2. Goals Identify common media connectors
Identify common network components
Identify features of 802 project network standards (hardware protocols)
802.2 (LLC)
802.3 (CSMA/CD) *ethernet)
802.5 (token ring)
(wireless)
FIDDI

3. Terminology Common to all Networks
Clients – computer that requests resources from another computer
Server – computer on the network that manages shared resources
Workstation – desktop computer, most clients are workstations
Network interface card ( NIC) – device that connects a computer to the network media
Network operating system (NOS) – software that runs on a server to manage network functions
Host – computer that enables resource sharing
Node – client, server or device that can communicate over a network and is identified by a unique network address
Shared resource – data or hardware provided to the client by the server
Topology – physical or logical layout of a computer network
Connectivity device – special devices which allow 2 or more networks or network segments to communicate
Protocol – predetermined method or format for exchanging data between computers. Data packets – distinct units of data transmitted from one computer to another
Addressing – scheme for assigning unique identifier to each node
Transmission media – means of transmitting data, physical connection wired or wireless

4. Basic Network Hardware
Transceivers– a device that interfaces another device to a network, broadcasts and receives signals to and from the surrounding computers.
NIC card
Access point for wireless network
Repeaters – simplest connectivity device used to regenerate a signal
2 ports
Hubs – multi-port repeater. Concentrator
Common wiring point for networks based on a star topology.
Takes input through one port and redistributes through all other ports
Each hub is a separate collision domain
Connects 2 LAN segments of the same type to expand collision domains
Type of Hubs
Passive – no power required, passes signal does not regenerate signal
Active – regenerates and cleans signal , power required (repeater)

5. Network Hardware continued…
Switch – physically like a hub, but electronically more sophisticated.
Can determine proper port for packet destination using MAC address reducing network traffic.
Preserves bandwidth on the network using segmentation
Bridges- connects 2 network segments together, forwards frames based on the MAC address
Protocol independent
Extend collision domains
Segment networks using non-routing protocols
All broadcast data is passed

6. Network Hardware cont…
Router –
multi-port device that directs data between networks and nodes using logical addressing,
switches devices that connect to LANs where multiple paths exist, determining best path.
Used to interconnect LANs and WANs
Each port can be configured for a unique network address
Can connect different types of network architecture together
Brouter—
perform the function of bridge and router in one device
Can forward outside subnet
CSU/DSU – channel service unit/data service unit –
connects networks to a communications carrier
Gateway –
Enables communication between 2 completely different computing environments or architectures that do not use the same protocols

7. Basics Concepts of Networking: Media ( *chapter 3)
Media is the physical connection on which signals move from one device to another. (Including wireless media)
Media types are bounded or unbounded
Unbounded
Radio waves
Infrared Light pulses
Laser beams
Microwave
Bounded
Copper
Fiber optic

8. Topologies
Physical or logical layout of the network, (how the signal is carried)
4 major topologies
Bus
Star
Ring
Mesh
Most networks are hybrid of the basic topologies.
Institute of Electrical and Electronic Engineers (IEEE) defined the topologies in 1980 along with some hardware protocols.
Known as the 802 Project—(for Feb 1980)

9. Bus Networks
Bus – devices are connected on a common linear cable (coaxial cable)
Both ends of the network must be terminated
All computers listen to the cable – only one computer transmits at a time
Signal is seen by all, but processed only by the computer whose address matches the destination address in the packet
Factors affecting performance
Break in the cable or loss of termination will stop network traffic
More computers the longer the wait the slower the network
Simple to install, difficult to troubleshoot

10. Ring Network Connects computers on a single circle of cable
Foundation for token ring architecture and FIDDI
Logical rings interconnected by multi-station access units (MAU) devices
Can reconfigure the ring when a computer goes down
Similar to a hub, internal wiring is a ring with ring-in ring-out ports for extending ring

11. Star Network Most common network
Star network several computers or devices interconnect to one another over a hub
Modular, centralized administration, easy to troubleshoot
Complex cabling schemes– document!!!!

12. Hardware protocols
Hardware protocols define how the devices put data on and take data off the network cable
also called channel access method
Closely associated with topologies but not the same
Defined in the 802 Project standards (combination of the physical topologies and hardware protocols)
802.2
802.3 CSMA/CD
802.4
802.5 Token Passing
802.11
Demand Priority
Methods to access the wire
Contention or Probabilistic
CSMA/CD and CSMA/CA
Deterministic or Token Passing
Token Ring
FIDDI

13. CSMA/CD CSMA/CA IEEE 802.3 standard (often called Ethernet standard)
Defined specifications for moving data across twisted pair and coaxial cables and the terminators used
Star or Bus networks
Carrier sense multiple access collision detect
Each computer listens for traffic on the wire (carrier sense)
If a computer senses the cable is free it sends frame
Often referred to as a packet
All computers can see the signal (multiple access)
No other computer can send until the cable is free again
If a collision occurs the sending computers wait a random time and resend (collision detect)
Collision –frames collide with frames from another computer blending the signals making both frames useless

