Computer Networks Transmission Media. Transmission Medium Physical path b/w transmitter and receiver...
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Transcript of Computer Networks Transmission Media. Transmission Medium Physical path b/w transmitter and receiver...
![Page 1: Computer Networks Transmission Media. Transmission Medium Physical path b/w transmitter and receiver Exists in two forms Guided – Wire, Optical Fiber.](https://reader031.fdocuments.us/reader031/viewer/2022032523/56649d935503460f94a7a70c/html5/thumbnails/1.jpg)
Computer Networks
Transmission Media
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Transmission Medium
Physical path b/w transmitter and receiver Exists in two forms
Guided – Wire, Optical Fiber Un-Guided – Wireless
Characteristics and quality determined by medium & signal In Guided: Medium is more important In Unguided: Bandwidth produced by antenna is more important
Key concerns are data rate and distance
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Design Factors
Number of design factors related to transmission medium and signal determine data rate and distance: Bandwidth
Greater the bandwidth, higher data rates could be achieved (if other factors remain constant)
Transmission Impairments Impairments like attenuation limit the distance
Interference E.g. EMI Competing signals in overlapping frequency bands may distort or
wipe out a signal Number of Receivers
In Guided Media Link may be P-to-P or multipoint In multipoint, more the number of attachments, more
attenuation/distortion, limiting the distance/data rate
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Electromagnetic Spectrum for Telecommunication
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Guided Media
Provide a Transfer Path from one device to another
Include Twisted Pair Cable Coaxial Cable Fiber Optic Cable
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Twisted Pair Cable
Least Expensive Easy to install Disadvantage:
Works in short range Support low data rate (at least now this is not the case)
Most widely used guided transmission medium Physically, twisted pair cable consists of two insulated copper wires
arranged in a regular spiral pattern ‘Pair’ is a single communication link
Number of pairs could be wrapped together in a tough shield Twisting the cable
Reduces crosstalk interference among adjacent pairs In bundled pairs
Different pairs have separate twist length Copper thickness is 0.4 – 0.9mm
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Twisted Pair Cable
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Twisted Pair Cable – Applications Telephone network
Subscriber loop; house and local exchange Within Buildings
Private Branch Exchanges (PBX) 64Kbps
Local Area Networks Traditionally 10Mbps but now 100Mbps and
1Gbps are also common
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Twisted Pair Cable – Transmission Characteristics Can transmit both analog & digital signal
For analog requires amplifier every 5 – 6 KM For Digital requires repeater every 2 – 3 KM
Limited Distance Limited Bandwidth (Traditionally 1MHz)
Now improved up to 200MHz Limited Data rate (Traditionally 10Mbps)
Now supports Gbps Susceptible to interference & noise
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Twisted Pair Cable – Types
Twisted Pair Cable comes in two varieties Unshielded Twisted Pair Cable (UTP)
Ordinary telephone wire Cheapest Easiest to install Suffers from external EM interference
Shielded Twisted Pair Cable (STP) Metal braid or sheathing that reduces interference More expensive Hard to handle (thick, heavy)
Read Variety of Twisted Pair Categories e.g. Cat 3, Cat 4, Cat 5 etc Find out difference at characteristics, physical and
operational levels
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Twisted Pair Cable – Types
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Twisted Pair Connectors (For LAN)
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Near End Crosstalk in Twisted Pair Cable Coupling of signal from one pair to another Occurs when transmit signal entering the link
couples back to receiving pair Near transmitted signal is picked up by near
receiving pair At connector level From neighbor pair
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Coaxial Cable
Versatile Medium Television Distribution
Ariel to TV Cable to TV
Previously used for long distance telephone transmission Now replaced by Fiber Optic Theoretically, can carry up to 10,000 calls simultaneously
Also used for Short Distance Computer links
LAN
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Coaxial Cable
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Coaxial Cable
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Coaxial Cable – Transmission Characteristics Can transmit both Digital and Analog Signals Have superior frequency characteristics than twisted
pair so could be used for high frequencies and data rates
Shielded, Concentric Construction Less susceptible to interference and crosstalk
Analog Signals Amplify every few kilometers Usable spectrum: up to 500MHz
Digital Signals Repeater every 1KM
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Categories of Coaxial Cable
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Coaxial Cable Connectors
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Quiz
Although you may feel that coaxial has several advantages over twisted pair, yet twisted pair is getting more popularity in different types of installations particularly networks (specially LAN) What is the reason behind it?
