Cover is for reference only

Optical fiber telecommunications. Volume B, Systems and networks/

Optical Fiber Telecommunications VI (A&B) is the sixth in a series that has chronicled the progress in the R&D of lightwave communications since the early 1970s. Written by active authorities from academia and industry, this edition brings a fresh look to many essential topics, including dev...

Full description

Saved in:
Bibliographic Details
Corporate Authors: Elsevier Science & Technology.
Group Author: Kaminow, Ivan P., 1930-; Li, Tingye; Willner, Alan E.
Published: Academic Press Inc.,
Publisher Address: Oxford :
Publication Dates: 2013.
Literature type: eBook
Language: English
Edition: Sixth edition.
Series: Optics and photonics
Subjects:
Optical fiber communication.
Optical fiber communication > Equipment and supplies.
Fiber optics.
Telecommunication systems > Management.
Electronic books.
Online Access: http://www.sciencedirect.com/science/book/9780123969606
Summary: Optical Fiber Telecommunications VI (A&B) is the sixth in a series that has chronicled the progress in the R&D of lightwave communications since the early 1970s. Written by active authorities from academia and industry, this edition brings a fresh look to many essential topics, including devices, subsystems, systems and networks. A central theme is the enabling of high-bandwidth communications in a cost-effective manner for the development of customer applications. These volumes are an ideal reference for R&D engineers and managers, optical systems implementers, university researchers and students, network operators, and investors. Volume A is devoted to components and subsystems, including photonic integrated circuits, multicore and few-mode fibers, photonic crystals, silicon photonics, signal processing, and optical interconnections. Volume B is devoted to systems and networks, including advanced modulation formats, coherent detection, Tb/s channels, space-division multiplexing, reconfigurable networks, broadband access, undersea cable, satellite communications, and microwave photonics. All the latest technologies and techniques for developing future components and systemsEdited by two winners of the highly prestigious OSA/IEEE John Tyndal award and a President of IEEE's Lasers & Electro-Optics Society (7,000 members)Written by leading experts in the field, it is the most authoritative and comprehensive reference on optical engineering the market.
Carrier Form: 1 online resource (1040 pages) : illustrations.
ISBN: 9780123969606 (electronic bk.)
0123969603 (electronic bk.)
Index Number: TK5103
CLC: TN929.11
Contents: Machine generated contents note: ch. 1 Fiber Nonlinearity and Capacity: Single-Mode and Multimode Fibers / Roland Ryf -- 1.1.Introduction -- 1.2.Network traffic and optical systems capacity -- 1.3.Information theory -- 1.3.1.Basic concepts -- 1.3.2.Link to optical communication -- 1.4.Single-mode fibers: single polarization -- 1.4.1.Stochastic nonlinear Schrodinger equation -- 1.4.2.Nonlinear capacity of standard single-mode fiber -- 1.4.3.Advanced single-mode fibers -- 1.4.4.Analytic formula of fiber capacity -- 1.5.Single-mode fibers: polarization-division multiplexing -- 1.5.1.Nonlinear propagation: stochastic Manakov equations -- 1.5.2.Capacity of PDM systems -- 1.6.Multicore and multimode fibers -- 1.6.1.Types of multicore and multimode fibers -- 1.6.2.Capacity scaling with the number of modes -- 1.6.3.Generalized Manakov equations for multimode fibers -- 1.6.4.Description of a few-mode fiber -- 1.6.5.Inter-modal cross-phase modulation -- 1.6.6.Inter-modal four-wave mixing -- 1.7.Conclusion -- References -- ch. 2 Commercial 100-Gbit/s Coherent Transmission Systems / Glenn A. Wellbrock -- 2.1.Introduction -- 2.2.Optical channel designs -- 2.3.100G channel-from wish to reality -- 2.4.Introduction of 100g channels to service provider networks -- 2.5.Impact of commercial 100g system to transport network -- 2.6.Outlook beyond commercial 100g systems -- 2.7.Summary -- References -- ch. 3 Advances in Tb/s Superchannels / Xiang Liu -- 3.1.Introduction -- 3.2.Superchannel principle -- 3.3.Modulation -- 3.4.Multiplexing -- 3.4.1.Overview of multiplexing schemes -- 3.4.2.Seamless multiplexing -- 3.4.3.Multiplexing with guard band -- 3.5.Detection -- 3.6.Superchannel transmission -- 3.6.1.Transmission based on single-carrier modulation and O-OFDM multiplexing -- 3.6.2.Transmission based on OFDM modulation and O-OFDM multiplexing -- 3.6.3.Transmission based on Nyquist-WDM -- 3.6.4.Optimization of the spectral-efficiency-distance-product -- 3.7.Networking implications -- 3