14. Packet
Packet- a unit of information transmitted as a whole for one device to another on a network. Large data is broken into manageable packets which are the basic unit of network data communication.
Data is broken into packets to:
Avoid flooding the cable speeding up transmissions
Lower the impact of retransmissions
Common packet components ( * common to all protocol packets) include:
Header
Alert signal and or clocking information
*source address
*destination address
*instructions for reassembling
Data
Varies from 512bytes to 4 KB depending on the network
Trailer
*Error checking
CRC (cyclical redundancy check—mathematical calculation performed on the packet at the source and again at the destination)

15. FIDDI Fiber Distributed Data Interface uses token passing protocol
Uses fiber optic media
CDDI uses copper media
Dual Ring topology
Secondary ring is backup only
Stations can be single or dual attached
A port attaches to primary ring
B port attaches to secondary ring
M port attaches single attached station to primary ring

16. Features of peer to peer network
No dedicated server
Share level security
no central administration
When to use
Security is not an issue,
10 or less computers
Simple to configure, low cost
Expansion is not an issue

17. Client/Server Network
Client/server- A network in which one or more master computers keeps a database of users and is responsible for responding to network requests
Features of client/server network
Dedicated server running NOS software
Centralized administration
Backups made easy
Redundancy
Security
Permissions – access rights to network resources
Authentication
User ID
Password
Privileges – actions a user can perform on a network
User accounts with rights to change the system
MS –administrator
Novell Netware – Supervisor
Unix or Linux – root (Superuser)

18. Trust Relationships
One-way explicit trusts (Windows NT)
Two-way transitive trusts (Windows 2000)

19. Directory Service Organizes and simplifies access to resources
Identifies users and resources
Provides a way to organize and access users and resources
Allows you to perform a number of functions
Acts as administration tool and end-user tool

20. Components of Directory Service
Objects – distinct named set of attributes that represents a network resource and its properties
Objects are assigned attributes
Each object must have, at minimum, an object class field and if a user a UID field
3 types of objects
Root – represents the beginning of the hierarchy
Container- (called OU by MS)
exists off the root or other container used to organize objects into logical groups
Country –
optional
Organization-
Represents a country or organization
Organizational unit (OU)—divide leaf objects into workgroups
Leaf
Represents network entities such as users, groups, printers, servers
Distinguished name – objects name along with the completer context starting from root.
.psprinter.accounting.microsoft.us.

21. Organizational Unit (OU)
Subsection under domain
A container that can hold users and computers
Administrative control of an OU can be given to a user
OUs can be assigned policies that apply to their contained objects
Locations where you can create OUs are
Under a domain
Under another OU

22. Media terminology
Carrier wave – the constant voltage of electrical current that carries the data; what the signal wave rides on.
Encoding – the representation of the computers digital zeroes and ones as a physical signal such as electrical current or light pulses
A one bit may be a 5 volt signal and a 0 bit a 2 volt signal
Frequency or amplitude of the signal wave is altered to encode data

23. Analog signal vs digital
Data can be transmitted via one of 2 signaling methods
Analog
Digital
Both are electrical current measured in volts
voltage -- strength of the signal
Digital is more reliable than analog transmission
Digital is less affected by noise than analog transmissions

24. Digital signal Digital is an on off state positive voltage = 1
no voltage = 0
1’s and 0’s are used to encode data
Pulse = bit
8 bits = byte
One byte carries one piece of information
Most data transmission is digital

25. Analog signal
Data sent on the wire is usually some form of analog signal
Electrical signals
Radio waves
Microwaves
Analog signals vary in frequency and amplitude

26. Frequency modulation The data travels along a particular frequency
The carrier signal is modified by the application of the data signal
Signal strength is constant , frequency of the signal changes

27. Amplitude modulation
The amplitude of the carrier signal is modified by the data signal
Frequency of the signal is constant, strength of the signal changes

28. Baseband Transmission3
Baseband Transmission
Bi directional using digital encoding
Single fixed frequency
Entire bandwidth for each signal
All devices use one channel
Signal decreases with length (attenuation)

29. Baseband Transmission (cont.)3
Baseband Transmission (cont.)
Baseband systems like Ethernet
Use repeaters to amplify signals
Restores strength & quality
Sends signal out on another cable
Increases span of network

30. Broadband Transmission3
Broadband Transmission
Uses analog techniques to encode
Continuous electrical or optic waves
Multiple channels on a single cable
Amplifiers are used to:
Strengthen & rebroadcast signal

31. Broadband Transmission(cont.)3
Broadband Transmission(cont.)
To support two-way communication:
Mid-split uses a single cable
Different frequencies for each channel
Dual cable uses two cables
One each for receive & transmit

32. Transmission Direction
Simplex
Simplest
One direction only ( sending or receiving)
Half duplex
Both directions
One direction at a time
Full duplex
Same time
Separate transmit and receives buffers maintained by the transceivers

