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Guided-Wave Optoelectronics
The first guided-wave components that employed signals in the form of light beams traveling along thin films were fabricated a little more than two decades ago. The parallel development of semiconductor lasers and the subsequent availability of low-loss optical fibers made possible the imple­ mentation of completely optical systems for communications, signal processing and other applications that had used only electronic circuitry in the past. Referred to as integrated optics, this technology has been rein­ forced by utilizing electronic components that act as controlling elements or perform other functions for which the optical counterparts are not as effec­ tive. The broader area thus generated was aptly named optoelectronics and it currently represents a fascinating, rapidly evolving and most promising technology. Specifically, the amalgamation of electronic and optics components into an integrated optoelectronics format is expected to provide a wide range of systems having miniaturized, high speed, broad band and reliable components for telecommunications, data processing, optical computing and other applications in the near and far future. This book is intended to cover primarily the optical portion of the op­ toelectronics area by focusing on the theory and applications of components that use guided optical waves. Hence all aspects of integrated optics are discussed, but optoelectronic components having primarily electronic rather than optical functions have not been included. Each chapter has been writ­ ten by experts who have actively participated in developing the specific areas addressed by them.
1117273562
Guided-Wave Optoelectronics
The first guided-wave components that employed signals in the form of light beams traveling along thin films were fabricated a little more than two decades ago. The parallel development of semiconductor lasers and the subsequent availability of low-loss optical fibers made possible the imple­ mentation of completely optical systems for communications, signal processing and other applications that had used only electronic circuitry in the past. Referred to as integrated optics, this technology has been rein­ forced by utilizing electronic components that act as controlling elements or perform other functions for which the optical counterparts are not as effec­ tive. The broader area thus generated was aptly named optoelectronics and it currently represents a fascinating, rapidly evolving and most promising technology. Specifically, the amalgamation of electronic and optics components into an integrated optoelectronics format is expected to provide a wide range of systems having miniaturized, high speed, broad band and reliable components for telecommunications, data processing, optical computing and other applications in the near and far future. This book is intended to cover primarily the optical portion of the op­ toelectronics area by focusing on the theory and applications of components that use guided optical waves. Hence all aspects of integrated optics are discussed, but optoelectronic components having primarily electronic rather than optical functions have not been included. Each chapter has been writ­ ten by experts who have actively participated in developing the specific areas addressed by them.
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Guided-Wave Optoelectronics

Guided-Wave Optoelectronics

Overview

The first guided-wave components that employed signals in the form of light beams traveling along thin films were fabricated a little more than two decades ago. The parallel development of semiconductor lasers and the subsequent availability of low-loss optical fibers made possible the imple­ mentation of completely optical systems for communications, signal processing and other applications that had used only electronic circuitry in the past. Referred to as integrated optics, this technology has been rein­ forced by utilizing electronic components that act as controlling elements or perform other functions for which the optical counterparts are not as effec­ tive. The broader area thus generated was aptly named optoelectronics and it currently represents a fascinating, rapidly evolving and most promising technology. Specifically, the amalgamation of electronic and optics components into an integrated optoelectronics format is expected to provide a wide range of systems having miniaturized, high speed, broad band and reliable components for telecommunications, data processing, optical computing and other applications in the near and far future. This book is intended to cover primarily the optical portion of the op­ toelectronics area by focusing on the theory and applications of components that use guided optical waves. Hence all aspects of integrated optics are discussed, but optoelectronic components having primarily electronic rather than optical functions have not been included. Each chapter has been writ­ ten by experts who have actively participated in developing the specific areas addressed by them.

Product Details

ISBN-13: 9783642970764
Publisher: Springer Berlin Heidelberg
Publication date: 01/23/2012
Series: Springer Series in Electronics and Photonics , #26
Edition description: Softcover reprint of the original 1st ed. 1988
Pages: 401
Product dimensions: 6.10(w) x 9.25(h) x 0.03(d)

Table of Contents

1. Introduction.- 1.1 Overview.- 1.2 Organization of the Book.- References.- 2. Theory of Optical Waveguides.- 2.1 Ray Optics of the Slab Waveguide.- 2.2 Fundamentals of the Electromagnetic Theory of Dielectric Waveguides.- 2.3 Modes of the Planar Slab Guide.- 2.4 Planar Guides with Graded-Index Profiles.- 2.5 Channel Waveguides.- 2.6 Coupled-Mode Formalism and Periodic Waveguides.- References.- 3. Waveguide Transitions and Junctions.- 3.1 Waveguide Modes and Coupled-Mode Theory.- 3.2 Fast and Slow Transitions.- 3.3 Mode Coupling Between Local Normal Modes.- 3.4 Two-Arm Branches.- 3.5 Waveguide Horns.- 3.6 Branches with Three Arms.- 3.7 Conclusion.- References.- 4. Titanium-Diffused Lithium Niobate Waveguide Devices.- 4.1 Waveguide Fabrication.- 4.2 Basic Device Considerations.- 4.3 Switch/Modulator.- 4.4 On/Off Modulators.- 4.5 Polarization Devices.- 4.6 Wavelength Filters.- 4.7 Polarization-Insensitive Devices.- 4.8 Some Ti:LiNbO3 Integrated-Optic Circuits.- 4.9 Applications.- 5. Mode-Controlled Semiconductor Lasers.- 5.1 Organization of the Chapter.- 5.2 Laser Basics.- 5.3 Structures for Transverse-Mode Control.- 5.4 Longitudinal Mode Control.- 5.5 Linewidth.- 5.6 High-Speed Modulation.- 5.7 Luminescent Diodes and Laser Amplifiers.- Appendix 5A: Glossary of Symbols.- References.- 6. Semiconductor Integrated Optic Devices.- 6.1 Semiconductor Waveguide Theory.- 6.2 Material Technology.- 6.3 Passive Waveguide Devices — Fabrication and Characterization.- 6.4 Electro-Optic Guided-Wave Modulators — Theory.- 6.5 Electro-Optic Guided-Wave Modulator Characteristics.- 6.6 Optoelectronic Integrated Circuits (OEIC).- 6.7 Concluding Remarks.- References.
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