundancy Protocol

Transport Layer
ISTP

Mobile IP
Mobile IP Protocol
RUDP
Reliable UDP
TALI
Transport Adapter Layer Interface
TCP
Transmission Control Protocol
UDP
User Datagram Protocol
Van Jacobson
compressed TCP
XOT
X.25 over TCP

Session Layer
BGMP
Border Gateway Multicast Protocol
Diameter

DIS
Distributed Interactive Simulation
DNS
Domain Name Service
ISAKMP/IKE
Internet Security Association and Key Management Protocol and Internet Key Exchange Protocol
Small Computer Systems Interface
LDAP
Lightweight Directory Access Protocol
MZAP
Multicast-Scope Zone Announcement Protocol
NetBIOS/IP
NetBIOS/IP for TCP/IP Environment

Application Layer
COPS
Common Open Policy Service
FANP
Flow Attribute Notification Protocol
Finger
User Information Protocol
FTP
File Transfer Protocol
HTTP
Hypertext Transfer Protocol
IMAP4
Internet Message Access Protocol rev 4
Instant Messaging and Presence Protocols
IPDC
IP Device Control
IRC
·Internet Relay Chat Protocol
ISAKMP
Internet Message Access Protocol version 4rev1
ISP

NTP
Network Time Protocol
POP3
Post Office Protocol version 3
Radius
Remote Authentication Dial In User Service
RLOGIN
Remote Login
RTSP
Real-time Streaming Protocol
SCTP
Stream Control Transmision Protocol
S-HTTP
Secure Hypertext Transfer Protocol
SLP
Service Location Protocol
SMTP
Simple Mail Transfer Protocol
SNMP
Simple Network Management Protocol
SOCKS
Socket Secure (Server)
TACACS+
Terminal Access Controller Access Control System
TELNET
TCP/IP Terminal Emulation Protocol
TFTP
Trivial File Transfer Protocol
WCCP
Web Cache Coordination Protocol
X-Window
X Window

Routing
BGP-4
Border Gateway Protocol
EGP
Exterior Gateway Protocol
EIGRP
Enhanced Interior Gateway Routing Protocol
HSRP
Cisco Hot Standby Router Protocol
IGRP
Interior Gateway Routing
NARP
NBMA Address Resolution Protocol
NHRP
Next Hop Resolution Protocol
OSPF
Open Shortest Path First
TRIP
Telephony Routing over IP

Tunneling
ATMP
Ascend Tunnel Management Protocol
L2F
The Layer 2 Forwarding Protocol
L2TP
Layer 2 Tunneling Protocol
PPTP
Point to Point Tunneling Protocol

Security
AH
Authentication Header
ESP
Encapsulating Security Payload
TLS
Transport Layer Security Protocol