"The book is an indispensable reference for researchers, development engineers, and system designers in fiber-optic communications. . . . It will excel as an introductory text in upper-level undergraduate and graduate courses on system applications of fiber optics." --Optik "One of the most comprehensive and detailed accounts of the physics and fundamental principles of erbium-doped fiber amplifiers. . . . I do not hesitate to recommend the book enthusiastically to anyone having an interest in EDFAs and their applications." --Physics Today Erbium-doped fiber amplifiers are an important…mehr
"The book is an indispensable reference for researchers, development engineers, and system designers in fiber-optic communications. . . . It will excel as an introductory text in upper-level undergraduate and graduate courses on system applications of fiber optics." --Optik
"One of the most comprehensive and detailed accounts of the physics and fundamental principles of erbium-doped fiber amplifiers. . . . I do not hesitate to recommend the book enthusiastically to anyone having an interest in EDFAs and their applications." --Physics Today
Erbium-doped fiber amplifiers are an important technology for lightwave voice, video, and data transmission. The first volume of Erbium-Doped Fiber Amplifiers: Principles and Applications offered an important exploration of the then-infant technology of erbium-doped fiber amplifiers. The passage of the 1996 Telecommunications Act and the growth of the Internet have sparked intense demand for expanded bandwidth in all network layers, resulting in significant advances in EFDA technology.
Erbium-Doped Fiber Amplifiers: Device and System Developments brings telecommunications professionals up to date. Combining the contributions from four international experts in EDFAs, this new volume expands the reader's conceptual understanding of EDFAs and covers the developmental issues of EDFAs that are relevant to modern telecom applications. The authors review:
New aspects in EDFA modeling, including the standard confined-doping, the transcendental-power-equation, and average-inversion-level models Design concepts for EDFAs in terrestrial and submarine WDM systems Transmission fiber design and dispersion-management techniques for terabit/s systems Amplified submarine-cable systems, including a brief history of submarine cable communications and the investigation of terabit/s system technologies Advanced concepts in the physics of noise in amplified light, noise figure definitions, entropy and ultimatecapacity limits Delving into fundamental concepts (including a wealth of previously unpublished materials) as well as important breakthroughs, this much-needed resource will place telecom engineers in a position to take advantage of every aspect in the broad potential of EDFAs.
Produktdetails
Produktdetails
Wiley Series in Telecommunications and Signal Processing 2
EMMANUEL DESURVIRE has been involved in the field of optical fiber amplifiers for nearly twenty years, starting with his PhD work on Raman fiber amplification in 1981-83. For his contributions to the early investigation and development of EDFAs at AT&T Bell Laboratories, he received several national and international awards, including the 1994 prize from the International Commission for Optics and, jointly with Professor D. N. Payne, the 1998 Benjamin Franklin Medal in engineering. He is currently Director of the Alcatel Technical Academy, a corporate program that aims to recognize experts and foster synergies in research and development. An IEEE Fellow, he has authored or coauthored more than 200 technical publications and 30 patents. DOMINIQUE BAYART graduated as Physics Engineer from the National Polytechnic Institute of Grenoble (France) in 1990. He joined Alcatel Research and Innovation (Marcoussis, France) in 1991 and is now Deputy Manager for the Photonic Transmission Unit. He has contributed 12 postdeadline papers to major conferences (OFC, ECOC, OAA) and authored or coauthored more than 70 technical publications and 30 patents. BERTRAND DESTHIEUX received an MS in physics from Limoges University, France, and graduated as an engineer from Orsay's École Supérieure d'Optique in 1990. He is a former team leader at the Alcatel Transmission System Division in Nozay, France. After Alcatel, he joined Latus Lightworks in Richardson, Texas, as manager of the optical transmission engineering department. He is now a senior engineer in the photonic department at Xtera Communications, Inc., in Allen, Texas. He has authored or coauthored nearly 20 technical publications and 15 patents. SÉBASTIEN BIGO received an engineering degree from the École Supérieure d'Optique in 1992 (Orsay, France) and a PhD from the University of Besançon (France) in 1996. He is the leader of the WDM transmission group at Alcatel Research and Innovation, which obtained several multi-terabit/s transmission records, and has authored or coauthored more than 80 papers and 25 patents.
Inhaltsangabe
Foreword. Preface. Acknowledgments. List of Acronyms and Symbols. PART A: FUNDAMENTALS, COMPLEMENTS, AND DEVELOPMENTS: PHYSICS AND MODELING. Chapter 1. New Aspects in EDFA Modeling. Chapter 2. Origin and Analysis of Noise in EDFAs. Chapter 3. Information Capacity of Optically Amplified Signals. Chapter 4. Secondary Physical Effects in EDFAs. PART B: NEW DESIGNS, DEVELOPMENTS, AND SYSTEM APPLICATIONS OF EDFAs. Chapter 5. Amplifier Technology and Design for Terrestrial Transmission. Chapter 6. Amplifier Technology and Design for Transoceanic Transmission. Chapter 7. Amplified Terrestrial Networks. Chapter 8. Amplified Submarine-Cable Systems. Appendix A: Time-Dependent Average-Inversion Model. Appendix B: Derivation of the Output PDF and Associated Mean and Variance for the Coherent Single-Photon Multiplier. Appendix C: Semiclassical Quantum-Beamsplitter Model. Appendix D: Semiclassical Derivation of Symbol PDF and BER of Optically Amplified Signals. Appendix E: BER Extrapolation Method Based on the Leveberg-Marquardt Nonlinear Curve-Fitting Algorithm. Appendix F: Mutual Information and Equivocation in Discrete Memoryless Channel with N-Symbol Alphabet. Appendix G: System Performance Criteria. Appendix H: Basic Principles of Error-Correction Coding. References. Index.
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.
Foreword. Preface. Acknowledgments. List of Acronyms and Symbols. PART A: FUNDAMENTALS, COMPLEMENTS, AND DEVELOPMENTS: PHYSICS AND MODELING. Chapter 1. New Aspects in EDFA Modeling. Chapter 2. Origin and Analysis of Noise in EDFAs. Chapter 3. Information Capacity of Optically Amplified Signals. Chapter 4. Secondary Physical Effects in EDFAs. PART B: NEW DESIGNS, DEVELOPMENTS, AND SYSTEM APPLICATIONS OF EDFAs. Chapter 5. Amplifier Technology and Design for Terrestrial Transmission. Chapter 6. Amplifier Technology and Design for Transoceanic Transmission. Chapter 7. Amplified Terrestrial Networks. Chapter 8. Amplified Submarine-Cable Systems. Appendix A: Time-Dependent Average-Inversion Model. Appendix B: Derivation of the Output PDF and Associated Mean and Variance for the Coherent Single-Photon Multiplier. Appendix C: Semiclassical Quantum-Beamsplitter Model. Appendix D: Semiclassical Derivation of Symbol PDF and BER of Optically Amplified Signals. Appendix E: BER Extrapolation Method Based on the Leveberg-Marquardt Nonlinear Curve-Fitting Algorithm. Appendix F: Mutual Information and Equivocation in Discrete Memoryless Channel with N-Symbol Alphabet. Appendix G: System Performance Criteria. Appendix H: Basic Principles of Error-Correction Coding. References. Index.
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.
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