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Assignment 2
How to connect two PC using point-to-point and multipoint configuration Write in brief and focus on your own experience/problems faced
How to make up straight, cross and console/roll over cables Write the configuration/scheme you followed No need to submit cables but bring those on submission day so
that cables could be tested What are the differences/improvements made in different
categories of twisted pair cables SUBMIT it as a brief report
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Optical Fiber
Thin (2–125µm), flexible guided medium uses optical ray to transmit data
Offer greater capacity Data rates of several Gbps
Smaller size and weight Lower attenuation Electromagnetic isolation Support longer distances
Repeaters required after 10s of KM
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Optical Fiber – Parts
Three concentric sections: Core
Inner most section More dense than cladding One or more very thin (width of hair, 8–100µm) strands/fiber made of
glass/plastic Very pure material
Cladding Less refractive Glass/plastic coating around core Optical property different than core Reflect the light back into the core that tries to escape
Jacket Protects against moisture, abrasion, crushing and other damages May be bundling a number of fibers
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Optical Fiber – Parts
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Optical Fiber – Parts
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Optical Fiber – Operation
The light travels into the core, produced by Light Emitting Diode (LED) of ILD (Injection Laser Diode)
While passing through the core, if the light gets out of core, cladding around the core reflects it back inside the core
Wavelength Multiplexing: Lights differ in wavelength Different lights could be sent in a single fiber and
could be distinguished distinctly at the receiver
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Fiber Optic – Operation
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Total Internal Reflection
Light that is reflected back from the edge of the medium it is traveling through; When light rays travel at an angle greater than the "critical" angle, which is determined by the medium, the light reflects back into the medium. If less than the critical angle (more perpendicular), the light is refracted out of the medium and lost to the outside
The reflection that occurs when light, in a higher refractive-index medium, strikes an interface, with a medium with a lower refractive index, at an angle of incidence (with respect to the normal) greater than the critical angle
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Total Internal Reflection
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Fiber Optic – Transmission Characteristics Act as wave guide for 1014 to 1015 Hz frequencies
Portions of infrared and visible spectrum Light rays created through LED or ILD Light Emitting Diode (LED)
Cheaper Wider operating temp range Last longer
Injection Laser Diode (ILD) More efficient Greater data rate
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Fiber Optic – Pros
Greater Capacity Hundreds of Gbps
Smaller size & weight Less expensive for long length installations Lower attenuation Low power requirements Non-Flammable (no short-circuit hazards) Electromagnetic Isolation Greater Repeater Spacing
10s of KM at least
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Fiber Optic – Cons
Installation! Maintenance is also difficult Cost Specialized Equipment and operating
Personnel Uni-directional Propagation
Light from one side can travel in a fiber Solution: Two fibers could be used
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Fiber Optic – Applications
Long haul trunks 1500 KM, 20 – 60 thousand voice channels
Metropolitan trunks 12 KM, 100,000 voice channels
Rural exchange trunks 400 – 60 KM, 5000 channels
Subscriber loop Replacing STP/UTP and Coaxial
LAN
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Fiber Optic – Transmission Modes Two modes of light propagation
Multimode Step Index Graded-index
Single mode Different modes operate on fiber bearing
different characteristics
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Fiber Optic – Transmission Modes
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Fiber Optic – Transmission Modes Multimode
Multiple beams from source to destination Two types
Step Index Graded Index
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Multimode: Step Index Density of core is constant from center to edges Abrupt changes due to sudden density change with cladding Rays which hit will less than critical angle penetrate (although
very less in number) Other rays are reflected back Different rays have different angles of reflections in a single core Beams with small angle of incidence would face more bounces
till it reaches the other end Distortion and attenuation problems
Sudden/abrupt change of direction due to total internal reflection Today used only by POF (Plastic Optic Fiber)
Fiber Optic – Transmission Modes
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Fiber Optic – Transmission Modes
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Fiber Optic – Transmission Modes Multimode: Graded Index
Density of core varies from center to edges Center is more dense while density increases towards edges
