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Fundamentals of Data Networks CPCS371 CPCS371 ‫الرحيم‬ ‫الرحمن‬ ‫اهلل‬ ‫بسم‬ ‫الرحيم‬ ‫الرحمن‬ ‫اهلل‬ ‫بسم‬ Faculty of Computing and Information Technology, KAU Computer Science Department Chapter 1: Chapter 1: Introduction Introduction
Chapter 1: Chapter 1: Introduction Introduction 1.1 Data Communications 1.2 Networks 1.3 The Internet 1.4 Protocols and Standards
Textbook : Data Communications and Networking, 4th Behrouz A. Forouzan.
Grading system Participation: 5 First test:10 Second test: 20 Final test: 30 Lab : 20 Quizzes : 15
Introduction Introduction  Data communications and networking  Change the way we do business and the way we live  Business decisions have to be made more quickly  Decision depends on immediate access to accurate information  Business today rely on computer networks and internetworks  Before get hooked up, we need to know:  How networks operate  What types of technologies are available  Which design best fills which set of needs
Introduction Introduction  Development of the PC changes a lot in business, industry, science and education.  Similar revolution is occurring in data communication and networking Technologies advances are making it possible for communications links to carry more and faster signals Services are evolving to allow the use of this expanded capacity For example telephone services extended to have: • Conference calling • Call waiting • Voice mail • Caller ID
1.1 Data Communications 1.1 Data Communications Communication:  Means sharing information • Local (face to face) or remote (over distance)  Telecommunication • Telephone, telegraph and television • Means communication at a distance • Tele is Greek for far
Data Communications Data Communications Data:  Refers to information • Presented in any form • Agreed upon by the parties ( creating & using) Data communication : is the exchange of data between two devices via some form of transmission medium (wire cable).
Data Communications Data Communications  Communication system made up of a combination of hardware and software  Effectiveness of data communication system depends on: 1. Delivery : The system must deliver data to correct destination. Data received by the indented user only 2. Accuracy: The system must deliver data accurately (no change). • Data changed & uncorrected is unusable
Data Communications Data Communications 3. Timeliness: The system must deliver data in timely manner • Data arrived late are useless • In the same order (video and audio) & without delay (Real time transmission) 4. Jitter: Variation in the packet arrival time (uneven quality in the video is the result)
Data Communications Data Communications
Components Components  A data communication system is made up of five components
Components Components 1. Message: the information (data) to be communicated – Consist of text, numbers, pictures, audio, or video 2. Sender: the device that sends the data message – Computer, workstation, telephone handset, video camera, … 3. Receiver: the device that receives the message – Computer, workstation, telephone handset, television, ….
Components Components 4. Medium: The physical path by which a message travels from sender to receiver – twisted pair, coaxial cable, fiber-optic, radio waves
Components Components 5. Protocol: a set of rules that govern data communications – An agreement between the communicating devices – Devices may be connected but not communicating (no protocol) – Arabic speaker with Japanese speaker
Data Representation Data Representation Text Text Audio Audio Video Video Numbers Numbers Images Images
Data Representation Data Representation Text: Sequence of bits (0s or 1s) Different sets of patterns to represent text symbols (each set is called: code) ASCII: 7 bits (128 symbols) common coding system today is: Unicode uses: 32 bits to represent a symbol or character in any language Unicode Unicode (4,294,967,296)
Data Representation Data Representation Numbers: Represented by bit patterns The number is directly converted to a binary number
Data Representation Data Representation Images: Represented by bit patterns A matrix of Resolution: size of the pixels High resolution: more memory is needed Each pixel is assigned a bit pattern 1-bit pattern (black and white dots image) 2-bit pattern (4 levels of gray) RGB (color images) pixels
Data Representation Data Representation Audio: Continuous not discrete Change to digital signal Video: Recording or broadcasting of a picture or movie Change to digital signal
Data Flow Data Flow Communication between two devices can be:  Simplex  Half-Duplex  Full-Duplex
Data Flow Data Flow Simplex (one way street)  The communication is unidirectional  Only one device on a link can transmit; the other can only receive  Use the entire capacity of the channel to send data  Example: Keyboards, Monitors Data
Data Flow Data Flow Half-Duplex (one-lane with two-directional traffic)  Each station can both transmit and receive, but not at the same time  When one device is sending, the other can only receive, and vice versa  The entire capacity of a channel is taken over by the transmitting device  Example: Walkie-talkies Data Data
