Fundamentals of Optical Fibers (Wiley Series in Pure and Applied Optics)/ (Record no. 176702)
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fixed length control field | 00359nam a2200121Ia 4500 |
040 ## - CATALOGING SOURCE | |
Transcribing agency | CUS |
082 ## - DEWEY DECIMAL CLASSIFICATION NUMBER | |
Classification number | 621.3692 |
Item number | BUC/F |
100 ## - MAIN ENTRY--PERSONAL NAME | |
Personal name | Buck, John A. |
245 #0 - TITLE STATEMENT | |
Title | Fundamentals of Optical Fibers (Wiley Series in Pure and Applied Optics)/ |
Statement of responsibility, etc. | John A.Buck, |
260 ## - PUBLICATION, DISTRIBUTION, ETC. (IMPRINT) | |
Name of publisher, distributor, etc. | Wiley-Interscience, |
Date of publication, distribution, etc. | 2004 |
300 ## - PHYSICAL DESCRIPTION | |
Extent | 352p. |
505 ## - FORMATTED CONTENTS NOTE | |
Formatted contents note | <br/>Chapter 1. Selected Topics in Electromagnetic Wave Propagation<br/>1.1. Maxwell's Equations and the Fundamental Fields 1<br/>1.2. Electromagnetic Wave Propagation in Sourceless Media 2<br/>1.2.1. Wave Equations in Simple Media 3<br/>1.2.2. Time-Harmonic Field Solutions 3<br/>1.2.3. Vector Helmholtz Equations and the Uniform<br/>Plane Wave<br/>1.2.4. E and H as Related Through the Intrinsic Impedance 5<br/>1.3. Power Transmission ^<br/>1.3.1. Computation of the Time-Average Power Density 6<br/>1.3.2. Standing Wave Power 7<br/>1.4. Group Velocity ^<br/>1.4.1. Propagation of a Wave Containing Two Frequencies 8<br/>1.4.2. Group Velocity Definition 9<br/>1.5. Reflection and Transmission of Waves at Plane Interfaces 10<br/>1.5.1. Reflection Geometry 10<br/>1.5.2. Applying the Field Boundary Conditions 11<br/>1.5.3. Special Cases: Total Transmission and Total Reflection 13<br/>1.6. Material Resonances and Their Effects on Wave Propagation 13<br/>1.6.1. The Classical Electron Oscillator Model and the Electric<br/>Susceptibility<br/>1.6.2. Wave Propagation in Media with Complex<br/>Susceptibilities<br/>1.6.3. Off-Resonance Behavior and the Sellmeier Equation 18<br/>1.6.4. Time Domain Analysis 18<br/>Problems<br/>91<br/>References<br/>Chapter2. Symmetric Dielectric Slab Waveguides 22<br/>2.1. Ray Analysis of the Slab Waveguide 22<br/>2.1.1. Guided Mode Requirements and Mode Types 23<br/>2.1.2. Plane Wave Field Representations 25<br/>2.1.3. Surface Waves and the Reflective Phase Shift 26<br/>2.1.4. Transverse Resonance and the Eigenvalue Equations 28CONTENTS<br/>2.2. Field Analy.si.s of the Slab Waveguide 29<br/>2.2.1. Solving for the Longitudinal Field Components 29<br/>2.2.2. Obtaining the Transverse Field Components 31<br/>2.3. Solutions of the Eigenvalue Equations 32<br/>2.3.1. Graphical Solution Method 32<br/>2.3.2. Interpreting the Graphical Solution 33<br/>2.4. Power Transmission and Confinement 34<br/>2.4.1. Power Computation and the Confinement Factor 35<br/>2.4.2. Mode Orthogonality 35<br/>2.5. Leaky Waves 35<br/>2.5.1. TE and TM Polarization 38<br/>2.5.2. Power Loss in Leaky Wave Transmission 38<br/>2.6. Radiation Modes 40<br/>2.6.1. Physical Description of Radiation Modes 40<br/>2.6.2. Summary of Wave Types 41<br/>2.7. Wave Propagation in Curved Slab Waveguides 42<br/>2.7.1. Basic Concepts of Curved Guiding 42<br/>2.7.2. Criteria for Small Curvature Loss 43<br/>2.7.3. Analysis of Curved Slab Waveguides Through<br/>Conformal Transformation 44<br/>Problems 47<br/>References 