computer networks chapter 7 – transmission media
TRANSCRIPT
Computer Networks
Chapter 7 – Transmission Media
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Transmission Media Categories
The transmission medium is the physical path between the transmitter and receiver in a data transmission system
The nature of both, the signal and the medium determines the quality of transmission
The media can be divided into two categories: Guided media – physical medium exists Unguided media – the air is used as a
medium
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Twisted-Pair Cable
Insulated copper wires in spiral pattern. Widely used for analog and digital transmission One of the wires transmits the signal, the other is used as
ground reference The twist is introduced to reduce the interference
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Twisted Pair Cable - Applications
Most common medium for many applications Telephone network Between house and local exchange
(subscriber loop) Within buildings To private branch exchange (PBX) For local area computer networks, 10Mbps or
100Mbps, or 1000Mbps
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Unshielded vs. Shielded Twisted Pair Cable
Unshielded Twisted Pair (UTP) Ordinary telephone wire Cheapest Easiest to install Suffers from external electrical and
mechanical interference Shielded Twisted Pair (STP)
Metal braid or sheathing that reduces interference
More expensive Harder to handle (thick, heavy)
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UTP Categories
Category 3 up to 16MHz Voice grade found in most offices Used with 10BaseT, IBM Token ring; Arc Net
Category 4 up to 20 MHz, the use is same as Cat 3
Category 5 up to 100MHz Commonly pre-installed in new office buildings Used with 10BaseT, Fast Ethernet, Gigabit
Ethernet, ATM
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UTP Categories-cont.
Category 5E (enhanced) Up to 100MHz, similar use as Cat 5,
Category 6 Up to 250 MHz, similar use as Cat 5 Lower attenuation and longer distances
than Cat. 5 Category 6E – enhanced Cat 6 Category 7 (draft)
Up to 600 MHz Used for high speed transmissions
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UTP Connectors
Standard – RJ45 Can be inserted in
only one way Easy to manipulate
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Performance of UTP
The attenuation depends on how thick the conductors are and the frequency at which is used
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Coaxial Cable
Central core conductor, enclosed within an insulator sheath which is encased by an outer conductor covered by outer sheath.
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Coaxial Cable - Applications
Television distribution Cable TV (RG-59) Lately, only the last part is kept, the rest is
replaced by fiber Long distance telephone transmission
Can carry 10,000 voice calls simultaneously Being replaced by fiber optic
Short distance computer systems links Local area networks, 10Base2 (RG-58),
10Base5 (RG-11) Obsolete (rarely used today)
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Coaxial Cable - Connectors
The most common connectors used with coaxial cable are BNC connectors Ordinary BNC
connector to connect a single wire
T BNC connector – to connect two wires
BNC terminator – to terminate the end of the wire
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Coaxial Cable - Performance
Analog Amplifiers every few km Closer if higher frequency Up to 500MHz
Digital Repeaters every 1km Closer for higher data rates
The performance depends on the diameter of the cable and the frequency used
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Fiber-Optic Cable
Consists of three components: the light source (laser or light emiting diode) the medium (ultra-thin fiber of glass) the detector (generates electric pulse when
light falls on it) Light pulses sent down a fiber spread out
in length as they propagate. The attenuation of light through glass
depends on the wavelength of the light (0.85, 1.30 and 1.55 micron are used for communication)
Wavelength l = c/f , c is the speed of light
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Fiber-Optic Cable - Structure
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Optical Fiber - Transmission Characteristics
Act as wave guide for 1014 to 1015 Hz Portions of infrared and visible spectrum
Light Emitting Diode (LED) Cheaper Wider operating temperature range Last longer
Injection Laser Diode (ILD) More efficient Greater data rate
Wavelength Division Multiplexing
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Wavelength Division Multiplex (WDM)
Fiber 1 spectrum
Fiber 2 spectrum
Spectrum on the shared fiber
Shared fiber
Fiber 1
Fiber 2Fiber 3
Fiber 4
Prism Prism
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Fiber-Optic Cable – Propagation Modes
The density of the core remains constant from the center to the edges
The density of the core varies from the center to the edges
Uses step-index fiber and highly focused source of light
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Fiber-Optic Cable - Connectors
Common connectors
ST- used in cable TV
SC – used in computer networks
MT-RJ – a new connector with a size of RJ-45
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Fiber-Optic Cable - Characteristics