Data Flow Data Flow Full-Duplex (Duplex) (two-way street)  Both stations can transmit and receive at same time  Signals going in either direction sharing the capacity of the link  Sharing can occur in two ways:  Link has two physically separate transmission paths • One for sending and the other for receiving  The capacity of the channel is divided between signals travelling in both directions  Example: Telephone network Data Data
Exercise Exercise What mode of data flow the following exhibits shows? Answer: Full-Duplex Data Data
Networks Networks  Network : A set of devices (nodes) connected by communication links Node : computer, printer, … - Distributed Processing : - Most networks used it - Task is divided among multiple computers instead of one single large computer
Networks Networks Network Criteria – Network must meet a certain number of criteria – The most important of the network criterions are: – Performance – Reliability – Security
Networks Networks  Performance  Transit time: A mount of time required for a message to travel from one device to another  Response time: Elapsed time between an inquiry and a response
Networks Networks  Performance  Performance depends on : 1- Number of users: large number slow response time. 2- Type of transmission medium: fiber-optic cabling faster than others cables. 3- Capabilities of the connected hardware: affect both the speed and capacity of transmission. 4- Efficiency of the software: process data at the sender and receiver and intermediate affects network performance.
Networks Networks  Performance  Performance is evaluated by two contradictory networking metrics:  Throughput (high): a measure of how fast we can actually send data through a network  Delay (low)
Networks Networks  Reliability  Reliability is measured by: 1. Frequency of failure 2. Recovery time of a network after a failure 3. Network’s robustness in a catastrophe: protect by good back up network system
Networks Networks  Security  Protecting data from unauthorized access  Protecting data from damage and development  Implementing policies and procedures for recovery from breaches and data losses (Recovery plan)
Networks Networks Physical Structures: Type of connection Network: Two or more devices connected through links Link: Communication pathway that transfers data from one device two another Two devices must be connected in some way to the same link at the same time. Two possible types: • Point-to-Point • Multipoint
Networks Networks Point-to-Point  Dedicated link between two devices Entire capacity of the link is reserved for transmission between those two devices Use an actual length of wire or cable
Networks Networks Point-to-Point  Other options, such as microwave or satellite is possible Example: Television remote control
Networks Networks Multipoint (multidrop)  More than two devices share a single link Capacity is shared Channel is shared either spatially or temporally  Spatially shared: if devices use link at same time  Timeshare: if users must take turns
Networks Networks Physical Topology  The way a network is laid out physically Two or more links form a topology The topology of a network is the geometric representation of the relationship of all the links and linking devices (nodes) to one another. Four topologies : Mesh, Star, Bus, and Ring
Physical Topology Physical Topology
Physical Topology Physical Topology Mesh Every link is dedicated point-to-point link The term dedicated means that the link carries traffic only between the two devices it connects
Physical Topology Physical Topology Mesh To link n n devices fully connected mesh has: n ( n - 1) / 2 n ( n - 1) / 2 physical channels (Full- Duplex) Every Device on the network must have n - 1 n - 1 ports
Physical Topology Physical Topology Mesh Example: 8 devices in mesh has links: n(n-1) / 2 number of links = 8 (8-1)/2 = 28 number of ports per device = n – 1 = 8 –1 = 7
Physical Topology Physical Topology Mesh Advantages Each connection carry its own data load (no traffic problems) A mesh topology is robust Privacy or security Fault identification and fault isolation
Physical Topology Physical Topology Mesh: Disadvantages Big amount of cabling Big number of I/O ports Installation and reconnection are difficult Sheer bulk of the wiring can be greater than the available space Hardware connect to each I/O could be expensive Mesh topology is implemented in a limited fashion; e.g., as backbone of hybrid network
Physical Topology Physical Topology Star: Dedicated point-to-point to a central controller (Hub) No direct traffic between devices The control acts as an exchange
Physical Topology Physical Topology Star Advantages Less expensive than mesh (1 Link + 1 port per device) Easy to install and reconfigure Less cabling Additions, moves, and deletions required one connection Robustness : one fail does not affect others Easy fault identification and fault isolation
Physical Topology Physical Topology Star Disadvantages Dependency of the whole topology on one single point (hub) More cabling than other topologies ( ring or bus) Used in LAN