33. Fiber Optics Glass or plastic strand core 2 modes
Single mode fiber
Faster
Longer distance 4000m
More expensive
Multimode fiber
2000 m
Thicker glass fiber core
Both have limited bend radius
Uses separate lines for send and receive
GB/s transmissions

34. Fiber Optics cont…
2 methods to translate digital stream to light pulses
LED (light emitting diode)
Short distances
LD (laser diode)
Long distances
Connectors used
Straight tip (ST)
MTRJ
Subminiature assembly (SMA)(SC)

35. Advantages and disadvantages of Fiber Optics
Faster data transmission
Longer distance
150 to meters segments
Immune to interference
Immune to corrosion
Secure from eavesdropping
Disadvantages
Cost
Hard to install

36. Infrared Encodes data into pulses of infrared light
Transmission methods include:
Line of sight
Reflective
Uses central access point
Scatter infrared (slowest)
Bounces the signal
Needs reflective surfaces
Reflected light may interfere
Broadband optical telepoint (fastest)
Multiple signals at once on different frequency channels
Infrared is one of the slower technologies
Distance is limited

37. Laser Overcomes the limits of speed and distance of infrared
155Mbps– 622Mbps
4KM
Speed and distance are inversely proportional
More expensive
Harder to install
Line of sight
Affected by physical obstruction
Protocol transparent

38. Radio Medium of choice for SOHO 3 categories
Short wave
Very high frequency (VHF)
Ultra high frequency (UHF)
FCC regulates usage of frequencies
License are required except for public bands
MHz
GHz
Broadcasting power is limited to avoid bleedover
Transmissions are
Single frequency
Spread spectrum

39. The 7 Layers of OSI Divide and conquer
Breaks networking concepts into easy to understand functions and their devices
Makes troubleshooting easier by isolating the function’s layer and focusing on the protocols and devices responsible
Allows development of new technologies without restructuring the entire network

40. Seven-Layer OSI Model 4

41. Application Layer (7) Topmost layer
Represents services that directly support user applications
Window to network services
Handles network access, flow control, and error recovery 6

42. Presentation Layer (6) Network translator
On sending end, determines formatting used to exchange data among computers and adds formatting so data can be understood by network
On receiving end, translates data from application format to a common intermediate format
Manages data compression, translation, encryption
I/O redirectors work to redirect resources to a server 7

43. Session Layer (5)
Allows two applications on different computers to open, use, and close connections
Performs name recognition and provides security
Provides synchronization by placing checkpoints in the data stream
Implements dialog control between communication processes 8

44. Transport Layer (4)
Sending end: repackages message, divides long messages to ship properly over determined route and arrive error-free
Receiving end: unpacks message, reassembles it, and acknowledges receipt
Provides flow control, error handling, and solves transmission problems 9

45. Network Layer (3) Addresses the package using network address scheme
Determines the best route on the network based on network conditions, priority of service
Performs packet switching, routing, traffic management, and controls congestion of data 10

46. Data-Link Layer (2)
Sending end: sends data frames from network layer to physical layer
Receiving end: packages raw bits from physical layer into data frames
Parts of data frame: Destination ID, Sender ID, Control Data
Acknowledges data frames, error checking, and verification 11

47. Physical Layer (1) Bottommost Layer
Hardware-oriented, establishes and maintains physical link between communication computers
Defines how the cable is attached to the NIC
Packet sent as an unstructured raw bit stream over physical medium
Referred to as the “hardware layer” 13

48. 802 Specifications Set Standards for: Network Interface Cards (NICs)
Wide area network (WAN) components
Components used to create twisted-pair and coaxial cable networks 20

49. 802 Specification Categories
Internetworking
Logical Link Control (LLC)
MAC layer, Carrier Sense Multiple Access with Collision Detection (CSMA/CD) LAN (Ethernet)
MAC layer, Token Bus LAN
MAC layer, Token Ring LAN
Metropolitan area Network (MAN)
Broadband Technical Advisory Group
Fiber-Optic Technical Advisory Group
Integrated Voice/Data Networks
Network Security
Wireless Network
Demand Priority Access LAN, 100BaseVG-AnyLAN
Unused
Cable modem standards
Wireless personal area networks (WPAN)
Broadband wireless standards 21

50. Project 802 LLC and MAC Sublayers22

51. Function of the Physical Layer
Hardware Layer
Defines the electrical and mechanical aspects of the network media
Voltages
Cables
Connectors
NICs, hubs and repeaters
Converts the bit stream furnished by the data-link layer into electrical, radio or optical signals and sends it across the media
Frame– the smallest unit of information that is sent after the Data-Link layer adds its header
Layer
Network device
Unit of information
Media Access control
NIC drivers /MAC address
Frames
Physical
Connectors, cables, NICs, hubs, repeaters
Bits and voltages

52. Three Components of the Physical Layer
Physical Signaling (PLS)
Physical Medium Attachment (PMA)
Medium Dependent Interface (MDI)

53. CRC Performs a mathematical algorithm on the frame
Adds result to trailer of packet
Receiving end does the same
ACk is sent if the same
NACK if different

