UID:
almahu_9948025719702882
Format:
1 online resource (479 p.)
ISBN:
1-281-03313-8
,
9786611033132
,
0-08-050627-5
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0-585-47053-7
Series Statement:
Optics and photonics
Content:
Optical fibers have revolutionized telecommunication, becoming the most widely used and the most efficient device for relaying information over long distances. While the market for optical fiber continues to grow, the next stage in the field of communication is the mass delivery of integrated services, such as home banking, shopping, internet services, and entertainment using video on demand. The economies and performance potential will determine the type of technology likely to succeed in the provision of these services. But it is already clear that optical fibers will play a crucial role in
Note:
Description based upon print version of record.
,
Front Cover; Fiber Bragg Gratings; Copyright Page; Contents; Preface; Chapter 1. Introduction; 1.1 Historical perspective; 1.2 Materials for glass fibers; 1.3 Origins of the refractive index of glass; 1.4 Overview of chapters; References; Chapter 2. Photosensitivity and Photosensitization of Optical Fibers; 2.1 Photorefractivity and photosensitivity; 2.2 Defects in glass; 2.3 Detection of defects; 2.4 Photosensitization techniques; 2.5 Densification and stress in fibers; 2.6 Summary of photosensitive mechanisms in germanosilicate fibers; 2.7 Summary of routes to photosentization
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Chapter 3. Fabrication of Bragg Gratings3.1 Methods for fiber Bragg grating fabrication; 3.2 Type II gratings; 3.3 Type IIA gratings; 3.4 Sources for holographic writing of gratings; Chapter 4. Theory of Fiber Bragg Gratings; 4.1 Wave Propagation; 4.2 Coupled-mode theory; 4.3 Coupling of counterpropagating guided modes; 4.4 Codirectional coupling; 4.5 Polarization couplers: Rocking filters; 4.6 Properties of uniform Bragg gratings; 4.7 Radiation mode couplers; 4.8 Grating simulation; 4.9 Multilayer analysis; Chapter 5. Apodization of Fiber Gratings; 5.1 Apodization shading functions
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5.2 Basic principles and methodology5.3 Fabrication requirements for apodization and chirp; References; Chapter 6. Fiber Grating Band-pass Filters; 6.1 Distributed feedback, Fabry-Perot, superstructures, and moiré gratings; 6.2 The Fabry-Perot and moiré band-pass filters; 6.3 The Michelson interferometer band-pass filter; 6.4 The Mach-Zehnder interferometer band-pass filter; 6.5 The optical circulator based OADM; 6.6 The polarizing beam splitter band-pass filter; 6.7 In-coupler Bragg grating filters; 6.8 Side-tap and long-period grating band-pass filters
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6.9 Polarization rocking band-pass filter6.10 Mode converters; References; Chapter 7. Chirped Fiber Bragg Gratings; 7.1 General characteristics of chirped gratings; 7.2 Chirped and step-chirped gratings; 7.3 Super-step-chirped gratings; 7.4 Polarization mode dispersion in chirped gratings; 7.5 Systems measurements with DCGs; 7.6 Other applications of chirped gratings; References; Chapter 8. Fiber Grating Lasers and Amplifiers; 8.1 Fiber grating semiconductor lasers: The FGSL; 8.2 Static and dynamic properties of FGLs; 8.3 The fiber Bragg grating rare-earth-doped fiber laser
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8.4 Erbium-doped fiber lasers8.5 The distributed feedback fiber laser; 8.6 Bragg grating based pulsed sources; 8.7 Fiber grating resonant Raman amplifiers; 8.8 Gain-flattening and clamping in fiber amplifiers; Chapter 9. Measurement and Characterization of Gratings; 9.1 Measurement of reflection and transmission spectra of Bragg gratings; 9.2 Perfect Bragg gratings; 9.3 Phase and temporal response of Bragg gratings; 9.4 Strength, annealing, and lifetime of gratings; References; Index; Optics and Photonics (Formerly Quantum Electronics)
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English
Additional Edition:
ISBN 0-12-400560-8
Language:
English