Physical Topology Physical Topology Bus It is multipoint One long cable acts as a backbone Used in the design of early LANS, and Ethernet LANs
Physical Topology Physical Topology Bus Nodes connect to cable by drop lines and taps Signal travels along the backbone and some of its energy is transformed to heat Limit of number of taps and the distance between taps
Physical Topology Physical Topology Bus Advantages Ease of installation Less cables than mesh, star topologies Disadvantages Difficult reconnection and fault isolation ( limit of taps) Adding new device requires modification of backbone Fault or break stops all transmission The damaged area reflects signals back in the direction of the origin, creating noise in both directions
Physical Topology Physical Topology Ring Each device has dedicated point-to-point connection with only the two devices on either side of it A signal is passed along the ring in one direction from device to device until it reaches its destination Each devices incorporates a Repeater
Physical Topology Physical Topology Ring Advantages Easy of install and reconfigure Connect to immediate neighbors Move two connections for any moving (Add/Delete) Easy of fault isolation Disadvantage Unidirectional One broken device can disable the entire network. This weakness can be solved by using a dual ring or a switch capable of closing off the break
Physical Topology Physical Topology Hybrid Topology Example: having a main star topology with each branch connecting several stations in a bus topology
Categories of Networks Categories of Networks Network Category depends on its size Two primary categories LAN LAN: Covers area < 2miles WAN WAN: Can be worldwide MAN MAN: Between LAN & WAN, span 10s of miles
Local Area Network (LAN) Local Area Network (LAN) Privately owned Links devices in the same office, building, or campus Simple LAN: 2 PCs & 1 printer in home or office Size is limited to a few kilometers Allow resources to be shared (hardware, software, or data)
Local Area Network (LAN) Local Area Network (LAN) An isolated LAN connecting 12 computers to a hub in a closet
Local Area Network (LAN) Local Area Network (LAN) LAN is distinguished by: Size (# users of OS, or licensing restrictions) Transmission medium (only one type) Topology (bus, ring, star) Data Rates (speed): Early: 4 to 16 Mbps Today: 100 to 1000 Mbps
Wide Area Networks (WAN) Wide Area Networks (WAN) Provides long-distance transmission of data over large geographic areas (country, continent, world)
Wide Area Networks (WAN) Wide Area Networks (WAN) Switched WAN Backbone of the Internet Dialup line point-to-point WAN Leased line from a telephone company
Wide Area Networks (WAN) Wide Area Networks (WAN)
Metropolitan Area Networks (MAN) Metropolitan Area Networks (MAN) Size between LAN and WAN Inside a town or a city Example: the part of the telephone company network that can provide a high-speed DSL to the customer
Interconnection of Networks: Interconnection of Networks: Internetworks Internetworks Two or more networks connected together
The Internet The Internet Internet has revolutionized many aspects of our daily lives. It has affected the way we do business as well as the way we spend our leisure time. Internet is a communication system that has brought a wealth of information to our fingertips and organized it for our use An internet is 2 or more networks that can communicate with each other The Internet is a collaboration of more than hundreds of thousands of interconnected networks
The Internet The Internet  An internet (small i) is two or more networks  Notable internet is called the Internet (hundreds of thousands interconnected networks)  Private individuals + government agencies + school + research facilities + Corporations + libraries in more than 100 countries  This communication system came in 1969  Mid-1960 (ARPA) Advanced Research Projects Agency in (DOD) was interested to connect mainframes in research organizations  1967, ARPA presented its ideas for ARPANET  Host computer connecting to (IMP) interface message processor.  Each IMP communicate with other IMP  1969, four nodes (universities) connected via IMPs to form a network  Software (NCP) Network Control Protocol provided communication between the hosts.  1972, Vint Cerf and Bob Kahn invented (TCP) Transmission Control Protocol  Later TCP was split to (TCP) Transmission Control Protocol and (IP) Internetworking Protocol
The Internet The Internet Internet Today Made of many LANs and WANs Every day new networks area added and removed Internet services Providers (ISPs) offer services to the end users International service providers National service providers Regional service providers Local service providers Data rate
The Internet The Internet Hierarchical organization of the Internet
Protocols and Standards Protocols and Standards Protocol synonymous with rule Standards: agreed-upon rules Protocols A protocol is a set of rules that govern data communications Defines What, How, and When it is communicated
