Networking - PowerPoint PPT Presentation

1 / 64
About This Presentation
Title:

Networking

Description:

ADSL (Asymmetrical Digital Subscriber Line) Cable Modems. Local Loops ... ADSL (Asymmetrical Digital Subscriber Line) up to 8 Mbps ... – PowerPoint PPT presentation

Number of Views:51
Avg rating:3.0/5.0
Slides: 65
Provided by: N215
Category:

less

Transcript and Presenter's Notes

Title: Networking


1
Networking
  • WEEK 1-Wednesday
  • By
  • Norrima Mokhtar

2
Networking and Telecommunications.
  • The big picture of networking and
    telecommunications can be broken up according to
    its protocols into the following four areas
  • Local Loops
  • LANs
  • MANs
  • WANs

3
Local Loops
  • In telephony, the local loop (also referred to as
    a subscriber line) is the physical link or
    circuit, that connects from the point of the
    customer premises to the edge of the carrier, or
    telecommunications service provider, network.

4
(No Transcript)
5
Local Loops
  • The Local Loop is often called "the last mile",
    and it refers to the last mile of analog phone
    line that goes from the telephone company's
    central office (CO) to your house. Typical local
    loop protocols are
  • Voice lines
  • Modem connections
  • ISDN (Integrated Services Digital Network)
  • ADSL (Asymmetrical Digital Subscriber Line)
  • Cable Modems

6
Local Loops
  • Cable modems are not part of the local loop but
    do fall into the category of the last mile, or
    how high speed digital communication gets to the
    premises (home).
  • It would incredibly expensive to replace the
    existing cabling structure and because this
    cabling was designed for voice communications
    rather than digital, all of these protocols are
    needed to overcome the existing cabling
    limitations in the local loop and provide high
    speed digital data transmission.

7
Local Area Networks (LANS)
8
Local Area Networks (LANS)
  • LANs (local area networks) are networks that
    connect computers and resources together in a
    building or buildings that are close together.
  • The components used by LANs can be divided into
    cabling standards, hardware, and protocols.

9
Local Area Networks (LANS)
  • Examples of cabling standards used on LANs are
  • Ethernet cabling standards IEEE 802.3 (10Base5),
    IEEE 802.3a (10Base2),IEEE 802.3i (10BaseT)
  • Unshielded Twisted Pair (UTP)
  • Shielded Twisted Pair (STP)

10
Ethernet
  • Ethernet is a family of frame-based computer
    networking technologies for local area networks
    (LANs).
  • The name comes from the physical concept of the
    ether.
  • It defines a number of wiring and signaling
    standards for the physical layer, through means
    of network access at the Media Access Control
    (MAC)/Data Link Layer, and a common addressing
    format.
  • Ethernet is standardized as IEEE 802.3.
  • The combination of the twisted pair versions of
    Ethernet for connecting end systems to the
    network, along with the fiber optic versions for
    site backbones, is the most widespread wired LAN
    technology.
  • It has been in use from the 1990s to the present,
    largely replacing competing LAN standards such as
    token ring, FDDI, and ARCNET.
  • In recent years, Wi-Fi, the wireless LAN
    standardized by IEEE 802.11, is prevalent in home
    and small office networks and augmenting Ethernet
    in larger installations.

11
Twisted Pair Cabling
  • Twisted pair cabling is a form of wiring in which
    two conductors are wound together for the
    purposes of canceling out electromagnetic
    interference (EMI) from external sources,
    electromagnetic radiation from the UTP cable, and
    crosstalk between neighboring pairs.
  • Twisting wires decreases interference because the
    loop area between the wires (which determines the
    magnetic coupling into the signal) is reduced.
  • In balanced pair operation, the two wires
    typically carry equal and opposite signals
    (differential mode) which are combined by
    addition at the destination.
  • The common-mode noise from the two wires (mostly)
    cancel each other in this addition because the
    two wires have similar amounts of EMI that are
    180 degrees out of phase.
  • This results in the same effect as subtraction.
    Differential mode also reduces electromagnetic
    radiation from the cable, along with the
    attenuation that it causes.