Advantages Greater capacity (data rates of hundreds of Gbps Smaller size & weight (easier to put in the ground than
cooper cables) Lower attenuation Electromagnetic isolation (not susceptible to electric
interference) Greater repeater spacing (10s of km at least)
Disadvantages High cost Difficult and expensive to install and maintain Light is unidirectional – one cable needed for each
direction
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Fiber –Optic Cable - Applications
Used with wavelength division multiplex (WDM) for long distance transmission of voice channels and data signals
Cable TV Local Area Networks, 100Base FX,
(Fast Ethernet) and 1000Base X (Gigabit Ethernet)
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Electromagnetic Waves in the Air
Besides through guided media, electromagnetic waves can spread through the atmosphere and outer space
Hz 104 108 1012 1016 1022
RadioMicrowaveInfrared UV X-ray Gamma ray
Visible light
Frequency spectrum of electromagnetic waves
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Wireless Transmission
Wireless transmission is used in all types of Wireless communication Mobile devices Satellite communication
The frequencies used by the signal and the power of the signal are most important for this type of transmission Frequencies 3KHz to 1 GHz are usually
called radio waves Frequencies between 1 and 300 GHz are
called microwaves
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Antennas Antennas are used for both, transmission
and reception of wireless signals To exchange information the antennas need to
be tuned to the same frequency
Two types of antennas Omnidirectional Directional
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Wireless Spectrum
Radio waves Micro waves
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Problems with Wireless Transmission
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Radio Waves
At low frequency, radio waves pass through obstacles well, but the power falls off sharply with distance (AM radio)
At high frequency, radio waves tend to travel in streight lines and bounce off obstacles
At all frequencies radio waves are subject to inerference from electrical equipment
The governments license the users of radio transmitters
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Radio Waves (cont.)
Radio waves are omnidirectional Signal spreads in all directions Can be received by many antennae Convenient for broadcasting
Frequencies used 30MHz to 1GHz
Applications Radio, Television and Paging systems
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Microwaves
Microwaves are unidirectional Focused beam Careful alignment required
Frequencies used 2GHz to 40GHz
Applications Wireless LANs, Satellite communication
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Infrared Transmission
A short range communication system – one room
Line of sight must be provided Frequencies used
3 x 1011 to 2 x 1014 Hz Application
PC-to-PC short range transmission
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Spread Spectrum
A type of wireless transmission in which signals are distributed over several frequencies simultaneously Developed to provide secure wireless
transmission (for military purposes) Used in wireless LAN to reduce
propagation effects (multi-path interference and others due to the higher frequencies)
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Satellite Microwave
Microwave onto which the data is modulated is transmitted to the satelite from the ground
Satellite receives on one frequency, amplifies or repeats the signal and transmits it back to earth using on board circuit known as transponder.
A typical satelite channel has extremely high bandwidth (500 MHz)
Satelites for communication purposes require geo-stationary orbit (Height of 35,784km)
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Satellites
A single satellite usually contains multiple transponders (typically 6-12)
Each transponder consists of a radio receiver and transmitter and uses a different radio frequency (i.e., channel) Multiple communications can proceed simultaneously
and independently
The degree of collimation of the microwave beem can be: coarse, so that the signal can be picked in a large
geografic area focused, so that it can be picked up over a limited
area
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Geosynchronous Satellites
Place in an orbit that is exactly synchronized with the rotation of the earth Geostationary Earth Orbit (GEO)
Distance required for geosynchronous orbit is 36,000 km or 20,000 miles.
The entire 360-degree circle above the equator can only hold 45-90 satellites. This is because satellites need to be
separated to avoid interference
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Network Connection accross an Ocean via Satelite
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Application of Satelites
Television Long distance telephone Private business networks Internet when there is no other
connection
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Satelites vs. Fiber
Satelite advantages: Sites that are not connected can easily use
the satelite by installing a ground station
Satelite disadvantages: Very large propagation delay (due to big
distances) Very low security Quality of transmission can become
questionable due to external influences