Protocols and Standards Protocols and Standards Elements of a protocol: Syntax: structure or format of data Example: 8-bits address of sender, 8-bits address of receiver Semantics: meaning of each section of bits Example: Does the address is a route to be taken or the final destination of the message Timing: when data should be sent and how fast they can be sent Example: sender produces data at 100 Mbps but the receiver can process data at only 1 Mbps  overload and data loose
Standards Standards Essential in creating and maintaining an open and competitive market for equipment manufactures Guaranteeing national and international interoperability of data and telecommunication technology and processes Providing guidelines to manufacturers, vendors, government agencies, and other service providers to ensure the kind of interconnectivity necessary in today’s marketplace and in international communications
Standards Standards Two categories De facto: not approved by an organized body but adopted as standards through widespread use De jure: Legislated by an officially recognized body
Standards Standards Standards are developed through the cooperation of: Standards Creation Committees ISO, ITU-T, CCITT, ANSI, IEEE, EIA Forums Created by special-interest groups Present their conclusions to the standards bodies Regulatory Agencies Ministry of Telecommunication and Information Technology (KSA) Purpose: Protecting the public by regulating radio, television, and communication
Standards Standards Internet standards Tested thoroughly tested specification that is useful to be adhered to by those who work with the Internet Formalized regulation that must be followed Specification become Internet standard Begins as Internet draft for 6 months Upon recommendation from the Internet authorities draft published as Request for Comment (RFC) RFC is edited, assigned a number, and made available to all interested parties

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fundamentals of data networks and communication

  • 1.
    Fundamentals of DataNetworks CPCS371 CPCS371 ‫الرحيم‬ ‫الرحمن‬ ‫اهلل‬ ‫بسم‬ ‫الرحيم‬ ‫الرحمن‬ ‫اهلل‬ ‫بسم‬ Faculty of Computing and Information Technology, KAU Computer Science Department Chapter 1: Chapter 1: Introduction Introduction
  • 2.
    Chapter 1: Chapter 1:Introduction Introduction 1.1 Data Communications 1.2 Networks 1.3 The Internet 1.4 Protocols and Standards
  • 3.
    Textbook : DataCommunications and Networking, 4th Behrouz A. Forouzan.
  • 4.
    Grading system Participation: 5 Firsttest:10 Second test: 20 Final test: 30 Lab : 20 Quizzes : 15
  • 5.
    Introduction Introduction  Data communicationsand networking  Change the way we do business and the way we live  Business decisions have to be made more quickly  Decision depends on immediate access to accurate information  Business today rely on computer networks and internetworks  Before get hooked up, we need to know:  How networks operate  What types of technologies are available  Which design best fills which set of needs
  • 6.
    Introduction Introduction  Development ofthe PC changes a lot in business, industry, science and education.  Similar revolution is occurring in data communication and networking Technologies advances are making it possible for communications links to carry more and faster signals Services are evolving to allow the use of this expanded capacity For example telephone services extended to have: • Conference calling • Call waiting • Voice mail • Caller ID
  • 7.
    1.1 Data Communications 1.1Data Communications Communication:  Means sharing information • Local (face to face) or remote (over distance)  Telecommunication • Telephone, telegraph and television • Means communication at a distance • Tele is Greek for far
  • 8.
    Data Communications Data Communications Data: Refers to information • Presented in any form • Agreed upon by the parties ( creating & using) Data communication : is the exchange of data between two devices via some form of transmission medium (wire cable).
  • 9.
    Data Communications Data Communications Communication system made up of a combination of hardware and software  Effectiveness of data communication system depends on: 1. Delivery : The system must deliver data to correct destination. Data received by the indented user only 2. Accuracy: The system must deliver data accurately (no change). • Data changed & uncorrected is unusable
  • 10.
    Data Communications Data Communications 3.Timeliness: The system must deliver data in timely manner • Data arrived late are useless • In the same order (video and audio) & without delay (Real time transmission) 4. Jitter: Variation in the packet arrival time (uneven quality in the video is the result)
  • 11.
  • 12.
    Components Components  A datacommunication system is made up of five components
  • 13.
    Components Components 1. Message: theinformation (data) to be communicated – Consist of text, numbers, pictures, audio, or video 2. Sender: the device that sends the data message – Computer, workstation, telephone handset, video camera, … 3. Receiver: the device that receives the message – Computer, workstation, telephone handset, television, ….
