Erbium-Doped Fiber Amplifiers: Principles and ApplicationsISBN: 978-0-471-26434-7
Paperback
800 pages
August 2002
This is a Print-on-Demand title. It will be printed specifically to fill your order. Please allow an additional 15-20 days delivery time. The book is not returnable.
|
List of Acronyms and Symbols.
A: FUNDAMENTALS OF OPTICAL AMPLIFICATION IN ERBIUM-DOPED SINGLE-MODE FIBERS.
Modeling Light Amplification in Erbium-Doped Single-Mode Fibers.
Fundamentals of Noise in Optical Fiber Amplifiers.
Photodetection of Optically Amplified Signals.
B: CHARACTERISTICS OF ERBIUM-DOPED FIBER AMPLIFIERS.
Characteristics of Erbium-Doped Fibers.
Gain, Saturation and Noise Characteristics of Erbium-Doped Fiber Amplifiers.
C: DEVICE AND SYSTEM APPLICATIONS OF ERBIUM-DOPED FIBER AMPLIFIERS.
Device Applications of EDFAs.
System Applications of EDFAs.
Appendix A: Rate Equations for Stark Split Three-Level Laser Systems.
Appendix B: Comparison of LP01 Bessel Solution and Gaussian Approximation for the Fundamental Fiber Mode Envelope.
Appendix C: Example of Program Organization and Subroutines for Numerical Integration of General Rate Equations (1.68).
Appendix D: Emission and Absorption Coefficients for Three-Level Laser Systems with Gaussian Mode Envelope Approximation.
Appendix E: Analytical Solutions for Pump and Signal+Ase in the Unsaturated Gain Regime, for Unidirectional and Bidirectional Pumping.
Appendix F: Density Matrix Description of Stark Split Three-Level Laser Systems.
Appendix G: Resolution of the Amplifier PGF Differential Equation in the Linear Gain Regime.
Appendix H: Calculation of the Output Noise and Variance of Lumped Amplifier Chains.
Appendix I: Derivation of a General Formula for the Optical Noise Figure of Amplifier Chains.
Appendix J: Derivation of the Nonlinear Photon Statistics Master Equation and Moment Equations for Two- or Three-Level Laser Systems.
Appendix K: Semiclassical Determination of Noise Power Spectral Density in Amplified Light Photodetection.
Appendix L: Derivation of the Absorption and Emission Cross Sections Through Einstein's A and B Coefficients.
Appendix M: Calculation of Homogeneous Absorption and Emission Cross Sections by Deconvolution of Experimental Cross Sections.
Appendix N: Rate Equations for Three-Level Systems with Pump Excited State Absorption.
Appendix O: Determination of Explicit Analytical Solution for a Low Gain, Unidirectionally Pumped EDFA with Single-Signal Saturation.
Appendix P: Determination of EDFA Excess Noise Factor in the Signal-Induced Saturation Regime.
Appendix Q: Average Power Analysis for Self-Saturated EDFAs.
Appendix R: A Computer Program for the Description of Amplifier Self-Saturation Through the Equivalent Input Noise Model.
Appendix S: Finite Difference Resolution Method for Transient Gain Dynamics in EDFAs.
Appendix T: Analytical Solutions for Transient Gain Dynamics in EDFAs.
Appendix U: Derivation of the Nonlinear Schrodinger Equation.
References.
Index.
A: FUNDAMENTALS OF OPTICAL AMPLIFICATION IN ERBIUM-DOPED SINGLE-MODE FIBERS.
Modeling Light Amplification in Erbium-Doped Single-Mode Fibers.
Fundamentals of Noise in Optical Fiber Amplifiers.
Photodetection of Optically Amplified Signals.
B: CHARACTERISTICS OF ERBIUM-DOPED FIBER AMPLIFIERS.
Characteristics of Erbium-Doped Fibers.
Gain, Saturation and Noise Characteristics of Erbium-Doped Fiber Amplifiers.
C: DEVICE AND SYSTEM APPLICATIONS OF ERBIUM-DOPED FIBER AMPLIFIERS.
Device Applications of EDFAs.
System Applications of EDFAs.
Appendix A: Rate Equations for Stark Split Three-Level Laser Systems.
Appendix B: Comparison of LP01 Bessel Solution and Gaussian Approximation for the Fundamental Fiber Mode Envelope.
Appendix C: Example of Program Organization and Subroutines for Numerical Integration of General Rate Equations (1.68).
Appendix D: Emission and Absorption Coefficients for Three-Level Laser Systems with Gaussian Mode Envelope Approximation.
Appendix E: Analytical Solutions for Pump and Signal+Ase in the Unsaturated Gain Regime, for Unidirectional and Bidirectional Pumping.
Appendix F: Density Matrix Description of Stark Split Three-Level Laser Systems.
Appendix G: Resolution of the Amplifier PGF Differential Equation in the Linear Gain Regime.
Appendix H: Calculation of the Output Noise and Variance of Lumped Amplifier Chains.
Appendix I: Derivation of a General Formula for the Optical Noise Figure of Amplifier Chains.
Appendix J: Derivation of the Nonlinear Photon Statistics Master Equation and Moment Equations for Two- or Three-Level Laser Systems.
Appendix K: Semiclassical Determination of Noise Power Spectral Density in Amplified Light Photodetection.
Appendix L: Derivation of the Absorption and Emission Cross Sections Through Einstein's A and B Coefficients.
Appendix M: Calculation of Homogeneous Absorption and Emission Cross Sections by Deconvolution of Experimental Cross Sections.
Appendix N: Rate Equations for Three-Level Systems with Pump Excited State Absorption.
Appendix O: Determination of Explicit Analytical Solution for a Low Gain, Unidirectionally Pumped EDFA with Single-Signal Saturation.
Appendix P: Determination of EDFA Excess Noise Factor in the Signal-Induced Saturation Regime.
Appendix Q: Average Power Analysis for Self-Saturated EDFAs.
Appendix R: A Computer Program for the Description of Amplifier Self-Saturation Through the Equivalent Input Noise Model.
Appendix S: Finite Difference Resolution Method for Transient Gain Dynamics in EDFAs.
Appendix T: Analytical Solutions for Transient Gain Dynamics in EDFAs.
Appendix U: Derivation of the Nonlinear Schrodinger Equation.
References.
Index.