54. Types of Fiber Cable types Single-mode fiber Multi-mode Loose-tube
Multi-strand, single cable
Tight-buffered
Single strand
Kevlar sheath
Cable of choice for interior installation
Single-mode fiber
One signal per strand
Faster rates longer distances
Multi-mode
Wavelength division multiplexing– several light beams per cable
Shorter distances due to modal dispersion

55. Signaling Optical transmitter Light on light off logic
Light emitting diode
Laser diode
Light on light off logic
Speed is direct corollary of the pulse rate
LED is slower MHz
LD GHz
Pulse width modulation
Streaming light short separators
Pulse rate modulation
Duration of separator is changed

56. Unbounded Signaling
Optical
Infrared
laser
Radio
Microwave

57. Optical Infrared Works like fiber light pulses Laser Line of sight
Scatter infrared
Reflective
Broadband optical telepoint
Laser
Requires line of sight

58. Radio AlohaNet – first radio-based network 802.11 standard 802.11a
2.4GHz frequency range
1-2 Mbps
802.11a
5GHz range
5Mbps, 11Mbps and 54Mbps speeds
802.11b
2.4GHz at higher speeds

59. Functions of the Data Link Layer (Layer 2)
Physical Addressing
Network Topology
Error Notification
Access to the physical media
Flow Control

60. Data Link Sub Layers Data Link is divided into 2 sub-layers
Logical Link Control (LLC)
Defines the rules that govern the establishment of logical interface points (SAPs) between devices and layers
Media Access Control (MAC)
Defines physical addressing and medium
Channel Access methods

61. Physical Address (MAC sublayer)
MAC address – 48 bit fixed physical address burned into the network interface by the manufacturer
Displayed in 6 part hexadecimal notation
00:60:B6:A1:78:17
First 24 bits = Organizational Unique Identifier (OUI)
Assigned and administered by IEEE Registration Authority
Last 24 bits = manufacturer assigned interface serial number
Used to uniquely identify all network interfaces
Each addressable port of a device must have a unique MAC address

62. Network Topologies—physical or logical layout of the network
Bus
Ring
Star
Mesh
Hybrid

63. Bus Devices are on a common linear cable (backbone, trunk or segment)
Cable requires termination on both ends
Break in the cable will bring the network to a halt
Uses contention to access the wire

64. Star
Cable segments from each computer are connected through a central component called a hub
Centralized management
Requires more cable than a bus
Failure of a cable or computer affects only that computer
Failure of a hub affects the whole segment

65. Ring Connects computers on a single circle of cable
Uses a token to move data
Data is passed by each computer in one direction
Failure of a computer can stop the network

66. Baseband signaling Used by most LAN technologies Digital communication
Full bandwidth
Bi-directional

67. IEEE
IEEE developed the 802 standards for design and compatibility for hardware components operating in the data-link and physical layers of the OSI
Common 802 standards
802.3 – Ethernet (CSMA/CD)
– Demand Priority Access
– CSMA/CA
802.5 – Token Ring
FDDI (ANSI X3T9.1 standard)

68. CSMA/CD (ETHERNET) Follows the 802.2 and 802.3 standards
Star or Bus Topology
Baseband Transmission
Contention based, probabilistic
Carrier Sense Multiple Access
All devices listen for traffic on the wire
A device sends only if the wire is clear
Collision Detect –
If a collision occurs the systems back-off and after a random time resend
More traffic more collisions
Segmenting the network can reduce collisions
Use a switch to create separate collision domains

69. 10BaseT 10Mbps Baseband over Twisted Pair (cat 3,4,5,or 6)
Star pattern, internal bus signal
Hub is a multi-port repeater
Maximum segment length 100 meters
Maximum computers on a network 1024
Minimum distance between computers is 2.5 meters
RJ-45 connections, transceivers on the NIC

70. 10BASE-2 200 meters (185) maximum segment Thinnet,7
10BASE-2
200 meters (185) maximum segment
Thinnet,
easy to manipulate
not TV coax (75 OHM cable RG58U)
RG-58A/U and RG58C/U 50ohm coaxial(IEEE spec)
minimum length is .5 meters or 20 inches
Transceiver built into NIC
BNC connector, terminators (50 ohm)
Bus topology, rule

71. 10BASE-5 2500 meter maximum network length7
10BASE-5
Standard Ethernet-- used when ethernet was introduced
Transceivers,attached to thicknet via vampire taps, drop cables less than 50 meter max to NICs connect with AUI or DIX port 2.5 meters apart
500 meter maximum segment length
2500 meter maximum network length
5 segments using repeaters (5-4-3 rule)

72. 5-4-3 rule
Max 5 segments
4 repeaters
3 populated segments

73. 10BASE-F Fiber-optic cable 3 subcategories All use star topology7
10BASE-F
Fiber-optic cable
3 subcategories
10BASE-FL fiber to the desktop (LAN)
10BASE-FP passive hubs (rather than repeaters) maximum cable length 500 meters per segment
10BASEFB Fiber backbone between hubs
All use star topology