  • 14.
    Components Components 4. Medium: Thephysical path by which a message travels from sender to receiver – twisted pair, coaxial cable, fiber-optic, radio waves
  • 15.
    Components Components 5. Protocol: aset of rules that govern data communications – An agreement between the communicating devices – Devices may be connected but not communicating (no protocol) – Arabic speaker with Japanese speaker
  • 16.
  • 17.
    Data Representation Data Representation Text: Sequenceof bits (0s or 1s) Different sets of patterns to represent text symbols (each set is called: code) ASCII: 7 bits (128 symbols) common coding system today is: Unicode uses: 32 bits to represent a symbol or character in any language Unicode Unicode (4,294,967,296)
  • 18.
    Data Representation Data Representation Numbers: Representedby bit patterns The number is directly converted to a binary number
  • 19.
    Data Representation Data Representation Images: Representedby bit patterns A matrix of Resolution: size of the pixels High resolution: more memory is needed Each pixel is assigned a bit pattern 1-bit pattern (black and white dots image) 2-bit pattern (4 levels of gray) RGB (color images) pixels
  • 20.
    Data Representation Data Representation Audio: Continuousnot discrete Change to digital signal Video: Recording or broadcasting of a picture or movie Change to digital signal
  • 21.
    Data Flow Data Flow Communicationbetween two devices can be:  Simplex  Half-Duplex  Full-Duplex
  • 22.
    Data Flow Data Flow Simplex(one way street)  The communication is unidirectional  Only one device on a link can transmit; the other can only receive  Use the entire capacity of the channel to send data  Example: Keyboards, Monitors Data
  • 23.
    Data Flow Data Flow Half-Duplex(one-lane with two-directional traffic)  Each station can both transmit and receive, but not at the same time  When one device is sending, the other can only receive, and vice versa  The entire capacity of a channel is taken over by the transmitting device  Example: Walkie-talkies Data Data
  • 24.
    Data Flow Data Flow Full-Duplex(Duplex) (two-way street)  Both stations can transmit and receive at same time  Signals going in either direction sharing the capacity of the link  Sharing can occur in two ways:  Link has two physically separate transmission paths • One for sending and the other for receiving  The capacity of the channel is divided between signals travelling in both directions  Example: Telephone network Data Data
  • 25.
    Exercise Exercise What mode ofdata flow the following exhibits shows? Answer: Full-Duplex Data Data
  • 26.
    Networks Networks  Network :A set of devices (nodes) connected by communication links Node : computer, printer, … - Distributed Processing : - Most networks used it - Task is divided among multiple computers instead of one single large computer
  • 27.
    Networks Networks Network Criteria – Networkmust meet a certain number of criteria – The most important of the network criterions are: – Performance – Reliability – Security
  • 28.
    Networks Networks  Performance  Transittime: A mount of time required for a message to travel from one device to another  Response time: Elapsed time between an inquiry and a response
  • 29.
    Networks Networks  Performance  Performancedepends on : 1- Number of users: large number slow response time. 2- Type of transmission medium: fiber-optic cabling faster than others cables. 3- Capabilities of the connected hardware: affect both the speed and capacity of transmission. 4- Efficiency of the software: process data at the sender and receiver and intermediate affects network performance.
  • 30.
    Networks Networks  Performance  Performanceis evaluated by two contradictory networking metrics:  Throughput (high): a measure of how fast we can actually send data through a network  Delay (low)
  • 31.
    Networks Networks  Reliability  Reliabilityis measured by: 1. Frequency of failure 2. Recovery time of a network after a failure 3. Network’s robustness in a catastrophe: protect by good back up network system
  • 32.
    Networks Networks  Security  Protectingdata from unauthorized access  Protecting data from damage and development  Implementing policies and procedures for recovery from breaches and data losses (Recovery plan)
  • 33.
    Networks Networks Physical Structures: Type ofconnection Network: Two or more devices connected through links Link: Communication pathway that transfers data from one device two another Two devices must be connected in some way to the same link at the same time. Two possible types: • Point-to-Point • Multipoint
  • 34.
    Networks Networks Point-to-Point  Dedicated linkbetween two devices Entire capacity of the link is reserved for transmission between those two devices Use an actual length of wire or cable
  • 35.
