DWDM : (Record no. 73951)

000 -LEADER
fixed length control field 13966nam a2200937 i 4500
001 - CONTROL NUMBER
control field 5266229
005 - DATE AND TIME OF LATEST TRANSACTION
control field 20220712205704.0
008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION
fixed length control field 100317t20152003njua ob 001 0 eng d
020 ## - INTERNATIONAL STANDARD BOOK NUMBER
ISBN 9780470544440
-- electronic
020 ## - INTERNATIONAL STANDARD BOOK NUMBER
-- print
020 ## - INTERNATIONAL STANDARD BOOK NUMBER
-- electronic
082 04 - CLASSIFICATION NUMBER
Call Number 621.3827
100 1# - AUTHOR NAME
Author Kartalopoulos, Stamatios V.,
245 10 - TITLE STATEMENT
Title DWDM :
Sub Title networks, science, and technology /
300 ## - PHYSICAL DESCRIPTION
Number of Pages 1 online resource (xxvi, 487 pages) :
505 0# - FORMATTED CONTENTS NOTE
Remark 2 Preface -- Acknowledgments -- List of Physical Constants -- Introduction -- 1. The Physics of Optical Components -- 1.1. Introduction -- 1.2. The Nature of Light -- 1.2.1. The Wave Nature of Light -- 1.2.2. The Particle Nature of Light -- 1.2.3. Huygens-Fresnel Principle -- 1.2.4. Interference -- 1.2.5. Holography -- 1.2.6. Optical Correlators and Storage -- 1.2.7. Light Attributes -- 1.3. Optical Materials -- 1.3.1. Transparent Versus Opaque Matter -- 1.3.2. Homogeneity and Heterogeneity -- 1.3.3. Isotropy and Anisotropy -- 1.3.4. Organic Materials -- 1.3.5. Photochromaticity -- 1.4. Light Meets Matter -- 1.4.1. Reflection and Refraction: Snell's Law -- 1.4.2. Critical Angle -- 1.4.3. Antireflection -- 1.4.4. Prisms and Superprisms -- 1.4.5. Propagation of Light -- 1.4.6. Diffraction -- 1.4.7. Polarization -- 1.4.8. Extinction Ratio -- 1.4.9. Phase Shift -- 1.4.10. Birefringence -- 1.4.11. Material Dispersion -- 1.4.12. Electro-Optic Effects -- 1.4.13. Material Attributes -- 1.5. The Fiber as an Optical Transmission Medium -- 1.5.1. Composite Refractive Indices -- 1.5.2. Fiber Modes -- 1.5.3. Fiber Attenuation and Power Loss -- 1.5.4. Fiber Birefringence -- 1.5.5. Dispersion -- 1.5.6. Spectral Broadening -- 1.5.7. Self-Phase Modulation -- 1.5.8. Self-Modulation or Modulation Instability -- 1.5.9. Effect of Pulse Broadening on Bit Error Rate -- 1.6. Nonlinear Phenomena -- 1.6.1. Stimulated Raman Scattering -- 1.6.2. Stimulated Brillouin Scattering -- 1.6.3. Four-Wave Mixing -- 1.6.4. Temporal FWM, Near-End and Far-End -- 1.6.5. Impact of FWM on DWDM Transmission Systems -- 1.6.6. Countermeasures to Reduce FWM -- 1.7. Solitons -- 1.8. Summary of Nonlinear Phenomena -- 1.9. Factors that Affect Matter and Light -- 1.10. Regarding Optical Fiber -- 1.10.1. Ideal Fiber Versus Real Fiber -- 1.10.2. The Evolving Bandwidth-Span Product -- 1.10.3. Fiber Amplifiers and Spectral Continuum -- 1.10.4. New Fibers -- 1.10.5. How Strong Is Fiber? -- 1.11. Fiber Connectivity -- 1.12. Optical PWBs.
