Silica optical fiber technology for devices and components design, fabrication, and international standards
From basic physics to new products, Silica Optical Fiber Technology for Device and Components examines all aspects of specialty optical fibers. Moreover, the inclusion of the latest international standards governing optical fibers enables you to move from research to fabrication to commercialization...
| Otros Autores: | , |
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| Formato: | Libro electrónico |
| Idioma: | Inglés |
| Publicado: |
Hoboken, New Jersey :
Wiley
2012.
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| Edición: | 1st edition |
| Colección: | Wiley series in microwave and optical engineering.
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| Materias: | |
| Ver en Biblioteca Universitat Ramon Llull: | https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009628263806719 |
Tabla de Contenidos:
- Silica Optical Fiber Technology for Devices and Components: Design, Fabrication, and International Standards; Contents; Preface; Acknowledgment; 1 Introduction; 1.1 Brief Historical Review of Silica Optical Fibers; 1.2 International Standards for Silica Optical Fibers; 1.3 Classifications of Silica Optical Fibers; References; 2 Review on Single-Mode Fiber Design and International Standards; 2.1 Optical Modes in Cylindrical Waveguides; 2.2 Material Dispersion in Optical Fibers; 2.3 Optical Attributes for Single-Mode Fiber Characterization and Classification
- 2.4 International Standards for Single-Mode FibersReferences; 3 Preform Fabrication and Optical Fiber Drawing Process; 3.1 Preform Fabrication Based on Chemical Vapor Deposition Process; 3.2 Postprocesses for Geometrical Modification of Preform; 3.3 Optical Fiber Drawing; References; 4 Dispersion-Managed Single-Mode Fibers for Wavelength Division Multiplexing; 4.1 Wavelength Allocations in Single-Mode Fibers for WDM Applications; 4.2 Optimization of Waveguide Parameters for Dispersion Control; 4.3 Refractive Index Profile Analysis for Dispersion-Shifted Fibers
- 4.4 Dispersion-Compensating Fibers Using the Fundamental Mode4.5 Dispersion Compensation Using High-Order Modes; References; 5 Multimode Fibers for Large-Bandwidth Applications; 5.1 History and Recent Application Trends of Multimode Optical Fibers; 5.2 Principle of Multimode Optical Fiber Design; 5.3 Impacts of Nonideal α-Refractive Index Profile on Transmission Bandwidth; 5.4 Main Attributes of GI-MMFs-Bandwidth and Differential Modal Delay; 5.5 Multimode Optical Fiber Standards; References; 6 Optical Nonlinearity Control in Optical Fibers
- 6.1 Historical Review of Optical Nonlinearity in Optical Fibers6.2 Origin of Optical Nonlinearities in Optical Fibers; 6.3 Specifications of Nonlinear Optical Processes in Optical Fibers; 6.4 Comparison of Raman and Brillouin Scattering in Single-Mode Optical Fibers; 6.5 Control of Raman Scattering in Silica Optical Fibers; 6.6 Brief Review on Raman Amplifiers and Lasers; 6.7 Control of Brillouin Scattering in Silica Optical Fibers; 6.8 Review on Fiber Brillouin Sensors and Recent Novel Applications; References; 7 Birefringence Control in Optical Fibers
- 7.1 Physical Parameters for the Polarization Characterization in Optical Fibers7.2 Representation of the State of Polarization in Optical Fiber Using Poincaré Sphere; 7.3 Classifications of Linear Polarization Maintaining Fibers; 7.4 Fabrication Methods for High Birefringence Fibers; 7.5 Control of Birefringence by Waveguide Design in Birefringent Fibers; 7.6 Single-Polarization Single-Mode Fibers; 7.7 Low Linear Birefringence Fibers; References; 8 Optical Fibers Based on Air-Silica Guiding Structure; 8.1 Review of Air-Silica Guidance in Optical Fibers
- 8.2 Fabrication Technique-Stack and Draw Method