    Networks Networks Point-to-Point  Other options, suchas microwave or satellite is possible Example: Television remote control
  • 36.
    Networks Networks Multipoint (multidrop)  Morethan two devices share a single link Capacity is shared Channel is shared either spatially or temporally  Spatially shared: if devices use link at same time  Timeshare: if users must take turns
  • 37.
    Networks Networks Physical Topology  Theway a network is laid out physically Two or more links form a topology The topology of a network is the geometric representation of the relationship of all the links and linking devices (nodes) to one another. Four topologies : Mesh, Star, Bus, and Ring
  • 38.
  • 39.
    Physical Topology Physical Topology Mesh Everylink is dedicated point-to-point link The term dedicated means that the link carries traffic only between the two devices it connects
  • 40.
    Physical Topology Physical Topology Mesh Tolink n n devices fully connected mesh has: n ( n - 1) / 2 n ( n - 1) / 2 physical channels (Full- Duplex) Every Device on the network must have n - 1 n - 1 ports
  • 41.
    Physical Topology Physical Topology Mesh Example: 8devices in mesh has links: n(n-1) / 2 number of links = 8 (8-1)/2 = 28 number of ports per device = n – 1 = 8 –1 = 7
  • 42.
    Physical Topology Physical Topology Mesh Advantages Eachconnection carry its own data load (no traffic problems) A mesh topology is robust Privacy or security Fault identification and fault isolation
  • 43.
    Physical Topology Physical Topology Mesh: Disadvantages Bigamount of cabling Big number of I/O ports Installation and reconnection are difficult Sheer bulk of the wiring can be greater than the available space Hardware connect to each I/O could be expensive Mesh topology is implemented in a limited fashion; e.g., as backbone of hybrid network
  • 44.
    Physical Topology Physical Topology Star: Dedicatedpoint-to-point to a central controller (Hub) No direct traffic between devices The control acts as an exchange
  • 45.
    Physical Topology Physical Topology Star Advantages Lessexpensive than mesh (1 Link + 1 port per device) Easy to install and reconfigure Less cabling Additions, moves, and deletions required one connection Robustness : one fail does not affect others Easy fault identification and fault isolation
  • 46.
    Physical Topology Physical Topology Star Disadvantages Dependencyof the whole topology on one single point (hub) More cabling than other topologies ( ring or bus) Used in LAN
  • 47.
    Physical Topology Physical Topology Bus Itis multipoint One long cable acts as a backbone Used in the design of early LANS, and Ethernet LANs
  • 48.
    Physical Topology Physical Topology Bus Nodesconnect to cable by drop lines and taps Signal travels along the backbone and some of its energy is transformed to heat Limit of number of taps and the distance between taps
  • 49.
    Physical Topology Physical Topology Bus Advantages Easeof installation Less cables than mesh, star topologies Disadvantages Difficult reconnection and fault isolation ( limit of taps) Adding new device requires modification of backbone Fault or break stops all transmission The damaged area reflects signals back in the direction of the origin, creating noise in both directions
  • 50.
    Physical Topology Physical Topology Ring Eachdevice has dedicated point-to-point connection with only the two devices on either side of it A signal is passed along the ring in one direction from device to device until it reaches its destination Each devices incorporates a Repeater
  • 51.
    Physical Topology Physical Topology Ring Advantages Easyof install and reconfigure Connect to immediate neighbors Move two connections for any moving (Add/Delete) Easy of fault isolation Disadvantage Unidirectional One broken device can disable the entire network. This weakness can be solved by using a dual ring or a switch capable of closing off the break
  • 52.
    Physical Topology Physical Topology HybridTopology Example: having a main star topology with each branch connecting several stations in a bus topology
  • 53.
    Categories of Networks Categoriesof Networks Network Category depends on its size Two primary categories LAN LAN: Covers area < 2miles WAN WAN: Can be worldwide MAN MAN: Between LAN & WAN, span 10s of miles
  • 54.
    Local Area Network(LAN) Local Area Network (LAN) Privately owned Links devices in the same office, building, or campus Simple LAN: 2 PCs & 1 printer in home or office Size is limited to a few kilometers Allow resources to be shared (hardware, software, or data)
  • 55.
    Local Area Network(LAN) Local Area Network (LAN) An isolated LAN connecting 12 computers to a hub in a closet
  • 56.