12
Shielded Twisted Pair (STP)
  • Shielded twisted pair is a special kind of copper
    telephone wiring used in some business
    installations. An outer covering or shield is
    added to the ordinary twisted pair telephone
    wires the shield functions as a ground.

13
Unshielded Twisted Pair (UTP)
  • The more common kind of wire that is installed to
    your home is unshielded twisted pair.

14
(No Transcript)
15
(No Transcript)
16
(No Transcript)
17
UTP
18
LANS Connectors
  • RJ45
  • RJ11
  • Hermaphroditic connectors
  • RS-232
  • BNC

19
LANs connectors
20
(No Transcript)
21
RJ11
  • RJ11 is a physical interface often used for
    terminating telephone wires. It is probably the
    most familiar of the registered jacks, being used
    for single line POTS(Plain old telephone service)
    telephone jacks in most homes and offices in
    North America and many other countries.

22
RJ11
23
  • The RJ45 network connector and the RJ11 look
    superficially alike, but the RJ11 has only four
    leads (or contacts) whereas the RJ45 has eight.
  • In computer systems, the RJ11 is used primarily
    for connecting to modems.
  • There are many different adapters for RJ11
    connectors, because telephone ports vary widely
    from country to country.

24
RJ11
25
Hermaphroditic Connector for fiber optic cables
26
RS232
  • In telecommunications, RS-232 (Recommended
    Standard 232) is a standard for serial binary
    data signals connecting between a DTE (Data
    terminal equipment) and a DCE (Data
    Circuit-terminating Equipment).
  • It is commonly used in computer serial ports. A
    similar ITU-T standard is V.24.

27
RS232
  • Serial, full-duplex communication port with
    maximal 115200kb/s transfer rate.
  • Used to connect external modems, mice and various
    specialized electronic devices like PLCs or
    meters.

28
(No Transcript)
29
(No Transcript)
30
LANs protocols
31
(No Transcript)
32
(No Transcript)
33
(No Transcript)
34
(No Transcript)
35
(No Transcript)
36
(No Transcript)
37
(No Transcript)
38
(No Transcript)
39
(No Transcript)
40
MANs
  • Metropolitan Area Networks (MANs) are networks
    that connect LANs together within a city.

41
MANs
  • A Metropolitan Area Network is a system of LANs
    connected throughout a city or metropolitan area.
  • MANs have the requirement of using
    telecommunication media such as voice channels or
    data channels.
  • Branch offices are connected to head offices
    through MANs.
  • Examples of organizations that use MANs are
    universities and colleges, grocery chains, and
    banks.

42
MANs
  • It may be a single network such as a cable
    television network, or it may be a means of
    connecting a number of LANs into a larger network
    so that resources may be shared LAN-to-LAN as
    well as device-to-device.
  • A MAN may be wholly owned and operated by a
    private company, or it may be a service provided
    by a public company, such as a local telephone
    company.
  • Many telephone companies provide a popular MAN
    service called Switched Multi-megabit Data
    Services (SMDS).

43
Examples of MAN protocols are
  • RS232, V35
  • X.25 (56kbps), PADs
  • Frame Relay (up to 45 Mbps), FRADs
  • Asynchronous Transfer Mode (ATM)
  • ISDN (Integrated Services Digital Network) PRI
    and BRI
  • Dedicated T1 lines (1.544 Mbps) and Fractional
    T1
  • T3 (45 Mbps) and OC3 lines (155 Mbps)
  • ADSL (Asymmetrical Digital Subscriber Line) up
    to 8 Mbps
  • XDSL (many different types of Digital Subscriber
    Lines)

44
Metropolitan-Area Network Services
                                              
                                  
45
(No Transcript)
46
WANs
  • Wide Area Networks (WANs) connect LANs together
    between cities.
  • The main difference between a MAN and a WAN is
    that the WAN uses Long Distance Carriers.
    Otherwise the same protocols and equipment are
    used as a MAN.

47
(No Transcript)
48
WANs
  • In contrast to LANs (which depend on their own
    hardware for transmission), WANs may utilize
    public, leased, or private communication devices,
    usually in combinations, and can therefore span
    an unlimited number of miles.
  • A WAN that is wholly owned and used by a single
    company is often referred to as an enterprise
    network.