Smooth change in density reflect rays back smoothly Low Distortion
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Fiber Optic – Transmission Modes Single Mode
Uses fiber like step index Density of core is constant
Very small diameter fiber Approximately the size of wavelength of light which will travel
across it Employs highly focused light
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Fiber Optic – Transmission Modes
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Fiber Optic – Connectors
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Un-Guided Media
Unguided media transport electromagnetic waves without using a physical conductor
Usually referred to as Wireless Communication Three ranges of frequencies are of our interest 30MHz – 1GHz
Radio 1GHz – 40GHz
Microwaves 3x1011 – 2x1014 Hz
Infrared
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Unguided Media
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Electromagnetic Spectrum for Wireless Communication
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Antenna
For unguided media, transmission and reception are achieved by means of antenna
Antenna is an electrical conductor/system of conductors used either for radiating electromagnetic energy or for collecting electromagnetic energy For transmission, conversion of electromagnetic energy
into radiation for traveling in surroundings and vice versa in reception
Both transmission and reception is normally done by same antenna in two-way communication
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Types of Antennas
Two Common types Omni-Directional Antenna
An antenna which radiate power equally in all directions Usually not possible Isotropic antenna is assumed which radiate power
equally in all directions Actual radiation pattern for the isotropic antenna is a
sphere with antenna at the center Directional Antenna
Further Different Types Parabolic Reflective Antenna Highly Directional Antenna etc
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Types of Antenna
Directional Antenna (Cont) Parabolic
Uses parabolic dish All the points on the dish are equidistant from a single point
known as FOCUS of the parabola If a source of electromagnetic energy is placed at the focus
(considering paraboloid as reflecting surface) the waves will bounce back to the axis of paraboloid
Larger the diameter of antenna, more tightly directional is the beam
On reception, all the waves that fall on the paraboloid are concentrated at focus
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Types of Directional Antenna
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Antenna Gain
Measure of Efficiency of Antenna Measure of Directionality of Antenna
More an antenna is directional towards its target, more would be its gain
It is one of the yardstick to select antennas for different purposes
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Wireless Propagation
Signal radiated from antenna travels along one of three routes Ground ware Propagation Sky Wave Propagation Line of Sight Propagation
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Wireless Propagation
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Frequency Bands Vs Propagation and Use
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Wireless Propagation
Ground Wave Propagation Follows almost the contour of earth Uses frequencies up to 2MHz Several factors involved in such movement
Electromagnetic wave induces current in the earth surface, causes the wave-front to tilt downward and travel over the earth curvature
These waves are scattered by atmosphere in such a way that they do not penetrate the upper atmosphere
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Wireless Propagation
Sky Propagation Used for amateur radio Signal from earth-based antenna is reflected from the
ionized layer of the upper atmosphere (ionosphere) back down to earth Happens due to Refraction: Change in the density/medium
while the wave travel from earth to the height Signal can take many bounces while moving from
transmitter to receiver This causes the signal to be picked up even after
thousands of kilometers from the transmitter (ideally)
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Wireless Propagation
Line of Sight Propagation Above 30MHz, neither ground nor sky wave
propagation mode operate Communication takes place on Line of Sight basis High frequency signal is not reflected by the
ionosphere so signal can travel from an earth station to satellite
For ground based communication, both the antennas must be within Effective LOS Microwaves Bent due to refraction
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Microwave Communication
Microwave communication takes place somewhere in 1 – 40GHz band of electromagnetic spectrum
Keep in mind that bigger the frequency used, higher would be the bandwidth and potentially higher data rates would be offered
But also notice that bigger frequencies have to face more attenuation problems and are more prone to several types of interferences
Assignment of frequency band is strictly regulated to be used for different purposes
Two General Types of Microwave Communication Terrestrial Microwave Satellite Microwave
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Microwave – Terrestrial Communication Usually uses parabolic dish antenna or other