    Local Area Network(LAN) Local Area Network (LAN) LAN is distinguished by: Size (# users of OS, or licensing restrictions) Transmission medium (only one type) Topology (bus, ring, star) Data Rates (speed): Early: 4 to 16 Mbps Today: 100 to 1000 Mbps
  • 57.
    Wide Area Networks(WAN) Wide Area Networks (WAN) Provides long-distance transmission of data over large geographic areas (country, continent, world)
  • 58.
    Wide Area Networks(WAN) Wide Area Networks (WAN) Switched WAN Backbone of the Internet Dialup line point-to-point WAN Leased line from a telephone company
  • 59.
    Wide Area Networks(WAN) Wide Area Networks (WAN)
  • 60.
    Metropolitan Area Networks(MAN) Metropolitan Area Networks (MAN) Size between LAN and WAN Inside a town or a city Example: the part of the telephone company network that can provide a high-speed DSL to the customer
  • 61.
    Interconnection of Networks: Interconnectionof Networks: Internetworks Internetworks Two or more networks connected together
  • 62.
    The Internet The Internet Internethas revolutionized many aspects of our daily lives. It has affected the way we do business as well as the way we spend our leisure time. Internet is a communication system that has brought a wealth of information to our fingertips and organized it for our use An internet is 2 or more networks that can communicate with each other The Internet is a collaboration of more than hundreds of thousands of interconnected networks
  • 63.
    The Internet The Internet An internet (small i) is two or more networks  Notable internet is called the Internet (hundreds of thousands interconnected networks)  Private individuals + government agencies + school + research facilities + Corporations + libraries in more than 100 countries  This communication system came in 1969  Mid-1960 (ARPA) Advanced Research Projects Agency in (DOD) was interested to connect mainframes in research organizations  1967, ARPA presented its ideas for ARPANET  Host computer connecting to (IMP) interface message processor.  Each IMP communicate with other IMP  1969, four nodes (universities) connected via IMPs to form a network  Software (NCP) Network Control Protocol provided communication between the hosts.  1972, Vint Cerf and Bob Kahn invented (TCP) Transmission Control Protocol  Later TCP was split to (TCP) Transmission Control Protocol and (IP) Internetworking Protocol
  • 64.
    The Internet The Internet InternetToday Made of many LANs and WANs Every day new networks area added and removed Internet services Providers (ISPs) offer services to the end users International service providers National service providers Regional service providers Local service providers Data rate
  • 65.
    The Internet The Internet Hierarchicalorganization of the Internet
  • 66.
    Protocols and Standards Protocolsand Standards Protocol synonymous with rule Standards: agreed-upon rules Protocols A protocol is a set of rules that govern data communications Defines What, How, and When it is communicated
  • 67.
    Protocols and Standards Protocolsand Standards Elements of a protocol: Syntax: structure or format of data Example: 8-bits address of sender, 8-bits address of receiver Semantics: meaning of each section of bits Example: Does the address is a route to be taken or the final destination of the message Timing: when data should be sent and how fast they can be sent Example: sender produces data at 100 Mbps but the receiver can process data at only 1 Mbps  overload and data loose
  • 68.
    Standards Standards Essential in creatingand maintaining an open and competitive market for equipment manufactures Guaranteeing national and international interoperability of data and telecommunication technology and processes Providing guidelines to manufacturers, vendors, government agencies, and other service providers to ensure the kind of interconnectivity necessary in today’s marketplace and in international communications
  • 69.
    Standards Standards Two categories De facto:not approved by an organized body but adopted as standards through widespread use De jure: Legislated by an officially recognized body
  • 70.
    Standards Standards Standards are developedthrough the cooperation of: Standards Creation Committees ISO, ITU-T, CCITT, ANSI, IEEE, EIA Forums Created by special-interest groups Present their conclusions to the standards bodies Regulatory Agencies Ministry of Telecommunication and Information Technology (KSA) Purpose: Protecting the public by regulating radio, television, and communication
  • 71.
    Standards Standards Internet standards Tested thoroughlytested specification that is useful to be adhered to by those who work with the Internet Formalized regulation that must be followed Specification become Internet standard Begins as Internet draft for 6 months Upon recommendation from the Internet authorities draft published as Request for Comment (RFC) RFC is edited, assigned a number, and made available to all interested parties