Five components of data communication. Figure 3.1.A Transmission medium and physical layer Tx media...
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Transcript of Five components of data communication. Figure 3.1.A Transmission medium and physical layer Tx media...
Five components of data communication
Figure 3.1.A Transmission medium and physical layer
Tx media is located below physical layer and is controlled by it.
So Tx media can be said to belong to layer zero. Tx media is anything that can carry info from src to dst
in form of EM signal.
Figure 3.1.B Classes of transmission media
3.1 GUIDED MEDIA
Guided media, which are those that provide a conduit from one device to another . The signal is directed and contained by physical limits of the medium . Metallic media carries signal in form of electric current while optical media in the form of light.
Twisted-Pair CableCoaxial CableFiber-Optic Cable
Topics discussed in this section:
http://www.youtube.com/watch?v=hjVNKeVdKcs&list=PL374944B232C0B48E
Figure 3.1.1 Twisted-pair cable
Two wires : one for signal and one for reference or ground.
Insulator to avoid shorting of lines . Why twists?
How many twists?
Noise affects both lines eqally thus at Rx the effectof noise gets cancelled.
Number of twists per unit length decides the quality of cable.
Figure 3.1.2 UTP and STP cables
Unshielded is more in use . Shielded is by IBM . seldom used outside IBM. STP has metal braided mesh to prevent noise and
crosstalk, but bulkier & expensive.
Table 3.1.1 Categories of unshielded twisted-pair cables by EIA
Figure 3.1.3 UTP performance
Figure 3.1.4 UTP connector
RJ stands for registered jack. Has 8 lines. Used in LAN RJ11 has 2 lines , used in land telephone system.
It carries higher freq than TP Outer conductor has two functions: protection from noise &
complete the circuit.
Figure 3.1.5 Coaxial cable
RG : radio govt ratings. Specifies wire gauge , type of insulator, size of casing etc.
Table 3.1.2 Categories of coaxial cables
BNC: Bayone-Neill –concelman Three types: connector to extend , T connector for taps &
terminator What is the need of terminator?
Figure 3.1.6 BNC connectors
To prevent reflection of signal else it works as antenna
Figure 3.1.7 Coaxial cable performance
Applications: 1) Was used in analog telephone networks( to carry 1000 voice channels, then for digital telephone networks ( upto 600Mbps) But now replaced by FOC2) Cable TV networks also used co-ax , but there also replaced by FOC3) Ethernet LAN( Thin 10 base2 10Mbps over 200 meters , Thick 10base5 10Mbps over 500mtr) but here also it replaced by UTP
Optical fiber
Is made of glass or plastic ( glass is costlier than plastic but better quality).
Transmits signal in form of light.
Light travels stright in single uniform substance , but when enters into different density material, the ray changes direction.
As long as angle of incidence (I) is less than or equal to critical angle , ray gets refracted, if greater then it gets reflected.
Figure 3.1.8 Bending of light ray
Analogy : throwing a flat stone piece in water
Cladding has less density than core
Figure 3.1.9Optical fiber
Figure 3.1.10 Propagation modes of transmission of light in FOC
Figure 3.1.11 Modes
Multi-mode fiber Named because multiple beams from light source move
through core in different paths. Fiber with large core diameter (greater than 10
micrometers) Divided in two sub types : step and graded index. Step Index : where density changes abruptly . So rays get reflected suddenly Graded index : where density changes gradually, So rays
get reflected smoothly.
Single mode fiber: The most common type of single-mode fiber has a core
diameter of 8–10 micrometers and is designed for use in the near infrared
Uses highly focused light , (laser), and propagation of beam almost horizontal.
All beams arrive at Rx together , so least distortion as compared to multimode.
But most costly
Acceptance angle Is the maximum angle ,within which all light rays having
angle less than this ,will get reflected internally.
Table 3.1.3 Fiber types
Figure 3.1.11 Fiber construction
The structure of a typical single-mode fiber.1. Core: 8 µm diameter2. Cladding: 125 µm dia.3. Buffer: 250 µm dia.4. Jacket: 400 µm dia.
Figure 3.1.12 Fiber-optic cable connectors
Subscriber channel Straight tip
Attenuation per Km is very less as compared to UTP and co-ax, so requires less no. of ( 10 times less) repeaters .
Figure 3.1.13 Optical fiber performance
Advantages of FOC: Higher BW limited only because of transducers at the ends. Less signal attenuation: repeater after 50Km Immunity to EM interference : since propagation by light Glass is not corrosive but copper Light weight Immunity to tapping : copper cable acts as antenna Disadvantages of FOC: Expensive installation and maintenance: expertise required Unidirectional light propagation: so for duplex two FOCs
required. Cost: costlier cable and interfaces Requires additional devices at both ends to convert electric
signal to light and light back to electric signal . To convert electric signal to light : 1) LED 2) Laser diode To convert light to electric signal : 1) PIN photodiode
2) PiPN Avalanche diode
1) LED
2) LASER diode
1)PIN photodiode
2) PiPN Avalanche