Together, this set sheds light on many new frontiers of knowledge, such as inhomogeneous modeling and nonlinear photon statistics, and demonstrates the many broadening benefits of EDFAs, including their polarization insensitivity, temperature stability, quantum-limited noise figure, and immunity to interchannel crosstalk.
Together, this set sheds light on many new frontiers of knowledge, such as inhomogeneous modeling and nonlinear photon statistics, and demonstrates the many broadening benefits of EDFAs, including their polarization insensitivity, temperature stability, quantum-limited noise figure, and immunity to interchannel crosstalk.
EMMANUEL DESURVIRE is Associate Professor of Electrical Engineering at Columbia University. For four years he was a member of the technical staff at AT&T Laboratories which did pioneering work in erbium-doped fiber amplifiers. In 1993 Dr. Desurvire received the IEEE's Distinguished Lecturer Award. In 1994, he joined Alcatel-Alsthom Recherche in France. He is a contributor to the book Fiber Lasers and Amplifiers and is the author or coauthor of more than 90 technical papers. He received his Diploma of Advanced Studies in the field of theoretical physics from the University of Paris in 1981 and his PhD in physics from the University of Nice two years later. He spent two years in postdoctoral research at Stanford University.
Inhaltsangabe
List of Acronyms and Symbols.
A: FUNDAMENTALS OF OPTICAL AMPLIFICATION IN ERBIUM-DOPEDSINGLE-MODE FIBERS.
Modeling Light Amplification in Erbium-Doped Single-ModeFibers.
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 FiberAmplifiers.
C: DEVICE AND SYSTEM APPLICATIONS OF ERBIUM-DOPED FIBERAMPLIFIERS.
Device Applications of EDFAs.
System Applications of EDFAs.
Appendix A: Rate Equations for Stark Split Three-Level LaserSystems.
Appendix B: Comparison of LP01 Bessel Solution and GaussianApproximation for the Fundamental Fiber Mode Envelope.
Appendix C: Example of Program Organization and Subroutines forNumerical Integration of General Rate Equations (1.68).
Appendix D: Emission and Absorption Coefficients for Three-LevelLaser Systems with Gaussian Mode Envelope Approximation.
Appendix E: Analytical Solutions for Pump and Signal+Ase in theUnsaturated Gain Regime, for Unidirectional and BidirectionalPumping.
Appendix F: Density Matrix Description of Stark Split Three-LevelLaser Systems.
Appendix G: Resolution of the Amplifier PGF Differential Equationin the Linear Gain Regime.
Appendix H: Calculation of the Output Noise and Variance of LumpedAmplifier Chains.
Appendix I: Derivation of a General Formula for the Optical NoiseFigure of Amplifier Chains.
Appendix J: Derivation of the Nonlinear Photon Statistics MasterEquation and Moment Equations for Two- or Three-Level LaserSystems.
Appendix K: Semiclassical Determination of Noise Power SpectralDensity in Amplified Light Photodetection.
Appendix L: Derivation of the Absorption and Emission CrossSections Through Einstein's A and B Coefficients.
Appendix M: Calculation of Homogeneous Absorption and EmissionCross Sections by Deconvolution of Experimental CrossSections.
Appendix N: Rate Equations for Three-Level Systems with PumpExcited State Absorption.
Appendix O: Determination of Explicit Analytical Solution for a LowGain, Unidirectionally Pumped EDFA with Single-SignalSaturation.
Appendix P: Determination of EDFA Excess Noise Factor in theSignal-Induced Saturation Regime.
Appendix Q: Average Power Analysis for Self-Saturated EDFAs.
Appendix R: A Computer Program for the Description of AmplifierSelf-Saturation Through the Equivalent Input Noise Model.
Appendix S: Finite Difference Resolution Method for Transient GainDynamics in EDFAs.
Appendix T: Analytical Solutions for Transient Gain Dynamics inEDFAs.
Appendix U: Derivation of the Nonlinear Schrodinger Equation.
References.
Index.
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. CHARACTERISTICS OF ERBIUM DOPED FIBER AMPLIFIERS. Characteristics of Erbium Doped Fibers. Gain, Saturation and Noise Characteristics of Erbium Doped Fiber Amplifiers. DEVICE AND SYSTEM APPLICATIONS OF ERBIUM DOPED FIBER AMPLIFIERS. Device Applications of EDFAs. System Applications of EDFAs. Appendices. References. Index.
A: FUNDAMENTALS OF OPTICAL AMPLIFICATION IN ERBIUM-DOPEDSINGLE-MODE FIBERS.
Modeling Light Amplification in Erbium-Doped Single-ModeFibers.
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 FiberAmplifiers.
C: DEVICE AND SYSTEM APPLICATIONS OF ERBIUM-DOPED FIBERAMPLIFIERS.
Device Applications of EDFAs.
System Applications of EDFAs.
Appendix A: Rate Equations for Stark Split Three-Level LaserSystems.
Appendix B: Comparison of LP01 Bessel Solution and GaussianApproximation for the Fundamental Fiber Mode Envelope.
Appendix C: Example of Program Organization and Subroutines forNumerical Integration of General Rate Equations (1.68).
Appendix D: Emission and Absorption Coefficients for Three-LevelLaser Systems with Gaussian Mode Envelope Approximation.
Appendix E: Analytical Solutions for Pump and Signal+Ase in theUnsaturated Gain Regime, for Unidirectional and BidirectionalPumping.
Appendix F: Density Matrix Description of Stark Split Three-LevelLaser Systems.
Appendix G: Resolution of the Amplifier PGF Differential Equationin the Linear Gain Regime.
Appendix H: Calculation of the Output Noise and Variance of LumpedAmplifier Chains.
Appendix I: Derivation of a General Formula for the Optical NoiseFigure of Amplifier Chains.
Appendix J: Derivation of the Nonlinear Photon Statistics MasterEquation and Moment Equations for Two- or Three-Level LaserSystems.
Appendix K: Semiclassical Determination of Noise Power SpectralDensity in Amplified Light Photodetection.
Appendix L: Derivation of the Absorption and Emission CrossSections Through Einstein's A and B Coefficients.
Appendix M: Calculation of Homogeneous Absorption and EmissionCross Sections by Deconvolution of Experimental CrossSections.
Appendix N: Rate Equations for Three-Level Systems with PumpExcited State Absorption.
Appendix O: Determination of Explicit Analytical Solution for a LowGain, Unidirectionally Pumped EDFA with Single-SignalSaturation.
Appendix P: Determination of EDFA Excess Noise Factor in theSignal-Induced Saturation Regime.
Appendix Q: Average Power Analysis for Self-Saturated EDFAs.
Appendix R: A Computer Program for the Description of AmplifierSelf-Saturation Through the Equivalent Input Noise Model.
Appendix S: Finite Difference Resolution Method for Transient GainDynamics in EDFAs.
Appendix T: Analytical Solutions for Transient Gain Dynamics inEDFAs.
Appendix U: Derivation of the Nonlinear Schrodinger Equation.
References.
Index.
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. CHARACTERISTICS OF ERBIUM DOPED FIBER AMPLIFIERS. Characteristics of Erbium Doped Fibers. Gain, Saturation and Noise Characteristics of Erbium Doped Fiber Amplifiers. DEVICE AND SYSTEM APPLICATIONS OF ERBIUM DOPED FIBER AMPLIFIERS. Device Applications of EDFAs. System Applications of EDFAs. Appendices. References. Index.
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