Handbook of distributed feedback laser diodes

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Bibliographic Details
Main Authors Morthier, Geert (Author), Vankwikelberge, Patrick (Author)
Format Electronic eBook
LanguageEnglish
Published Boston : Artech House, [2013]
EditionSecond edition.
SeriesArtech House applied photonics series.
Subjects
Solid-state lasers.
Semiconductor lasers.
Diodes, Semiconductor.
elektronické knihy
electronic books
Online AccessFull text
ISBN9781608077021
1608077020
9781523117246
1523117249
9781608077014
1608077012
Physical Description1 online resource (397 pages) : illustrations.

Cover

Table of Contents:
  • Intro; Title; Contents; Preface; CH01 Introduction to Fabry-Perot and Distributed Feedback Laser Diodes; CH02 Rate Equation Theory of Laser Diodes; CH03 Coupled-Mode Theory of DFB Laser Diodes; CH04 Applying the Coupled Mode Theory; CH05 A Closer Look at the Carrier Injection; CH06 The Spectrum of DFB Laser Diodes; CH07 The IM and FM Behavior of DFB Laser Diodes; CH08 Harmonic and Intermodulation Distortion in DFB Laser Diodes; CH09 Noise Characteristics of DFB Laser Diodes; CH10 Wavelength Tunable DFB Laser Diodes; CH11 Bistable and Self-Pulsating DFB Laser Diodes
  • CH12 Fabrication and Packaging of DFB Laser DiodesCH13 Epilogue; Appendix A: Noise, Auto-Correlations, and Spectral Densities; Appendix B: Derivation of (9.13) from (4.41); About the Authors; Index; 1.1 Historical Background; 1.2 Laser Diode Device Structure; 1.3 Operation of the Laser Diode; 1.4 Essential Laser Diode Characteristics; 1.5 Use of Laser Diodes in Optical CommunicationsSystems; 1.6 Dynamic Single-Mode Laser Diodes; 1.7 Organization of This Book; 2.1 Introduction; 2.2 Carrier Density Rate Equation; 2.3 Photon Density Rate Equation; 2.4 Phase Equations
  • 2.5 Introducing Noise in the Rate Equations2.6 Optical Gain and Absorption; 2.7 Some Well-Known Solutions of the Rate Equations; 2.8 The Influence of External Reflections; 2.9 Summary; 3.1 The Physical Processes Inside a Laser Diode; 3.2 The Need for Simplification; 3.3 Assumptions about the Modeled Laser Structure; 3.4 Optical Wave Propagation; 3.5 Discussion of the Coupled-Mode Wave Equations; 3.6 The Electrical Transport Problem; 3.7 The Standing-Wave Effect in Gain-Coupled Lasers; 3.8 Boundary Conditions; 4.1 Introduction; 4.2 Threshold Solutions for Simple DFB Lasers
  • 4.3 Numerical Solutions of the Coupled Mode Model4.4 The Narrowband Approach for Solving the CoupledMode Model; 4.5 The Broadband Approach for Solving the CoupledMode Model; 4.6 Coupling Coefficients for DFB Lasers; 4.6 Coupling Coefficients for DFB Lasers; 4.7 Derivation of the Rate Equations for DFB Lasers; 4.8 Longitudinal Spatial Hole Burning; 5.1 Introduction; 5.2 Heterojunctions and Semi-Insulating Materials; 5.3 Carrier Leakage Over Heterobarriers; 5.4 Carrier Injection in Gain-Guided and Weakly Index-Guided Lasers; 5.5 Lateral Current Leakage in Index-Guided Structures
  • 5.6 Parasitic Elements5.7 Microwave Effects; 5.8 Circuit Modeling of Leakage and Parasitic Elements; 5.9 Summary; 6.1 Amplified Spontaneous Emission; 6.2 Side-Mode Rejection and Yield of DFB Lasers; 6.3 Degradation of the SMSR by Spatial Hole Burning; 6.4 DFB Lasers with Reduced Spatial Hole Burning; 6.5 Measurement of the ASE Spectrum of DFB Lasers; 6.6 Extraction of Device Parameters from the Spectrum; 7.1 Measuring the IM Response of Laser Diodes; 7.2 Measuring the FM Response of Laser Diodes; 7.3 The IM Response; 7.4 The FM Response; 7.5 Lateral Spatial Hole Burning

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