505 8# - FORMATTED CONTENTS NOTE
Remark 2 Exercises -- References -- Standards -- 2. Optical Components -- 2.1. Introduction -- 2.1.1. Geometrical Optics -- 2.1.2. Insertion Loss and Isolation -- 2.1.3. Parameters Common to All Components -- 2.2. Optical Filters -- 2.2.1. Fabry-Perot Interferometer -- 2.2.2. Dielectric Thin Film -- 2.2.3. Diffraction Gratings -- 2.2.4. Bragg Gratings -- 2.2.5. Mach-Zehnder Interferometry -- 2.2.6. Arrayed Waveguide Grating Filters -- 2.2.7. Polarizing Filters -- 2.2.8. Absorption Filters -- 2.2.9. Acousto-Optic Tunable Filters -- 2.2.10. Hybrid Filters -- 2.2.11. Comparing Tunable Filters -- 2.3. Optical Directional Couplers -- 2.4. Optical Power Attenuators -- 2.5. Polarizers and Rotators -- 2.6. Beam Splitters -- 2.7. Optical Isolators and Circulators -- 2.8. Quarter-Wavelength and Half-Wavelength Plates -- 2.9. Optical Multiplexers and Demultiplexers -- 2.9.1. Prisms and Superprisms -- 2.9.2. Gratings -- 2.9.3. Mach-Zehnder Demultiplexer -- 2.9.4. Arrayed Waveguide Grating Demultiplexers -- 2.9.5. Channel Interleavers and Channel Splitters -- 2.10. Optical Cross-Connects -- 2.10.1. Free-Space Optical Switching -- 2.10.2. Solid-State Cross-Connects -- 2.10.3. Polymers and Inks -- 2.10.4. Photochromic Materials -- 2.10.5. Technologies and Switching Speeds -- 2.11. Optical Add-Drop Multiplexers -- 2.12. Optical Equalizers -- 2.13. Light Sources -- 2.13.1. Light-Emitting Diodes -- 2.13.2. Lasers -- 2.14. Laser Beams -- 2.14.1. Gaussian Beams -- 2.14.2. Near-Field and Far-Field Distribution -- 2.14.3. Peak Wavelength -- 2.14.4. Degree of Coherence -- 2.14.5. Laser Safety -- 2.15. Modulators -- 2.15.1. Types of Modulators -- 2.15.2. A Case: Amplitude Modulation -- 2.15.3. Modulation and Bit Error Probabilities -- 2.16. Photodetectors and Receivers -- 2.16.1. The PIN Photodiode -- 2.16.2. The APD Photodiode -- 2.16.3. Photodetector Figure of Merit -- 2.16.4. ITU-T Nominal Center Frequencies -- 2.17. Optical Amplifiers -- 2.17.1. Semiconductor Optical Amplifiers -- 2.17.2. Rare Earth-Doped Fiber Optical Amplifiers.
505 8# - FORMATTED CONTENTS NOTE
Remark 2 2.17.3. Optical Parametric Amplifiers -- 2.17.4. Raman Amplifiers -- 2.17.5. Synergistic Amplification -- 2.17.6. Stimulated Brillouin Scattering -- 2.17.7. Amplification in the Low-Loss Spectral Range -- 2.18. Wavelength Converters -- 2.18.1. Cross-Gain Modulation -- 2.18.2. Cross-Phase Modulation -- 2.18.3. Four-Wave Mixing -- 2.18.4. Optical Frequency Shifting -- 2.19. Optical Phase-Locked Loops -- 2.20. Ring Resonators -- 2.21. Optical Attenuators -- 2.22. Optical Signal-to-Noise Ratio -- 2.22.1. Bit Error Rate -- 2.22.2. BER and Eye Diagram -- 2.23. New Materials and Components -- 2.23.1. Optical Materials -- 2.23.2. Hollow Fibers -- 2.23.3. Lasers and Receivers -- 2.23.4. Optical Cross-Connects -- 2.23.5. Optical Memories -- 2.23.6. Optical Integration -- Exercises -- References -- Standards / 233 -- 3. Communications Fundamentals -- 3.1. Introduction -- 3.2. Pulse Coded Modulation -- 3.3. Loop Accessing Methods -- 3.3.1. xDSL -- 3.3.2. Other High-Speed Short-Reach Technologies -- 3.4. Time Division Multiplexing Systems -- 3.4.1. Access and Pair-Gain Systems -- 3.4.2. Fiber-to-the-Home Technology -- 3.4.3. Switching Systems -- 3.4.4. Digital Cross-Connect Systems -- 3.5. Getting Connected -- 3.6. Data Systems -- 3.6.1. The OSI Model -- 3.6.2. Local Area Networks -- 3.6.3. Packet Networks -- 3.6.4. Frame Relay -- 3.6.5. ATM -- 3.6.6. Quality of Service -- 3.7. SONET and SDH -- 3.7.1. SONET Topologies -- 3.7.2. SONET and SDH Rates -- 3.7.3. SONET and SDH Frames -- 3.7.4. Floating Frames and Pointers -- 3.7.5. Overhead Definition -- 3.7.6. Frequency Justification -- 3.7.7. Path Overhead -- 3.7.8. Maintenance -- 3.7.9. Operations Communications Interface -- 3.7.10. Interworking -- 3.7.11. Next-Generation SONET -- 3.8. Internet -- 3.8.1. Voice over IP -- 3.8.2. Fax over IP (FoIP) -- 3.8.3. ATM over SONET -- 3.8.4. IP over SONET -- 3.9. Optical Networks -- 3.10. What Is a DWDM System and Network? -- Exercises -- References -- Standards -- 4 .DWDM Systems -- 4.1. Introduction.