74. 10BASE-F cont…
Used for long runs between buildings 2000meter max segment length
1023 max number of segments
Max device per segment = 2
CSMA/CD channel access method
High cost
reserved for connections between hubs or for connections requiring security from EMI
difficult to install

75. Token Ring Developed by IBM IEEE 802.5 standard Star-wired topology7
Token Ring
Developed by IBM
IEEE standard
Star-wired topology
Star cabled, operate as logical ring
Token passing channel access method
Wired in a star from the hub– logical ring in the hub
NICs are either 4Mbps or 16Mbps baseband transmission
Used with fiber and switches for high speed and distance

76. Beaconing Active monitor sends beacon announcement every 7 seconds
If computer does not receive the beacon puts a message on the ring
Source address
Address of upstream computer
Continues to send until it receives beacon from upstream number
Finally the only machine beaconing is the one directly downstream from the fault
Hub reconfigures ring dropping the non-responsive device

77. FDDI Fiber optic cable Token passing channel access
Uses dual ring topology for redundancy
Data flows in opposite directions
NICS are
Dual attachment stations (A port stations can reconfigure the ring)
Single attachment stations

78. FDDI Key difference in frame transmission from token passing
FDDI computer can transmit as many frames as it can produce in a predetermined period of time before releasing the token

79. Error Detection Lost Frames Checksum or CRC Frame Size Buffer Overflow
Interference
Data Link notifies Transport Layer. Error correction is done in the Transport layer.

80. Network Layer
Allows internetworking-- Services of the network layer allow different networks to find each other
Services may be used by LAN’s but WAN’s cannot exist without them
Supports both connection-oriented and connectionless service from upper layer protocols
Protocols are typically routing protocols

81. Routable Protocols
Protocols that support multipath LAN to LAN communication
TCP/IP
IPX/SPX

82. Non-routable
Work only in local LAN
Use physical addressing

83. Connection-Oriented Protocols
Connection is established
Data is sent in orderly,slower fashion
Packet receipt is acknowledged
Resends error packets
Connection is terminated

84. Connectionless Protocols
Place the data on the network and assume it will arrive
Faster than connection oriented
Does not establish, maintain or tear down a session
Packet sequencing and sorting is handled in the higher layers
Not as reliable as connection oriented
PDU is a datagram

85. Functions of the Network Layer
Manage Logical Addressing
Translate logical to physical address
Route messages between networks
Determine best path
Controls congestion
Uses priority and network conditions
Does switching and routing of packets
PDU is a packet or datagram at this layer

86. Protocols of the Network Layer
Internet Packet Exchange—(IPX) – logical addressing protocol used by Novell NetWare
Internet Protocol – (IP) – logical addressing protocol used by TCP/IP networks
Internet Control Message Protocol –(ICMP)– used to send control, confirmation and error messages
Border Gateway Protocol –(BGP)—internet inter-domain routing protocol
Open Shortest Path First- (OSPF)– a link state , interior gateway protocol used in TCP/IP networks
Routing Information Protocol –(RIP)– an Internet routing protocol that uses hop count metric
Address Resolution Protocol-(ARP)– resolves logical to physical address
Reverse Address Resolution Protocol –(RARP) – resolves physical to logical address

87. IP Provides source and destination addressing and routing
Connectionless datagram protocol –assumes other protocols will ensure reliable delivery

88. Classes There are 5 Classes
Class A(1-126),B( ),C ( ) unicast addresses used by networks
Class D multicast address ( )
Class E is experimental, future use ( )

89. Routing in TCP/IP
Subnet mask is used to identify the network portion of the IP address
Only devices on the same network can “see “ each other
Default gateway is an address of a multi-homed device (router)
Maintains a table of all known networks
Forwards the packet via the port connected to the network of the destination IP

90. Netmask
Signifies the part of the address used for the network and the part used for the host
Default mask for each Class A B C
1= network 0=hosts

91. Routing Tables Static Dynamic
Administrator manually configures route tables (reconfigure for changes)
More secure
Dynamic
Routers use routing protocols to configure routing tables
Routing tables must contain a minimum of 2 fields
IP address prefix (netmask)
Next hop (gateway)
Most include the metric of a route

92. Distance Vector Simple Router knows only of directly connected devices
Maintains a table of next hop on interface
Uses metric to determine hop count and routes accordingly
Not very secure
Not scalable (15 hop limit)
RIP protocol

93. Link State Monitor condition of each connected link
Advertise conditions to neighboring routers
Link speed
Latency
Status of routers on the network
OSPF protocol

94. Internet Control Message Protocol
ICMP- RFC792- defined
Integral part of IP– part of Internet Layer
Uses IP datagram delivery facility to send messages
ICMP messages function—(used by routers)
Flow Control– destination host sends
ICMP Source Quench Message to sender
Temporarily stops transmission
Detectiong unreachable destination—
System which detected problems sends destinatin unreachable to datagrams source
If destination is network or host intermediate
System sends
If port is unreachable
Destination host sends message
Redirecting routes
Gateway sends ICMP Redirect Message
Better route – to tell the host to use a different gateway

