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Optical Solitons in Fibers Third Edition 2003 [Hardback]

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  • Formāts: Hardback, 201 pages, height x width: 235x155 mm, weight: 1060 g, IX, 201 p., 1 Hardback
  • Sērija : Springer Series in Photonics 9
  • Izdošanas datums: 14-Nov-2002
  • Izdevniecība: Springer-Verlag Berlin and Heidelberg GmbH & Co. K
  • ISBN-10: 3540436952
  • ISBN-13: 9783540436959
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  • Cena: 91,53 €*
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Optical Solitons in Fibers Third Edition 2003Palielināt
  • Formāts: Hardback, 201 pages, height x width: 235x155 mm, weight: 1060 g, IX, 201 p., 1 Hardback
  • Sērija : Springer Series in Photonics 9
  • Izdošanas datums: 14-Nov-2002
  • Izdevniecība: Springer-Verlag Berlin and Heidelberg GmbH & Co. K
  • ISBN-10: 3540436952
  • ISBN-13: 9783540436959
Citas grāmatas par šo tēmu:
Permanent link: https://www.kriso.lv/db/9783540436959.html
Keywords:
Optical solitons in fibers are a beautiful example of how an abstract mathematical concept has had an impact on new information transmission technologies. The concept of all-optical data transmission with optical soliton systems is now setting the standard for the most advanced transmission systems. The book deals with the motion of light waves in optical fibers, the evolution of light wavepackets, optical information transfer, all-optical soliton transmission systems, the control of optical solitons, polarization effects, dispersion-managed solitons, WDM transmission, soliton lasers, all-optical switching and other applications. This book is a must for all researchers and graduate students active in the field of optical data transmission.

Recenzijas

From the reviews of the third edition:



OPTICS & PHOTONICS NEWS



"The story of optical solitons in fibers is a wonderful example of how an abstract mathematical concept has produced a tremendous impact on real-world technology. Earlier editions of the book introduced the basic properties of optical solitons in fibers and methods of constructing all-optical transmission systems. This edition emphasizes practical issues related to applications in ultrahigh-speed communications, including information transfer, lightwave propagation in fibers, soliton control, the effects of higher order terms and the influence of polarization mode dispersion. Applications of solitons outside of long-distance transmission are explored. They include generation of short optical pulses, soliton switches and solitons in media having spatial periodicity in axial or in radial directions."



"This is quite simply an excellent text. It is the perfect review of optical soliton effects in a fibre, providing an up-to-date commentary with particular relevance to telecommunications, but with adequate information to be applicable to any area of optical soliton physics. sufficient referencing is provided to allow extensive follow up on any of the subtopics. I recommend it highly as an essential text to anyone with even a passing interest in optical solitons." (Prof. J. R. Taylor, Contemporary Physics, Vol. 45 (2), 2004)

Introduction
1(2)
Wave Motion
3(8)
What is Wave Motion?
3(1)
Dispersive and Nonlinear Effects of a Wave
4(1)
Solitary Waves and the Korteweg de Vries Equation
5(2)
Solution of the Korteweg de Vries Equation
7(4)
Lightwave in Fibers
11(8)
Polarization Effects
11(1)
Plane Electromagnetic Waves in Dielectric Materials
12(2)
Kerr Effect and Kerr Coefficient
14(1)
Dielectric Waveguides
15(4)
Information Transfer in Optical Fibers and Evolution of the Lightwave Packet
19(22)
How Information is Coded in a Lightwave
19(1)
How Information is Transferred in Optical Fibers
20(3)
Master Equation for Information Transfer in Optical Fibers: The Nonlinear Schrodinger Equation
23(2)
Evolution of the Wave Packet Due to the Group Velocity Dispersion
25(1)
Evolution of the Wave Packet Due to the Nonlinearity
26(1)
Technical Data of Dispersion and Nonlinearity in a Real Optical Fiber
27(2)
Nonlinear Schrodinger Equation and a Solitary Wave Solution
29(3)
Modulational Instability
32(5)
Induced Modulational Instability
37(1)
Modulational Instability Described by the Wave Kinetic Equation
38(3)
Optical Solitons in Fibers
41(20)
Soliton Solutions and the Results of Inverse Scattering
41(3)
Soliton Periods
44(1)
Conservation Quantities of the Nonlinear Schrodinger Equation
44(1)
Dark Solitons
45(4)
Soliton Perturbation Theory
49(3)
Effect of Fiber Loss
52(1)
Effect of the Waveguide Property of a Fiber
53(4)
Condition of Generation of a Soliton in Optical Fibers
57(1)
First Experiments on Generation of Optical Solitons
58(3)
All-Optical Soliton Transmission Systems
61(16)
Raman Amplification and Reshaping of Optical Solitons-First Concept of All-Optical Transmission Systems
61(3)
First Experiments of Soliton Reshaping and of Long Distance Transmission by Raman Amplifications
64(3)
First Experiment of Soliton Transmission by Means of an Erbium Doped Fiber Amplifier
67(1)
Concept of the Guiding Center Soliton
68(3)
The Gordon-Haus Effect and Soliton Timing Jitter
71(2)
Interaction Between Two Adjacent Solitons
73(1)
Interaction Between Two Solitons in Different Wavelength Channels
74(3)
Control of Optical Solitons
77(20)
Frequency-Domain Control
77(5)
Time-Domain Control
82(4)
Control by Means of Nonlinear Gain
86(4)
Numerical Examples of Soliton Transmission Control
90(7)
Influence of Higher-Order Terms
97(6)
Self-Frequency Shift of a Soliton Produced by Induced Raman Scattering
98(1)
Fission of Solitons Produced by Self-Induced Raman Scattering
99(1)
Effects of Other Higher-Order Dispersion
100(3)
Polarization Effects
103(20)
Fiber Birefringence and Coupled Nonlinear Schrodinger Equations
103(3)
Solitons in Fibers with Constant Birefringence
106(5)
Polarization-Mode Dispersion
111(4)
Solitons in Fibers with Randomly Varying Birefringence
115(8)
Dispersion-Managed Solitons (DMS)
123(18)
Problems in Conventional Soliton Transmission
123(1)
Dispersion Management with Dispersion-Decreasing Fibers
124(3)
Dispersion Management with Dispersion Compensation
127(9)
Quasi Solitons
136(5)
Application of Dispersion Managed Solitons for Single-Channel Ultra-High Speed Transmissions
141(18)
Enhancement of Pulse Energy
141(3)
Reduction of Gordon-Haus Timing Jitter
144(3)
Interaction Between Adjacent Pulses
147(4)
Dense Dispersion Management
151(1)
Nonstationary RZ Pulse Propagation
152(3)
Some Recent Experiments
155(4)
Application of Dispersion Managed Solitons for WDM Transmission
159(10)
Frequency Shift Induced by Collisions Between DM Solitons in Different Channels
159(2)
Temporal Shift Induced by Collisions Between DM Solitons in Different Channels
161(3)
Doubly Periodic Dispersion Management
164(2)
Some Recent WDM Experiments Using DM Solitons
166(3)
Other Applications of Optical Solitons
169(19)
Soliton Laser
169(4)
Pulse Compression
173(3)
All-Optical Switching
176(4)
Solitons in Fibers with Gratings
180(4)
Solitons in Microstructure Optical Fibers
184(4)
References 188(9)
Index 197