505 8# - FORMATTED CONTENTS NOTE
Remark 2 4.2. DWDM Network Topologies-Review -- 4.3. DWDM Systems and Network Layers -- 4.3.1. DWDM and Standards -- 4.3.2. Domains or Functions -- 4.3.3. System Partitioning and Remoting -- 4.4. Key Building Blocks of a DWDM System -- 4.4.1. Transmitters and Receivers -- 4.4.2. Optical Amplifiers and Regenerators -- 4.4.3. Dispersion Compensating Solutions -- 4.4.4. Optical Gain Equalizers -- 4.4.5. Optical Wavelength Translators -- 4.4.6. Timing -- 4.4.7. Optical Switching -- 4.4.8. Control Architectures and Controllers -- 4.4.9. Interfaces -- 4.5. Wavelength Management Strategy -- 4.6. Equipment Sensing Strategy -- 4.7. Fault Detection and Reporting Strategy -- 4.7.1. Fault Detection on the Network Level -- 4.7.2. Fault Detection Identifiers -- 4.7.3. Overhead, Data, and Error Correction: The Digital Wrapper -- 4.8. Power Strategy -- 4.9. DWDM Systems by Network Layer -- 4.9.1. Point-to-Point Systems -- 4.9.2. Large Optical Cross-Connect Systems -- 4.9.3. DWDM Metro Systems -- 4.9.4. Access DWDM Systems and First/Last Mile -- 4.10. Protected and Unprotected Systems -- 4.11. Engineering DWDM Systems -- 4.11.1. Parameters That Influence Optical Design -- 4.11.2. ITU-T Recommended Frequencies -- 4.11.3. Channel Capacity, Width, and Spacing -- 4.11.4. Channel Bit Rate and Modulation -- 4.11.5. Multichannel Frequency Stabilization -- 4.11.6. BER and Channel Performance -- 4.11.7. Channel Dispersion -- 4.11.8. Power Launched -- 4.11.9. Optical Amplification and Compensation -- 4.11.10. The Fiber-Medium and Limitations -- 4.11.11. Optical Power Budget -- 4.11.12. Power Budget Calculations by Example -- Conclusions -- Exercises -- References -- Standards -- 5. DWDM Networks -- 5.1. Introduction -- 5.1.1. Multiprotocol Label Switching -- 5.1.2. MPS -- 5.1.3. DiffServ, IntServ, and MPLS -- 5.1.4. Optical Virtual Path Network -- 5.1.5. Network Layers and Protection -- 5.1.6. The Evolving Telecommunications Management Network -- 5.2. The Optical Transport Network -- 5.3. DWDM Network Topologies and Restoration Strategies.
505 8# - FORMATTED CONTENTS NOTE
Remark 2 5.3.1. Point-to-Point Topology -- 5.3.2. Ring Topology -- 5.3.3. Mesh Topology -- 5.3.4. Ring-Mesh Networks -- 5.4. Dispersion Management -- 5.5. Bandwidth Management -- 5.5.1. Wavelength Management -- 5.5.2. Traffic Management -- 5.5.3. Congestion Management -- 5.6. Fiber Span Between Transmitter and Receiver -- 5.7. Fault Management -- 5.8. Network Security -- 5.9. DWDM Network Issues -- 5.9.1. Interoperability and Internetworking -- 5.9.2. Optical Performance Monitoring -- 5.9.3. Network Future-Proofing -- 5.9.4. Wavelength Sharing -- 5.9.5. IP/SONET over DWDM -- 5.9.6. Maintenance -- 5.9.7. DWDM Network Management -- 5.10. Wireless DWDM Networks -- Exercises -- References -- Standards -- 6. Emerging Technologies -- 6.1. Introduction -- 6.2. Emerging Technologies -- 6.2.1. Theory and New Materials -- 6.2.2. Communications Components, Systems, and Networks -- 6.2.3. Intelligent Homes -- 6.2.4. Intelligent Transportation -- 6.2.5. Intelligent Powering Systems -- 6.3. Current Research -- 6.3.1. Advanced Lasers -- 6.3.2. Artificial Optical Materials -- 6.3.3. Optical Cross-Connect -- 6.3.4. Optical Memories and Variable Delay Lines -- 6.3.5. Nonintrusive Optical Sensors -- 6.4. Conclusion -- References -- Standards -- Answers to Exercises -- Acronyms -- Index -- About the Author.