95. ARP RARP Address resolution protocol
Determines hardware address for IP
If address is not cached then broadcasts request
RARP
Reverse address resolution protocol
Maintains a database of machine numbers, (created by system administrator)
Provides IP number to hardware address

96. Transport Protocols
Facilitate communication sessions between computers
Ensure reliable movement of data
Monitor flow control
End to end error detection recovery
Responsible for end-to-end integrity of data
Congestion control
solves transmission problems
Breaks data into chunks (segments data) and and sequences segments begins encapsulation

97. Transport Layer (4)
Sending end: repackages message, divides long messages to ship properly over determined route and arrive error-free
Receiving end: unpacks message, reassembles it, and acknowledges receipt
Provides flow control, error handling, and transmission. 9

98. Transport Protocols Ensure reliable data delivery6
Transport Protocols
Ensure reliable data delivery
TCP (Transmission Control Protocol)
SPX (Sequenced Packet eXchange)
Novell’s connection-oriented protocol
NWLink (MS implementation of SPX)
NetBEUI-MS standard transport layer non-routable (NetBEUI/NetBIOS)

99. Connectionless Protocols6
Connectionless Protocols
Place the data on the network and assume it will arrive
Faster, doesn’t waste time establishing, maintaining, and tearing down connections.
Packet sequencing and sorting are handled at higher layers
Not as reliable as connection-oriented
Connectionless packets referred to as datagrams

100. Connection-Oriented Protocols6
Connection-Oriented Protocols
Connection is established
Data sent in orderly, slower fashion
Packet receipt is acknowledged
Resends error packets
Connection is terminated

101. Port Numbers Logical address that points to a specific protocol
Identifies application to transport layer
Up to 65,536 ports
2 port addresses
Well known ports (0-1023)
Controlled and assigned by IANA
Destination port
Ephemeral ports
Used by client to establish connections
source and destination
Registered ports ( )
Accessible to network users and processes with no special administrative privileges
Must be registered with IANA
Dynamic or private ports ( )
Open for use without restriction

102. Well Known Ports 20 FTP data 21 FTP control 23 Telnet 25 SMTP 53 DNS
80 HTTP
444 HTTPS
109 POP v2
110 POP v3
2049 NFS

103. Flow Control Buffer overflow Stop and Wait Static Window
Do nothing ; potential for large number of retransmissions
Stop and Wait
Ack packet for each frame
Static Window
Set number of frames to transmit before waiting for ack
Agreed on during the handshake
Sliding Window
Receiving device sends a hold packet . 2 types:
Selectively repeat---Only nack generates resends
Go back n--- cumulative ack
Packets arrive in sequence
Resends bad packet and any that followed it

104. Error Control Types of error Packet loss Packet corruption
Packet duplication

105. DNS (Domain Name System)
Transport layer, name-to-address resolution protocol
DNS server keeps a list of system’s names and their IP addresses.
Can use a system’s logical name (microsoft.com) rather than its numerical address when communicating

106. Session --Virtual connection for the purpose of transferring data
Dialogue –series of sessions used for a complex process or transfer of a large quantity of data.

107. Session Layer Functions
Allows applications on different computers to open, use and close a connection
Structured dialog
Security
name recognition
Synchronization
check points in data

108. Steps for establishing a session
Logon on authentication
Establish connection ID number
Agree on services and duration
Determine who initiates transfer
Coordinate ack and retransmission procedures
Session layer relies on support from lower layers to create sessions. In TCP/IP the transport and session functions are combined in the transport layer.

109. Logon Authentication
Connection oriented --required before session building can begin
credentials– user information required by a system to permit access to network resources
Username and password
Cached and checked each time a resource is accessed
Client/server model authentication is done by the security database of the server running the service
Peer to peer model – the password is compared to the password assigned to the resource

110. Managers data compression, translation, and encryption
Presentation
Network Translator
On sending end determines format used to exchange data among networked computers and adds formatting so data can be understood
Uses a commonly recognized intermediary format, receiving computer translates back to own format
Managers data compression, translation, and encryption
Redirector operates here

111. Presentation Layer Protocols
Presentation layer implementations are not typically associated with a particular protocol stack.
Some examples of presentation layer coding and conversion schemes include
ASCII.
EBCDIC
Motion Picture Experts Group (MPEG)
QuickTime
Tagged Image File Format (TIFF)
Joint Photographic Experts Group (JPEG)
Graphics Interchange Format (GIF),

112. Compression Choice of file format dictates compression scheme
Source encoding– compression at file level
Lossless–
Maintains quality
tif and bmp
Lossy-
Trade quality for size
gif and jpg
Data compression– compression at transfer
Finite set of symbols—
Run length encoding

