E-Book, Englisch, 804 Seiten
Reihe: Optics and Photonics
Binh Guided Wave Photonics
1. Auflage 2016
ISBN: 978-1-4398-9716-4
Verlag: Taylor & Francis
Format: PDF
Kopierschutz: Adobe DRM (»Systemvoraussetzungen)
Fundamentals and Applications with MATLAB®
E-Book, Englisch, 804 Seiten
Reihe: Optics and Photonics
ISBN: 978-1-4398-9716-4
Verlag: Taylor & Francis
Format: PDF
Kopierschutz: Adobe DRM (»Systemvoraussetzungen)
A comprehensive presentation of the theory and simulation of optical waveguides and wave propagations in a guided environment, Guided Wave Photonics: Fundamentals and Applications with MATLAB® supplies fundamental and advanced understanding of integrated optical devices that are currently employed in modern optical fiber communications systems and photonic signal processing systems. While there are many texts available in this area, none provide the breadth and depth of coverage and computational rigor found in this one.
The author has distilled the information into a very practical, usable format. In a logical progression of theory and application, he starts with Maxwell's equations and progresses directly to optical waveguides (integrated optic and fiber optic), couplers, modulators, nonlinear effects and interactions, and system applications. With up-to-date coverage of applicable algorithms, design guides, material systems, and the latest device and system applications, the book addresses:
- Fundamentals of guiding optical waves, including theoretical and simplified techniques
- Linear and nonlinear aspects of optical waveguiding
- Manipulating lightwaves by coupling and splitting
- Interactions of lightwaves and ultra-fast electrical travelling waves in modern optical modulators
- Applications of guided wave devices in optical communication systems and optical signal processing
Providing fundamental understanding of lightwave guiding and manipulating techniques, the text covers the field of integrated photonics by giving the principles, theoretical and applications. It explains how to solve the optical modes and their coupling as well as how to manipulate lightwaves for applications in communications and signal processing.
Zielgruppe
Undergraduate and graduate students studying optical fiber communications, ultra high speed networks, and signal processing; engineers and researchers of integrated optical devices.
Autoren/Hrsg.
Fachgebiete
- Technische Wissenschaften Elektronik | Nachrichtentechnik Nachrichten- und Kommunikationstechnik Optische Nachrichtentechnik
- Technische Wissenschaften Technik Allgemein Technische Optik, Lasertechnologie
- Technische Wissenschaften Sonstige Technologien | Angewandte Technik Lasertechnologie, Holographie
Weitere Infos & Material
Introduction
Historical Overview of Integrated Optics and Photonics
Why Analysis of Optical Guided-wave Devices?
Principal Objectives
Chapters Overview
Single Mode Planar Optical Waveguides
Formation of Planar Single Mode Waveguide Problems
Approximate Analytical Methods of Solution
APPENDIX A: Maxwell Equations in Dielectric Media
APPENDIX B: Exact Analysis of Clad-linear Optical Waveguides
APPENDIX C: Wentzel–Kramers–Brilluoin Method, Turning Points and Connection Formulae
APPENDIX D: Design and Simulation of Planar Optical Waveguides
3D Integrated Optical Waveguides
Marcatili’s Method Effective Index Method
Non-uniform Grid Semivectorial Polarized Finite Difference Method for Optical Waveguides with Arbitrary Index Profile
Conclusions
Single Mode Optical Fibers: Structures and Transmission Properties
Optical Fibers
Nonlinear Optical Effects
Optical Fiber Manufacturing and Cabling
Concluding Remarks
Signal Attenuation and Dispersion
Signal Distortion in Optical Fibers
Transfer Function of Single Mode Fibers
Fiber Nonlinearity
Advanced Optical Fibers: Dispersion-shifted, Flatten and Compensated Optical Fibers
Numerical Solution: Split Step Fourier Method
Appendix: MATLAB Program for the Design of Optical Fibers
Program Listings of the Split Step Fourier Method with Self Phase Modulation and Raman Gain Distribution
Program Listings of an Initialization File
Design of Single Mode Optical Fiber Waveguides
Unified Formulation of Optical Fiber Waveguide Problems
Simplified Approach to the Design of Single Mode Optical Fibers
Dispersion Flattening and Compensating
Design Algorithm
Design Cases
Concluding Remarks
References
Appendix A: Derivatives of the RI with Respect to Wavelength
Appendix B: Higher Order Derivatives of the Propagation Constant
MATLAB Program for Design of Single Mode Optical Fibers
Scalar Coupled-mode Analysis
Coupler Configurations
Two-Mode Couplers
Fiber-slab Couplers
Fiber Bending
Numerical Calculations
Results and Discussion
Concluding Remarks
Full Coupled-mode Theory
Full Coupled-mode Analysis
Scalar CMT with Vectorial Corrections
Grating-assisted Fiber-slab Couplers
Analysis of Nonlinear Waveguide Couplers
Coupling in Dual-core Microstructure Fibers
Nonlinear Optical Waveguides: Switching, Parametric Conversion and Systems Applications
Introduction
Formulation of Electromagnetic Wave Equations for Nonlinear Optical Waveguides
Numerical Examples of Nonlinear Optical Waveguides
Nonlinear Optical Waveguide for Optical Transmission Systems
Demultiplexing 320 Gb/s Optical Time Division Multiplexed-Differential Quadrature Phase Shift Keying Signals Using Parametric Conversion in Nonlinear Optical Waveguides
Concluding Remarks
Integrated Guided-wave Photonic Transmitters
Optical Modulators
Traveling Wave Electrodes for Integrated Modulators
Lithium Niobate Optical Modulators: Devices and Applications
Generation and Modulation of Optical Pulse Sequences
Generation of Modulation
Nonlinearity in Guided Wave Devices
Nonlinear Effects in Integrated Optical Waveguides for Photonic Signal Processing
Nonlinear Effects in Actively Mode-locked Fiber Lasers
Nonlinear Photonic Pre-processing for Bispectrum Optical Receivers
Raman Effects in Microstructure Optical Fibers or Photonic Crystal Fibers
Raman Gain of Segmented Core Profile Fibers
Appendices