50<br/>Chapter3. Weakly-Guiding Fibers with Step Index Profiles 51<br/>3.1. Rays and Fields in the Step Index Fiber 53<br/>3.1.1. Ray Trajectories and Transverse Resonance 53<br/>3.1.2. Relations Between Ray Paths and Mode Field Patterns 55<br/>3.1.3. Weakly Guiding Fibers and the LP Modes 55<br/>3.2. Field Analysis of the Weakly Guiding Fiber 56<br/>3.2.1. Assumed Field Solutions and Wave Equations for LP<br/>Modes 56<br/>3.2.2. Solving the Wave Equation 57<br/>3.2.3. Evalifating the Coefficients 59<br/>3.3. Eigenvalue Equation for LP Modes 60<br/>3.3.1. Derivation of the Eigenvalue Equation 60<br/>3.3.2. Graphical Solution Method 62<br/>3.3.3. Cutoff Conditions and Mode Designations 65<br/>3.4. LP Mode Characteristics 66<br/>3.4.1. Intensity Patterns and Polarizations 66<br/>3.4.2. Parameter Computation 69<br/>3.4.3. Power Confinement 71<br/>3.5. Single-Mode Fiber Parameters 73<br/>3.5.1. Cutoff Wavelength 73<br/>3.5.2. Gaussian Approximation for the LPoi Mode Field 75CONTENTS ix<br/>3.6. Derivation of the General Step Index Fiber Fields 79<br/>3.6.1. Mode Field Derivation 80<br/>3.6.2. Mode Classification and the Eigenvalue Equation 81<br/>3.6.3. The Eigenvalue Equation Under the Weak-Guidance<br/>Approximation 82<br/>3.6.4. General Mode Fields Under the Weak-Guidance<br/>Approximation 84<br/>3.6.5. LP Modes as Superpositions of General Modes 85<br/>Problems 87<br/>References 90<br/>Chapter4. Loss Mechanisms in Silica Fiber 92<br/>4.1. Basic Loss Effects in Transmission 93<br/>4.2. Fabrication of Silica Fibers 94<br/>4.2.1. Perform Manufacturing Using MCVD 94<br/>4.2.2. Dopants for Control of Refractive Index 95<br/>4.2.3. Perform Completion and Fiber Drawing 96<br/>4.3. Intrinsic Loss 97<br/>4.3.1. Ultraviolet Absorption 97<br/>4.3.2. Infrared Absorption 97<br/>4.3.3. Rayleigh Scattering 98<br/>4.3.4. Combined Intrinsic Losses 100<br/>4.4. Extrinsic Loss 101<br/>4.4.1. Metallic and Rare Earth Impurities 101<br/>4.4.2. Loss Arising from OH 102<br/>4.5. Bending Loss 103<br/>4.5.1. Wave Theory of Macrobending Loss 104<br/>4.5.2. Additional Factors That Influence Macrobending Loss 108<br/>4.5.3. Microbending Loss 109<br/>4.6. Source-to-Fiber Coupling 112<br/>4.6.1. Single-Mode Fiber Splicing 113<br/>4.6.2. Gaussian Beam Input Coupling 115<br/>4.6.3. General Source Coupling to Multimode Fiber 117<br/>4.6.4. Imaging Methods in Extended-Source Coupling 119<br/>Problems ' 120<br/>References 122<br/>Chapters. Dispersion 125<br/>5.1. Pulse Propagation in Media Possessing Quadratic Dispersion 126<br/>5.1.1. Propagation ofTransform-Limited Gaussian Pulses 126<br/>5.1.2. Input Pulses with Initial Chirp 131<br/>5.1.3. Gaussian Pulses Having Excess Bandwidth 133<br/>5.1.4. Characterizing Arbitrarily Shaped Pulses 134<br/>5.1.5. Cubic Dispersion 136* CONTENTS<br/>5.2. Material Di.spersion 138<br/>5.2.1. Group Delay and Group Index 138<br/>5.2.2. Di.spersion Parameter I4I<br/>5.2.3. Wavelength Domain Description of Cubic Dispersion 142<br/>5.3. Di.spersion in Optical Fiber 145<br/>5.3.1. Group Delay in Step-Index Fiber 145<br/>5.3.2. Group Dispersion in Single-Mode Fiber 149<br/>5.4. Chromatic Dispersion Compensation 153<br/>5.4.1. Dispersion-Compensating Fiber 153<br/>5.4.2. Gires-Tournois Interferometer 154<br/>5.4.3. Chirped Fiber Bragg Grating 159<br/>5.5. Polarization Dispersion 161<br/>5.5.1. Wave Polarization in Single-Mode Fiber 162<br/>5.5.2. Differential Group Delay and