Multiwavelength Optical Networks: A Layered Approach - Hardcover

Über die Autorin bzw. den Autor

Thomas E. Stern holds the Dicker Chair in Electrical Engineering at Columbia University. He has served in various leadership roles at Columbia, including department chair, technical director of the Center for Telecommunications Research, and leader of the CTR Lightwave Networks Research Group. Professor Stern is an IEEE Fellow, holds several patents, and has authored more than a hundred papers on networking and related topics. Balachander Krishnamurthyof AT&T Labs Research is a well-known researcher with over a score of publications in the World Wide Web and networking fields alone. He has given tutorials on the Web at several conferences, published over 45 technical papers, co-authored and edited 'Practical Reusable UNIX Software' and was the series editor for the 'Trends in Software' series of books. He holds several patents and has given invited talks in over thirty countries. His recent papers can be found in http://www.research.att.com/~bala/papers.

020130967XAB04062001

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Written by leading authorities in optical networking, this book explores wide area wavelength-division multiplexing now that commercial deployment is at hand. After an overview of the enabling technology, the authors focus on methodologies for network analysis, control, design, and protection from a layered multiwavelength network architecture point of view.

The book presents four architecture categories, in increasing order of complexity:

• Shared channel networks, which use optical multiplexing and multiple access to provide multipoint connectivity on a static optical layer
• Wavelength-routed networks, which use optical switching to provide point-to-point connectivity over a reconfigurable optical layer
• Linear lightwave networks, which support multipoint connectivity over a reconfigurable optical layer
• Hybrid, logically routed networks, using electronically switched overlays to provide virtual connectivity on a reconfigurable optical layer

Procedures for network control and design are covered for each category of network and are illustrated with examples. The emphasis here is on the fundamental role of available network resources--optical spectrum, fiber topology, and switching node and access station functionality--in determining network performance. Important topics covered are:

• Multiplexing and multiple access in the optical domain
• Effective techniques for physical layer simulation
• Optical switch designs to circumvent component imperfections, plus coverage of optical layer packet switching
• New and efficient algorithms for routing and wavelength assignment
• Combining the advantages of optical transparency and electronic switching
• Network survivability and fault recovery
• Recent commercial trends in multiwavelength optical networking and practical deployment issues that may arise, including cost, flexibility, and performance tradeoffs