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Progress in optical fibers / Peter S. Emersone edited.

Contributor(s): Material type: TextTextPublisher: Hauppauge, NY : Nova Science Publishers, c2011Description: 1 online resourceContent type:
  • text
Media type:
  • computer
Carrier type:
  • online resource
ISBN:
  • 9781622570027
  • 1622570022
Subject(s): Genre/Form: Additional physical formats: Print version:: Progress in optical fibersDDC classification:
  • 621.36/92 22
LOC classification:
  • QC448
Online resources:
Contents:
PROGRESS IN OPTICAL FIBERS ; PROGRESS IN OPTICAL FIBERS ; CONTENTS ; PREFACE ; RESEARCH AND REVIEW STUDIES; INTEGRATED OPTICAL RING RESONATORS: MODELLING AND TECHNOLOGIES ; Abstract ; 1. Introduction ; 2. Modelling ; 2.1. Transfer Matrix Approach ; 2.2. Bidirectional Model ; 2.3. Z-Transform Based Model ; 2.3. Time-Dependent Model ; 2.5. Modelling Based on FDTD ; 3. Technologies ; 3.1. Silica-on-Silicon Technology ; 3.2. Glass Technology ; 3.3. Lithium Niobate Technology; 3.4. Polymer Technology ; 3.5. SiON, Si3N4 and Sin Technologies ; 3.6. SOI Technology.
3.7. III-V Semiconductors Technology 4. Conclusion ; Acknowledgements ; References ; VCSEL RESONATORS; Abstract ; Introduction ; The Model; The (GaIn)(NAs)/GaAs Quantum Well ; The (GaIn)(NAsSb)/Ga(NAs) Quantum Well ; The Electrical Model ; The Optical Model ; The Thermal Model ; The Gain Model ; Interactions between Individual Physical Phenomena ; Oxide-Confined 1.3- M GaAs-Based VCSELs [41] ; VCSEL with a Single Oxide Aperture ; VCSELs with Two Oxide Apertures ; Oxide-Confined 1.5- M GaAs-Based VCSELs ; Conclusion ; Acknowledgments ; References.
MICROSTUB RESONATORS BASED-WAVEGUIDES FORFILTERING AND MULTIPLEXING DEVICESAbstract; Introduction; 1. Geometrical Parameters and Method of Calculation; 2. Rejective Filter; 2.1. Effect of the Metallization of the Stub; 2.2. Effects of the Geometrical Parameters; 2.3. Improvement of the Quality Factor; 2.4. Symmetric Wave Excitation; 2.5. Three Dimensional Structure; 2.6. Application to the Near Optical Regime; 3. Selective Filter; 4. Bent Y-Branch Waveguide; 4.1. Y-Branch Rejective Filter; 4.2. Y-Branch Selective Filter; Conclusion; References.
DEVELOPMENT OF RAIN AND SCINTILLATIONMODELS AT KU-BAND IN SOUTHEAST ASIATROPICAL COUNTRIESAbstract; Chapter 1. Introduction; 1.1. Background; 1.2. Objectives of the Research; 1.3. Organization of the Thesis; Chapter 2. Rainfall And Scintillation Models; 2.1. Introduction; 2.2. The Importance of Rainfall Rate; 2.3. Rainfall in Tropical and Equatorial Regions; 2.4. Prediction of Rainfall Attenuation Using Rainfall Rate; 2.4.1. Prediction of Rainfall Attenuation Using Equiprobability Method; 2.5. Prediction of Tropospheric Scintillation; 2.5.1. Theory of Tropospheric Scintillation.
2.5.2. Theory of Turbulence-Induced Scintillation2.5.3. Description of Scintillation Effects; 2.6. Conversion of Rainfall Rate from Sixty-Minutes to One-Minute; 2.6.1. Segal's Method; 2.6.2. Burgueno's Method; 2.6.3. Chebil and Rahman's Method; 2.6.4. Joo's Method; 2.6.5. Moupfouma's Method; 2.7. One-Minute Rainfall Rates Models; 2.7.1. Dutton and Dougherty Rainfall Rate Model; 2.7.2. KIT (Kitami Institute of Technology) Simplified Rainfall Rate Model; 2.7.3. Morita Rainfall Rate Model; 2.7.4. Moupfouma (Refined) Rainfall Rate Model; 2.7.5. Rice and Holmberg Rainfall Rate Model.
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Includes bibliographical reference index.