Polarization Mode<br/>Dispersion in the Intrinsic Regime 164<br/>5.5.3. Polarization Mode Di.sper.sion in the Coupled Regime 166<br/>5.6. System Considerations and Di.spersion Mea.surement 172<br/>5.6.1. Linear System Model—Fiber Bandwidth 173<br/>5.6.2. Dispersion Limits 174<br/>5.6.3. Dispersion Measurement 176<br/>Problems 178<br/>References 183<br/>Chapter6. Special-Purpose Index Profiles 185<br/>6.1. Multimode Graded Index Fiber 185<br/>6.1.1. Ray Optics Picture 186<br/>6.1.2. Field Analysis 188<br/>6.1.3. Index Profile Optimization 194<br/>6.2. Special Index Profiles in Single-Mode Fiber 198<br/>6.2.1. The Equivalent Step Index Method 198<br/>6.2.2. Index Profiles for Control of Loss and Dispersion 207<br/>6.2.3. Polarization-Maintaining Fiber 214<br/>6.2.4. Photonic Crystal Fiber 219<br/>Problems 223<br/>References 225<br/>Chapter?. Nonlinear Effects in Fibers I: Nonresonant Processes 228<br/>7.1. Nonlinear Optics Fundamentals 229<br/>7.1.1. The Role of Medium Polarization in Wave Propagation 229<br/>7.1.2. The Nonlinear Polarization 230<br/>7.1.3. The Structure ofthe Nonlinear Susceptibility 232<br/>7.1.4. Symmetries in the Third-Order Susceptibility Tensor 235<br/>7.1.5. Example:Third Harmonic Generation 237<br/>7.2. Nonlinear Phase Modulation on Pulses 241<br/>7.2.1. Nonlinear Refractive Index . 241<br/>7.2.2. Self-Phase Modulation 243CONTENTS XI<br/>7.3. The Nonlinear Schrodinger Equation 245<br/>7.3.1. Development of the Nonlinear Schrodinger Equation<br/>from the Wave Equation 246<br/>7.3.2. Normalized Form of the Nonlinear Schrodinger<br/>Equation 249<br/>7.3.3. Optical Solitons 251<br/>7.4. Additional Nonresonant Proces.se.s 255<br/>7.4.1. Cross-Phase Modulation 258<br/>7.4.2. Four-Wave Mixing 260<br/>Problems 263<br/>References 265<br/>Chapters. Nonlinear Effects in Fibers II: Resonant Processes<br/>and Amplification 267<br/>8.1. Raman Scattering 268<br/>8.1.1. Basic Theory of Stimulated Raman Scattering 268<br/>8.1.2. Raman Gain in Silica Fiber 274<br/>8.1.3. Stimulated and Spontaneous Raman Scattering in Fiber 276<br/>8.1.4. Multiple Stokes Orders and Raman Cross-Talk 279<br/>8.1.5. Raman Fiber Amplifiers 282<br/>8.2. Stimulated Brillouin Scattering 285<br/>8.2.1. Stimulated Brillouin Scattering as a Third-Order<br/>Process 286<br/>8.2.2. The Acoustic Displacement Equation 287<br/>8.2.3. The Nonlinear Polarizations and Coupled Equations for<br/>Stimulated Brillouin Scattering 288<br/>8.2.4. Brillouin Amplification 290<br/>8.2.5. Adapting the Theory to Optical Fibers 292<br/>8.3. Rare-Earth-Doped Fiber Amplifiers 293<br/>8.3.1. Basic Theory of Amplification by Stimulated Emission 294<br/>8.3.2. Absorption and Emission Characteristics of<br/>Erbium-Doped Fiber 296<br/>8.3.3. Erbium-Doped Fiber Amplifier Fabrication,<br/>Configuration,and Operating Regimes 302<br/>8.3.4. Gain Flattening and Noise 304<br/>8.3.5. Other Rare-Earth-Doped Systems 305<br/><br/> |
942 ## - ADDED ENTRY ELEMENTS (KOHA) | |
Koha item type | General Books |
Withdrawn status | Lost status | Damaged status | Not for loan | Home library | Current library | Shelving location | Date acquired | Full call number | Accession number | Date last seen | Koha item type |
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Central Library, Sikkim University | Central Library, Sikkim University | General Book Section | 29/08/2016 | 621.3692 BUC/F | P31704 | 29/08/2016 | General Books |