113. Encryption Data security – 3 common methods
sending device scrambles the bit order before transmitting
Receiving device has key to unscramble
3 common methods
Substitution cipher
Substitute one letter for another
Transposition cipher
Reorders characters
Data encryption standard (DES)
Most secure
64 bit key exchanged at beginning of the session determines bit order
May use Exclusive Or-Gate in data stream to change the key

114. Services that directly support the users applications
Application processes communicate between applications and lower layer services
Allow software programs to negotiate formatting, procedure, security and synchronization
File transfer Data base access
Window for application to access network services

115. Hardware
Gateway

116. TCP/IP Protocol Stack 4 layers Process/Application app/pres/sess
Host to Host transport
Internet network
Network Access datalink/physical

117. IP IP V4 uses a 32 bit address in 4byte divisions
Each byte has 256 possibilities
0 and 255 reserved for network broadcast
127 is a loop back
1-254 are used to denote networks or hosts

118. IP Addressing Logical Address assigned to each host
IP locates the network of a device
Once the network is located the network will find the device by the host portion of the address

119. Subnet Mask
Used to denote which part of the address Is the network and which is the node
1 masks the network

120. IP Addressing (Ver. 4) First octet denotes class A, B, C, D, E6
IP Addressing (Ver. 4)
First octet denotes class A, B, C, D, E
Class A,B,C are network classes
Class D is multicast addresses
Class E is experimental
Class A ,387,064 hosts
(254*254*254 hosts)
Class B ,512 hosts
(254*254 hosts)
Class C
254 hosts per network

121. Fully Qualified Domain Name
Unique computer name within a DNS namespace
Example—sales.
Read from left to right
More specific information is on the left

122. Network layer protocols of TCP/IP suite
BootP
DHCP
ICMP
ARP
RARP

123. DHCP Places available IP addresses into a pool and leases to clients
50% maturity client request renewal from leasing server
75% maturity client requests reassignment from any server
Can hand out most TCP/IP configuration parameters

124. ICMP (Internet Control Message Protocol)
RFC 792
TCP/IP best troubleshooting aid
Network layer protocol used to send control messages (errors and confirmations)
Out of band messages separate from the data

125. ARP Address Resolution Protocol
Network layer protocol used to resolve a logical (IP) address to a physical (MAC) address
When a system begins a conversation with a host that it does not have a physical address for, it sends and ARP broadcast packet requesting the physical address that corresponds to the logical address. Then, the Data Link layer can correctly send the packet through the network.
RARP- assign IP address to MAC address

126. WINS NETBIOS to IP Requires WINS server WINS database is dynamic–
system broadcasts when it boots to the network
Server extracts information

127. Hosts and LMHosts Statically resolve IP addresses Hosts LMHosts
DNS to IP
LMHosts
NETBIOS to IP

128. TCP/IP Protocol Suite RIP (Routing Information Protocol)6
TCP/IP Protocol Suite
RIP (Routing Information Protocol)
Network layer protocol
Distance-vector routing protocol used for route discovery (hops)
OSPF (Open Shortest Path First)
Link-state routing protocol used by routers running TCP/IP to determine the best path through a network.

129. Transmission Control Protocol (TCP/IP)
Three-Way Handshake:
Requestor sends a packet specifying the port number and its initial sequence number (ISN) to server
Server acknowledges with its ISN, which consists of the requestor’s ISN, plus 1
The requester replies with the server’s ISN, plus 1 12

130. Configuring TCP/IP TCP/IP protocol can be configured one of two ways
Dynamic via DHCP (automatic IP)
Static – IP set
IP address
Subnet mask
Gateway IP for forwarding packets beyond the LAN

131. Gateway A gateway in TCP/IP is a doorway to other networks
Usually an internal port of a router
Can be a 2nd ethernet card on a dual homed system
If multiple gateways are listed in the routing table, they will be queried in the order listed
Default gateway– defines where to send a packet if the network or node is not recognized

132. Subnetting Borrowing host bits of a IP network address
More networks fewer hosts per network
Reduce congestion
Security

133. CIDR (Supernetting) Classless Interdomain Routing (classless IP)
Response to the depleted supply of IPv4 addresses
Borrow bits from the network portion of the address to allow for more hosts
Used for networks that require more than 254 hosts
Network addresses must be contiguous or fall within the range of the subnet mask
To combine class C the 3rd octet of the first address must be divisible by the range of addresses
If public addressing must be contiguous range
Network Address uses an IP prefix/CIDR block
/20

134. TCP/IP Utilities
Troubleshooting utilities that are part of the TCP/IP suite
Tracert
Ping
IPconfig
Nbtstat
Route
Netstat

135. IPX/SPX Developed by Xerox in early 1980s
Default network protocol for Novell NetWare versions prior to 5.0
Protocol provides transport services for data over the network
IPX is connectionless protocol
SPX is connection oriented protocol

136. NetBEUI
IBM NetBIOS Enhanced User Interface (1985) for LAN Manager server application
Default protocol for WNT3.51
NetBEUI is a non routable protocol
Operates mostly in the Data Link Layer
Modeled after the LLC of the OSI
Requires a bridge or switch to segment the network
Fastest of all protocols currently in use
Discontinued as of XP

