Specialty optical fibers handbook
This book is a comprehensive contributed volume that aims to describe and explain the design, fabrication, operating characteristics, and specific applications of the most popular and useful types of specialty optical fibers. These "specialty fibers? include any kind of optical fiber that has b...
| Other Authors: | , |
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| Format: | eBook |
| Language: | Inglés |
| Published: |
Oxford :
Academic Press
2007.
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| Edition: | 1st edition |
| Subjects: | |
| See on Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009627343806719 |
Table of Contents:
- Front Cover; Specialty Optical Fibers Handbook; Copyright Page; Dedication; Contents; Editors; List of Contributors; Preface; Chapter 1: Specialty Optical Fiber Market Overview; 1.1 Market Overview; 1.1.1 Production Versus Consumption; 1.1.2 Rapidly Growing Need to Use Fiber Optic Sensors; 1.1.3 Weapon System Development; 1.1.4 100-1000 X Improvements in Performance; 1.1.5 High Cost of Functionality; 1.1.6 Multiple Features in the Same Specialty Fibers; 1.2 Specialty Optical Fibers: A Few Selected Examples; 1.2.1 Fluoride Fiber; 1.2.2 Tellurite Fiber; 1.2.3 Bismuth-Doped Fiber
- 1.2.4 Polarizing Fiber1.2.5 Photonic Crystal Fiber-Holey Fibers; 1.2.6 Dispersion-Compensating Fiber; 1.2.7 High-Index Fiber; 1.2.8 Polarization-Maintaining Fiber; 1.2.9 Photosensitive Fiber; 1.2.10 Erbium-Doped Fiber; 1.3 Conclusions; Chapter 2: Light-Guiding Fundamentals and Fiber Design; 2.1 Introduction; 2.2 Physical Structure of a Telecommunications Optical Fiber; 2.3 Linear Lightwave Propagation in an Optical Fiber; 2.3.1 Electromagnetic Preliminaries; 2.3.2 Intuition from the Slab Waveguide; 2.3.3 Optical Fiber: A Cylindrical Waveguide; 2.3.4 The Linearly Polarized Mode Set LPlm
- 2.3.5 Finite Element Analysis for Waveguide Calculations2.4 Working Definitions of Cutoff Wavelength; 2.4.1 Introduction; 2.4.2 Theoretical Cutoff Wavelength; 2.4.3 Effective Cutoff Wavelengths; 2.5 Impact of Profile Design on Macrobending Losses; 2.5.1 The Depressed Cladding Fiber Design; 2.5.2 Phenomenology of Macrobending Loss; 2.6 Fiber Attenuation Loss; 2.7 Origins of Chromatic Dispersion; 2.7.1 Introduction; 2.7.2 Material Dispersion; 2.7.3 Waveguide Dispersion; 2.8 Polarization Mode Dispersion; 2.8.1 Overview; 2.8.2 Background; 2.8.3 Modeling and Simulation
- 2.8.4 Control of PMD in Fiber Manufacturing2.8.5 Measurement of PMD; 2.8.6 Fiber-to-Cable-to-Field PMD Mapping; 2.9 Microbending Loss; 2.9.1 Microbending; 2.10 Fiber Nonlinearities; 2.10.1 Overview; 2.10.2 Background; References; Chapter 3: Overview of Materials and Fabrication Technologies; 3.1 Double-Crucible Technique; 3.2 Vapor-Deposition Techniques; 3.3 Outside Vapor Deposition; 3.4 Vertical Axial Deposition; 3.5 Direct Nanoparticle Deposition; 3.6 Modified Chemical Vapor Deposition; 3.6.1 Chemical Equilibria: Dopant Incorporation; 3.6.2 Purification from Hydroxyl Contamination
- 3.6.3 Thermophoresis3.7 Plasma Chemical Vapor Deposition; 3.8 Sol-Gel Processes; 3.8.1 Alkoxide Sol-Gel Processing; 3.8.2 Colloidal Sol-Gel Processing; 3.9 Sol-Gel Microstructure Fiber Fabrication; 3.10 Fiber Drawing; Acknowledgments; References; Chapter 4: Optical Fiber Coatings; 4.1 Introduction; 4.2 Early History of Coatings for Optical Fiber; 4.3 Evolution of Optical Fibers and Protective Coatings; 4.3.1 Coating Contributions to Microbending Minimization; 4.3.2 Glass Fiber Fracture Mechanics and Coating Contributions to Fiber Strength Retention; 4.3.3 Durability of Fiber Optic Coatings
- 4.4 Cabling of Optical Fibers