Description based on print version record.

Includes bibliographical references and index.

English.

PROGRESS IN OPTICAL FIBERS ; PROGRESS IN OPTICAL FIBERS ; CONTENTS ; PREFACE ; RESEARCH AND REVIEW STUDIES; INTEGRATED OPTICAL RING RESONATORS: MODELLING AND TECHNOLOGIES ; Abstract ; 1. Introduction ; 2. Modelling ; 2.1. Transfer Matrix Approach ; 2.2. Bidirectional Model ; 2.3. Z-Transform Based Model ; 2.3. Time-Dependent Model ; 2.5. Modelling Based on FDTD ; 3. Technologies ; 3.1. Silica-on-Silicon Technology ; 3.2. Glass Technology ; 3.3. Lithium Niobate Technology; 3.4. Polymer Technology ; 3.5. SiON, Si3N4 and Sin Technologies ; 3.6. SOI Technology.

3.7. III-V Semiconductors Technology 4. Conclusion ; Acknowledgements ; References ; VCSEL RESONATORS; Abstract ; Introduction ; The Model; The (GaIn)(NAs)/GaAs Quantum Well ; The (GaIn)(NAsSb)/Ga(NAs) Quantum Well ; The Electrical Model ; The Optical Model ; The Thermal Model ; The Gain Model ; Interactions between Individual Physical Phenomena ; Oxide-Confined 1.3- M GaAs-Based VCSELs [41] ; VCSEL with a Single Oxide Aperture ; VCSELs with Two Oxide Apertures ; Oxide-Confined 1.5- M GaAs-Based VCSELs ; Conclusion ; Acknowledgments ; References.

MICROSTUB RESONATORS BASED-WAVEGUIDES FORFILTERING AND MULTIPLEXING DEVICESAbstract; Introduction; 1. Geometrical Parameters and Method of Calculation; 2. Rejective Filter; 2.1. Effect of the Metallization of the Stub; 2.2. Effects of the Geometrical Parameters; 2.3. Improvement of the Quality Factor; 2.4. Symmetric Wave Excitation; 2.5. Three Dimensional Structure; 2.6. Application to the Near Optical Regime; 3. Selective Filter; 4. Bent Y-Branch Waveguide; 4.1. Y-Branch Rejective Filter; 4.2. Y-Branch Selective Filter; Conclusion; References.

DEVELOPMENT OF RAIN AND SCINTILLATIONMODELS AT KU-BAND IN SOUTHEAST ASIATROPICAL COUNTRIESAbstract; Chapter 1. Introduction; 1.1. Background; 1.2. Objectives of the Research; 1.3. Organization of the Thesis; Chapter 2. Rainfall And Scintillation Models; 2.1. Introduction; 2.2. The Importance of Rainfall Rate; 2.3. Rainfall in Tropical and Equatorial Regions; 2.4. Prediction of Rainfall Attenuation Using Rainfall Rate; 2.4.1. Prediction of Rainfall Attenuation Using Equiprobability Method; 2.5. Prediction of Tropospheric Scintillation; 2.5.1. Theory of Tropospheric Scintillation.

2.5.2. Theory of Turbulence-Induced Scintillation2.5.3. Description of Scintillation Effects; 2.6. Conversion of Rainfall Rate from Sixty-Minutes to One-Minute; 2.6.1. Segal's Method; 2.6.2. Burgueno's Method; 2.6.3. Chebil and Rahman's Method; 2.6.4. Joo's Method; 2.6.5. Moupfouma's Method; 2.7. One-Minute Rainfall Rates Models; 2.7.1. Dutton and Dougherty Rainfall Rate Model; 2.7.2. KIT (Kitami Institute of Technology) Simplified Rainfall Rate Model; 2.7.3. Morita Rainfall Rate Model; 2.7.4. Moupfouma (Refined) Rainfall Rate Model; 2.7.5. Rice and Holmberg Rainfall Rate Model.

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