137. AppleTalk Addressing
Name Binding Protocol (NBP) dynamically assigns a unique node ID to each host and binds the NBP name to the ID
Datagram Delivery Protocol (DDP) provides point to point delivery functions
Uses a 16 bit network number
DDP packet contains source and destination address, hop count and checksum
Hop count over 16 is discarded
Connectionless protocol

138. WAN Overview
Most are combinations of LANS and communication components connected by WAN Links
Packet-switching networks
Fiber-optic cable
Microwave transmitters
Satellite links
Cable television coaxial systems
Usually leased from service provider due to cost
Use the following transmission technologies
Analog– digital---packet-switching

139. Remote Access (WAN) Protocols
Point to Point Protocol (PPP)
Point to Point Tunneling Protocol (PPTP)
Used on Virtual Private Network (VPN)
Remote Desktop Protocol (RDP)
Citrix Independent Computing Architecture protocol (ICA)

140. PPTP (tunneling for VPN)
More secure connection
Uses encryption keys Supports multiprotocol VPN
Can connect via the internet to network
Connect to the RAS server
PPTP routes IP, IPX, or NetBEUI PPP protocol packets over TCP/IP network
Uses encapsulation

141. Circuit Switching Used in telephone communication
Established connection from point A to point B maintained for duration of the session
Packets arrive in order
Used by Public Switched Telephone Network (PSTN) (POTS)
And Integrated Services Digital Network (ISDN)

142. Packet Switching Networks
Switches direct packets over pathways.For short and long distance
Fast efficient , reliable
Internet is packet switching network
Data handling:
Original data is segmented into packets
Each packet is labeled with sequence and destination
Each packet sent individually onto the network
By fastest, shortest route
Reconstructs data at destination end
Does not depend on any single pathway
Use Virtual circuits for temporary dedicated pathways
Switched Virtual Circuit– ppp established when needed
Permanent Virtual Circuit– established as permanent logical connection

143. T1 Most widely used digital line type PPP 2 wire pairs
Send and receive
Full duplex rate of 1.544Mbps
Transmits digital voice and data and video
Most costly of WAN links
Can subscribe to a channel in 64Kbps (fractional T-1)

144. CSU/DSU Channel service unit/data service unit
Provides network interface for the T1 connection and your computer equipment
CSU provides filtering of noise and intercepts loopback signals
DSU provides synchronization and timing

145. Sonet/SDH
Synchronous Optical Network and Synchronous Data Hierarchy are competing technologies
SONET
Physical Layer protocol uses fiber optics for transmission
Can be configured in dual ring or bus topology
155Mbps-2.5Gbps transmission
Deliver voice data and video
Sonet uses Time Division Multiplexing to mix signals of different speeds into a single high speed transmission

146. SONET cont… SONET networks are divided into 3 separate regions
Local collector ring– individual access
Regional network– collates signals into a single pipeline
Broadband backbone– moves data over the highspeed pipeline

147. VPN Uses the Internet for remote connection
Uses PPTN protocol, encrypting data and securing the connection

148. RAID (tab 16.4) Redundant array of independent disks Levels
Level 0 striping
64k blocks divided equally across disk– no redundancy
2-32 drives
Large logical disk
Level 1 Disk Mirroring
Two drives single controller
Disk duplexing
Two drives , two controllers
Level 2 Striping with ecc
Block is distributed across stripes
Level 50 RAID1 and RAID5

149. Security in the NOS Security patches Security features:
Share level access
User level access
Authentication
File system security
Printer security
Directory services
IP Security
Kerberos

150. Share level Owner is responsible for security
Restrictions are set on the share (passwords are optional)
Read only (read and copy)
Full control ( anything including modify permissions and ownership)
Change ( read edit delete)

151. User Level
User ID and password are the key to the network resources (Credentials)
Association of permissions and rights are through the Security Identification (SID) number in Windows
Kept in the Security Accounts Management database (SAM)
Novell the user is an object and permissions are properties of that object
Directory Services tracks UID and GID against the object properties
Credentials are checked each time a resource is accessed

152. Building Barriers Firewalls Circuit gateway– session layer of OSI
directs all traffic to the gateway IP port
Substitutes sending machines IP address with gateway address
Intercepts incoming traffic, filters and passes it on
Application gateway– control traffic primarily by opening and closing ports

153. Firewalls continued Direct traffic via: Packet filtering
Stateful inspection
Proxy service

154. Proxy service Similar to proxy servers
Intercepts packets from the outside and forwards to host
Replaces outgoing IP address with gateway (circuit gateway)

155. SSL and TLS
Secure Socket Layer (SSL) Connection security protocol that provides secured point to point connection between 2 devices
SSL Handshake protocol--Requires secure connection and credential exchange (encryption and key exchange)
SSL Record Protocol– encapsulates network data and allows encryption and transmission
Transport Layer Security (TLS) – recent implementation of SSL focuses on transport layer