49
Criteria for Classification of Computer Network
  • The following are the characteristics used to
    classify different types of computer networks
  • Topology
  • Topology is nothing but the geometric management
    of positioning computer systems to involve them
    in the form of a network. For example, Star
    topology, Bus topology, etc.
  • Protocol
  • The protocols are nothing but the set of rules
    and signals that are used for communication in
    the network. For example, 'Ethernet' is one of
    the most popular protocols for LANs.
  • Architecture
  • Networks can usually be classified in the
    following two types -
  • Peer-to-peer architecture.
  • Client-Server architecture.

50
NETWORK TOPOLOGIES
  • The term topology refers to the way a network is
    laid out, either physically or logically.
  • Two or more devices connect to a link 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 (usually called nodes)
    to each other.
  • There are five basic topologies possible mesh,
    star, tree, bus, and ring.

51
Multipoint Line Configuration
52
Categories of Topologies
53
NETWORK TOPOLOGIES
  • These five labels describe how the devices in a
    network are interconnected rather than their
    physical arrangement.
  • For example, having a star topology does not mean
    that all of the computers in the network must be
    placed physically around a hub in a star shape.
  • A consideration when choosing a topology is the
    relative status of the devices be linked. Two
    relationships are possible peer-to-peer, where
    the devices share the link equally, and
    primary-secondary, where one device controls
    traffic and the others must transmit through it.
  • Ring and mesh topologies are more convenient for
    peer-to-peer transmission, while star and tree
    are more convenient for primary-secondary, bus
    topology is equally convenient for either.

54
Mesh
  • In a mesh topology, every device has a dedicated
    point-to-point link to every other device.
  • The term dedicated means that the link carries
    traffic only between the two devices it connects.
  • A fully connected mesh network therefore has n(n
    - l)/2 physical channels to link n devices.
  • To accommodate that many links, every device on
    the network must have 7 input/output (I/O) ports.

55
(No Transcript)
56
Star
  • In a star topology, each device has a dedicated
    point-to-point link only to a central controller,
    usually called a hub.
  • The devices are not directly linked to each
    other.
  • Unlike a mesh topology, a star topology does not
    allow direct traffic between devices.
  • The controller acts as an exchange. If one device
    wants to send data to another, it sends the data
    to the controller, which then relays the data to
    the other connected device.

57
(No Transcript)
58
Tree
  • A tree topology is a variation of a star. As in a
    star, nodes in a tree are linked to a central hub
    that controls the traffic to the network.
  • However, not every device plugs directly into the
    central hub.
  • The majority of devices connect to a secondary
    hub that in turn is connected to the central hub.
  • The central hub in the tree is an active hub. An
    active hub contains a repeater, which is a
    hardware device that regenerates the received bit
    patterns before sending them out.
  • Repeating strengthens trans- missions and
    increases the distance a signal can travel.

59
(No Transcript)
60
Bus
  • The preceding examples all describe
    point-to-point configurations. A bus topology, on
    the other hand, is multipoint. One long cable
    acts as a backbone to link all the devices in the
    network.
  • Nodes are connected to the bus cable by drop
    lines and taps. A drop line is a connection
    running between the device and the main cable. A
    tap is a connector that either splices into the
    main cable or punctures the sheathing of a cable
    to create a contact with the metallic core.
  • As a signal travels along the backbone, some of
    its energy is transformed into heat. Therefore,
    it becomes weaker and weaker the farther it has
    to travel.
  • For this reason there is a limit on the number of
    taps a bus can support and on the distance
    between those taps.

61
(No Transcript)
62
Ring
  • In a ring topology, each device has a dedicated
    point-to-point line configuration only with 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 device in the ring
    incorporates a repeater.
  • When a device receives a signal intended for
    another device, its repeater regenerates the bits
    and passes them along.

63
(No Transcript)
64
Tutorial
  • Give four main protocols in Networking.
  • What is Local Loop?
  • What is LANs?
  • What is MANs?
  • What is WANs?
  • Gives and explain types of network topology?
Write a Comment
User Comments (0)
About PowerShow.com