Note continued: 11.4.5.Spatial whiteness of received noise -- 11.4.6.Frequency-dependent mode-dependent loss and gain -- 11.5.Direct-detection mode-division multiplexing -- 11.6.Coherent mode-division multiplexing -- 11.6.1.Average channel capacity of narrowband systems -- 11.6.2.Wideband systems and frequency diversity -- 11.6.3.Signal processing for mode-division-multiplexing -- 11.7.Conclusion -- References -- ch. 12 Multimode Communications Using Orbital Angular Momentum / Alan E. Willner -- 12.1.Perspective on orbital angular momentum (OAM) multiplexing in communication systems -- 12.2.Fundamentals of OAM -- 12.3.Techniques for OAM generation, multiplexing/demultiplexing, and detection -- 12.3.1.OAM generation -- 12.3.2.OAM multiplexing/demultiplexing -- 12.3.3.OAM detection -- 12.4.Free-space communication links using OAM multiplexing -- 12.4.1.OAM+WDM link -- 12.4.2.OAM+PDM link -- 12.4.3.Scalability of OAM+PDM in spatial domain -- 12.5.Fiber-based transmission links -- 12.5.1.Fiber design -- 12.5.2.Coupling and controlling OAM in fibers -- 12.5.3.Long-length propagation of OAM in fiber -- 12.5.4.Fiber-based data transmission using OAM -- 12.6.Optical signal processing using OAM -- 12.6.1.Data exchange -- 12.6.2.Add/drop -- 12.6.3.Multicasting -- 12.6.4.Monitoring and compensation -- 12.7.Future challenges of OAM communications -- References -- ch. 13 Transmission Systems Using Multicore Fibers / Shoichiro Matsuo -- 13.1.Expectations of multicore fibers -- 13.2.MCF design -- 13.2.1.Types of MCFs -- 13.2.2.Inter-core crosstalk in homogeneous uncoupled MCFs -- 13.2.3.Inter-core crosstalk in heterogeneous uncoupled MCFs -- 13.3.Methods of coupling to MCFs -- 13.3.1.Lens coupling systems -- 13.3.2.Fiber-based systems and waveguide-based systems -- 13.3.3.Splicing techniques -- 13.4.Transmission experiments with uncoupled cores -- 13.4.1.Early demonstrations -- 13.4.2.Scalability of core number -- 13.4.3.1-R repeated demonstrations -- 13.5.Laguerre-Gaussian mode
Note continued: 23.5.2.Modulation bandwidth of RSOA and its equalization technique -- 23.5.3.Utilization of advanced modulation formats -- 23.5.4.Ultrahigh-speed WDM PON -- 23.6.Fault monitoring, localization and protection techniques -- 23.6.1.Fault localization techniques for WDM PON -- 23.6.2.Survivable WDM PONs -- 23.7.Summary -- Appendix: Acronyms -- References -- ch. 24 FTTX Worldwide Deployment / Zisen Zhao -- 24.1.Introduction -- 24.2.Background of fiber architectures -- 24.2.1.Passive optical networks (PONs) -- 24.2.2.Point to point -- 24.3.Technology variants -- 24.3.1.B-PON -- 24.3.2.GE-PON -- 22.3.3.G-PON -- 24.3.4.Next-generation PON technologies -- 24.3.5.Coexistence and wavelength plan -- 24.3.6.Extended reach systems -- 24.3.7.CO consolidation -- 24.4.Status and FTTX deployments around the world -- 24.4.1.FTTX in Asia -- 24.4.2.FTTX in Europe and Africa -- 24.4.3.FTTX in the Americas -- 24.5.What's Next? -- 24.6.Summary -- References -- ch. 25 Modern Undersea Transmission Technology / Georg Mohs -- 25.1.Introduction -- 25.1.1.Reach, latency and capacity -- 25.1.2.The capacity challenge -- 25.2.Coherent transmission technology in undersea systems -- 25.2.1.Introduction to coherent detection -- 25.2.2.Linear impairment compensation with coherent detection -- 25.2.3.Nonlinearity accumulation in dispersion uncompensated transmission -- 25.3.Increasing spectral efficiency by bandwidth constraint -- 25.3.1.Inter-symbol interference compensation by linear filters -- 25.3.2.Multi-symbol detection -- 25.4.Nyquist carrier spacing -- 25.4.1.Spectral shaping for single channel modulation formats -- 25.4.2.Orthogonal frequency division multiplexing (OFDM) -- 25.4.3.Super-channels -- 25.5.Increasing spectral efficiency by increasing the constellation size -- 25.5.1.Higher order modulation formats -- 25.5.2.Receiver sensitivity -- 25.5.3.Coded modulation -- 25.6.Future trends -- 25.6.1.Nonlinearitycompensation -- 25.6.2.Multi-core and multi-mode fiber -- 25.7.Sum

Related Book Recommendations