directional antennas Sending & Receiving antennas are rigidly fixed and
focused towards each-other to use a narrow beam in LOS transmission
Antennas are usually fixed at heights to extend range b/w them and to avoid obstacles
These point-to-point links may be cascaded for multiple times for prolonged communication links
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Microwave – Terrestrial Communication: Application Long haul telecommunication service
Alternative to coaxial and fiber since require less repeaters and is easy to install but requires line of sight
May be used as Short Haul To connect two buildings in the same city To have wireless internet connection from some
ISP
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Microwave – Terrestrial Communication: Transmission Characteristics Most common band for long-haul
telecommunications are 4 – 6GHz Congested
11GHz band is in use now For Short Range (Connecting Two Buildings)
22GHz band is utilized Attenuation is not problem in short distances
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Microwave – Satellite
Satellite is a microwave relay station Links two or more ground stations Satellite receives transmission on one frequency,
may amplify, and transmits on another frequency For effective functionality, a satellite is required to
remain stationary w.r.t its position over earth In other case, it will lose the line of sight to its earth stations
To accomplish this goal, satellite must have a rotation period equal to earth Match occurs at height of 35,863Km of equator
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Microwave – Common Satellite Configuration
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Microwave – Limitation in Satellite Two satellites using same frequency band
will interfere with each other if they come closer
To avoid 40 spacing b/w satellites is required in 4/6GHz
Band (Measured from earth) 30 spacing is required in 12/14GHz Band
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Microwave – Satellite Applications Television Distribution Long Distant Telephone
Transmission Private Business Networks
VSAT (Very Small Aperture Terminal)
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Microwave – Satellite Transmission Characteristics Optimum Frequency range
1 – 10GHz Remember: Low frequency for longer distances, higher
attenuate Below 1GHz, lot of noises from natural sources
Most P-t-P satellites today use 5.925 – 6.425GHz for Upload and 3.7 – 4.2GHz for download Combination is called 4/6 Band
Transmission and Reception frequencies differ Otherwise interference will occur
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Microwave – Satellite Transmission Characteristics 4/6GHz Band is in optimum zone but got saturated Other bands with 1 – 10GHz are not available
because of interferences Usually terrestrial devices operate on those
12/14GHz band is developed Uplink: 14 – 14.5GHz Downlink: 11.7 – 12.2GHz
It is expected that 12/14GHz band will also saturate shortly so 20/30GHz band is proposed
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Broadcast Radio Communication Main difference in Microwave and Radio is
that Microwave is usually directional while radio is omni-directional
Radio Doesn’t require dish-shaped antennas Doesn’t need antennas to be mounted accurately
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Radio – Application
“Radio” term illustrate frequencies from 3KHz to 300GHz in general
Broadcast Radio is an informal term to cover FM, VHF and part of UHF i.e. 30MHz to 1GHz
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Broadcast Radio – Transmission Characteristics 30MHz band is transparent to Ionosphere LOS is required for communication Frequency used is less than employed by
microwaves so the signal faces less attenuation Ideal for broadcast transmission
Impairments are usually caused by Multi-path
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Infrared Communication
Requires LOS May use reflected surface in the absence of LOS
Infrared cannot transfer through walls Microwave can!
More secure Communication in closed environments could not
be hacked from outside No Licensing required since no frequency
allocation issue
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Problems
Free Space Loss Multi-path Refraction
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Free Space Loss
Signal disperses with distance Signal becomes weaker as distance b/w
antennas increase For satellite it is the main cause of signal loss
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Multi-Path
For Wireless Communication, LOS is preferred and mostly required
In other cases like mobile telephony, obstacles are there
Signals can be reflected back from such obstacles and receiver may receive multiple copies of same signals with varying delays
In extreme cases, there may be no direct signal
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Multi-Path
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Refraction
Radio Waves refract/bent while traveling through atmosphere
Caused by changes in speed of signal with altitude or by spatial changes in atmospheric conditions
Speed of signal increases with altitude but bents downwards
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Assignment 3
What is IEEE802.x Write about IEEE Focus on 802 Standards defined under 802 Umbrella