session-1 (int to optical fibre).ppt
TRANSCRIPT
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History of Optical Communication
? Hand signals, Flags and Smoke Signals
? Light Transmission through bent water jet
1000 Nature of light was defined and laws of reflection given
1880 Photo Phone by A.G. Bell
1962 Laser diode
1966 Idea of optical fiber for communication by Kao & Hock ham
1970 Chemical vapor deposition(VCD) < 20 db/ Km by Corning
1973 MCVD <1 db/Km by Bell Systems
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1977 VAD < 0.4 db/Km @ 1300 nm by NTT & SEI
1980 Introduction of actual optical technology
1986 < 0.2 db/Km @ 1550 nm
1987 Photonic regenerators introduced
1988 British Telecom.
1990 O.F used in the long distance network
History of Optical Communication
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Nature of Light and Laser
Nature of Light Short Wave
White Light
Coherent Light (Waves)
In-Coherent Light (Waves)
Laser
Stimulated Emission
Maximum Acceptance Angle on Optical Fiber
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Frequency Spectrum
Radio Waves
Micro Waves
Infrared (Wave length > 0.7 micro meter)
Visible (0.4 (blue) to 0.7(red) micro meter)
Ultra Violet (< 0.4 micro meter)
Optical frequencies for Optical Fiber Transmission
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Basic Optical Fiber System
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TRANSMISSION CHARACTERISTICS OF OFC
Normalized Frequency Windows of Optical Fiber. Bandwidth Coupling Efficiency
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Construction of single Fiber
Core
Cladding
Jacket
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Types of Optical Fiber on profile
• Types with respect to Modes: Single Mode Fiber Multimode Fiber
• Types with respect to Index Profile: Step Index Graded Index
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Fiber versus copper
Glass• Uses light
• Transparent
• Dielectric material nonconductive
• EMI immune
• Low thermal expansion
• Brittle, rigid material
• Chemically stable
Copper• Uses electricity
• Opaque
• Electrically conductive material
• Susceptible to EMI
• High thermal expansion
• Ductile material
• Subject to corrosion and galvanic reactions
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Index of Refraction
It is the ratio of the speed of light through a medium to the speed of light through vacuum.
gIndex of refraction (n) = cV
V
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Index of Refraction
It is equal to the sine of the angle of incidence divided by the sine of the angle of
refraction.
Index of refraction (n) = sin isin r
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Refractive Indices
MATERIAL
VACCUM
AIR
MERCURY VAPOUR
WATER
GLASS
DIAMOND
INDEX OF REFRACTION
1.0000
1.0003
1.0009
1.3
1.6
2.4
Selected indices of refraction
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Optical Fiber Transmission System
• Optical Transmitter:Produces and encodes the light signal.
• Optical Amplifier:May be necessary to boost the light signal (for long distance)
• Optical Receiver:Receives and decodes the light signal
• Optical Fiber:Conducts the light signal over a distance
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Optical Transmitter
• Function:Electrical to optical converter
• Types:Light Emitting Diode (LED)
Laser Diode (LD)
• Comparison:Item LED LD
Data rate Low High
Mode Multimode Multimode/Single mode
Distance short long
Temp sensitivity
minor substantial
cost low expensive