520 ## - SUMMARY, ETC.
Summary, etc An A-to-Z look at an increasingly important technology: DWDM The race for unprecedented bandwidth is on - and DWDM(Dense Wave-length Division Multiplexing) is opening the way. DWDM is the technology that allows multiple streams of data to flow in one optical fiber of optical communication network. DWDM is the key technology at the heart of new systems and networks that offers more bandwidth at less cost. Soon, DWDM promises to change bandwidth from a premium to a commodity item. DWDM: Networks, Devices, and Technology provides a comprehensive treatment of DWDM, its technology, systems, and networks, as well as engineering design. It explains how DWDM works, how it is used in system design, how optical network architecture can benefit from DWDM, and what the design issues are. Written by an expert in the field, the book covers: . Current telecommunication networks and their issues. Current telecommunication systems and networks. New and emerging photonic technologies in development. Optical and photonic physics that describe DWDM components A the building blocks of DWDM - and how they are used. New optical systems, devices, and networks that are replacing electronics How optical and photonic devices are used in photonic systems. How DWDM systems are engineered and constructed using photonic components. The strengths, faults, efficiencies, and issues relevant to DWDM systems and networks. New emerging technologies Suitably detailed yet clear and concise, this is a comprehensive reference that makes this new technology wholly accessible to both practicing engineers and students.
650 #0 - SUBJECT ADDED ENTRY--SUBJECT 1
Subject Wavelength division multiplexing.
650 #0 - SUBJECT ADDED ENTRY--SUBJECT 1
Subject Optical communications.
650 #0 - SUBJECT ADDED ENTRY--SUBJECT 1
Subject Multiplexing.
856 42 - ELECTRONIC LOCATION AND ACCESS
Uniform Resource Identifier https://ieeexplore.ieee.org/xpl/bkabstractplus.jsp?bkn=5266229
942 ## - ADDED ENTRY ELEMENTS (KOHA)
Koha item type eBooks
264 #1 -
-- Piscataway, New Jersey :
-- IEEE Press,
-- 2003.
264 #2 -
-- [Piscataqay, New Jersey] :
-- IEEE Xplore,
-- [2002]
336 ## -
-- text
-- rdacontent
337 ## -
-- electronic
-- isbdmedia
338 ## -
-- online resource
-- rdacarrier
588 ## -
-- Description based on PDF viewed 12/21/2015.
695 ## -
-- Lenses
695 ## -
-- Multiprotocol label switching
695 ## -
-- Network topology
695 ## -
-- Optical amplifiers
695 ## -
-- Optical devices
695 ## -
-- Optical fiber amplifiers
695 ## -
-- Optical fiber networks
695 ## -
-- Optical fiber polarization
695 ## -
-- Optical fiber sensors
695 ## -
-- Optical fibers
695 ## -
-- Optical filters
695 ## -
-- Optical imaging
695 ## -
-- Optical polarization
695 ## -
-- Optical reflection
695 ## -
-- Optical refraction
695 ## -
-- Optical switches
695 ## -
-- Optical variables measurement
695 ## -
-- Photonics
695 ## -
-- Quality of service
695 ## -
-- Telephony
695 ## -
-- Terminology
695 ## -
-- Wavelength division multiplexing
695 ## -
-- Bandwidth
695 ## -
-- Biographies
695 ## -
-- Bit rate
695 ## -
-- Codecs
695 ## -
-- Coils
695 ## -
-- Copper
695 ## -
-- DSL
695 ## -
-- Electromagnetic scattering
695 ## -
-- IP networks
695 ## -
-- Indexes

No items available.