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Features
- This unique free application is for all students across the world. It covers 226 topics of Optical Fiber Communication in detail. These 226 topics are divided in 5 units.
- Each topic is around 600 words and is complete with diagrams, equations and other forms of graphical representations along with simple text explaining the concept in detail.
- This USP of this application is "ultra-portability". Students can access the content on-the-go from anywhere they like.
- Basically, each topic is like a detailed flash card and will make the lives of students simpler and easier.
- Some of topics Covered in this application are:
- 1. Historical development
- 2. Optical fiber communication system
- 3. Advantages of optical fiber communication
- 4. Ray Model
- 5. Attenuation
- 6. Carrier recombination:
- 7. Absorption
- 8. Linear scattering losses
- 9. Nonlinear scattering losses
- 10. Fiber bend loss
- 11. Dispersion
- 12. Overall fiber dispersion
- 13. Dispersion-modified single-mode fibers
- 14. Polarization
- 15. Nonlinear effects
- 16. Soliton propagation
- 17. Optical fiber splices
- 18. Optical connectors
- 19. Cylindrical ferrule connectors
- 20. Duplex and multiple-fiber connectors
- 21. Expanded beam connectors
- 22. GRIN-rod lenses
- 23. Fiber couplers
- 24. Three- and four-port couplers
- 25. Star couplers
- 26. Wavelength division multiplexing couplers
- 27. Optical isolators and circulators
- 28. Optical spectral filters
- 29. Wavelength Interference filter de-multiplexers
- 30. GRIN-rod lensed band-pass de-multiplexer
- 31. Interaction length
- 32. Fiber Bragg grating (FBG)
- 33. Arrayed waveguide grating (AWG)
- 34. "Constructive interference "
- 35. Optical add/drop wavelength multiplexer using FBG
- 36. Optical Source
- 37. Laser action- General principles
- 38. The Einstein relations
- 39. Population inversion
- 40. Optical feedback and laser oscillation
- 41. Threshold condition for laser oscillation
- 42. Optical emission from semiconductors
- 43. Spontaneous emission
- 44. Other radiative recombination processes
- 45. Stimulated emission
- 46. Heterojunctions
- 47. The semiconductor injection laser
- 48. Stripe geometry of Injection laser
- 49. Laser modes in injection laser
- 50. Single-mode operation of the Injection laser
- 51. Gain-guided lasers
- 52. Index-guided lasers
- 53. Quantum-well lasers
- 54. Quantum-dot laser
- 55. Single-frequency injection lasers
- 56. Injection laser characteristics
- 57. Injection laser to fiber coupling
- 58. The Nd: YAG laser
- 59. Glass fiber lasers
- 60. Mid-infrared and far-infrared lasers
- 61. Long external cavity lasers
- 62. Fiber lasers
- 63. Integrated external cavity lasers
- 64. LED as Optical Source
- 65. LED power and efficiency
- 66. LED structures
- 67. LED characteristics
- 68. Optical detectors
- 69. Optical detection principles
- 70. P-N-Photodiodes
- 71. Absorption
- 72. Direct and indirect absorption: silicon and germanium
- 73. The PIN photodiode
- 74. Traveling-wave photodiodes
- 75. Unitraveling carrier (UTC) photodiode
- 76. Resonant cavity enhanced photodiode
- 77. Noise in PIN Photodiode
- 78. Avalanche photodiodes
- 79. Silicon avalanche photodiodes
- 80. Germanium avalanche photodiodes
- 81. IIIV alloy avalanche photodiodes
- 82. Benefits and drawbacks with the avalanche photodiode
- 83. Quantum-dot photodetectors
- 84. Phototransistors
- 85. Waveguide phototransistors
- 86. Metal – semiconductor - metal photodetectors
- 87. Noise
- 88. Receiver noise
- 89. Receiver capacitance and bandwidth
- 90. Excess avalanche noise factor
- 91. Gain-bandwidth product
- 92. Receiver structures
- 93. FET preamplifiers
- 94. High-performance receivers
- 95. PIN - FET hybrid receivers
- 96. Optical amplifiers
- 97. Semiconductor Optical Amplifiers
- 98. Characteristics for semiconductor optical amplifiers
- 99. Performance characteristics of SOA
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