Application of Intelligent Signaling and Control of Dynamically Switched Optical Networks


Developers: Alan Verlo, Jason Leigh, Maxine Brown, Ruoyun Yang, Thomas A. DeFanti, Bill Nickless, Mort Rahimi, Tim Ward, Mitch Theys, Joe Mambretti, Andrew Schmidt, Linda Winkler

Funding: NSF

The proposed software development efforts will leverage the significant potential of a newly installed metro optical testbed for application-level dynamic control of resource discovery, allocation and adjustment. Efforts at many levels are required to make such flexibility available in service provisioning, infrastructure and service resource management:
  • Research into the behavior of advanced scientific applications, not just on extremely high-performance optical network, but on one that can be dynamically adjusted at a granular level
  • Identify application-level networking requirements, investigate management techniques for optical networks, and study new service provisioning models related to application needs
  • Research new methods for application signaling
  • Investigate interconnections between application signaling and IP-based control-plane methods, such as through GMPLS
  • Test deployment of those techniques on an advanced testbed and analyze results
  • Experiment with multiple-service provisioning to ensure gateways to traditional networks and protocols
  • Develop a system for performance metrics, monitoring and analysis
  • Create a testbed for StarLight, the next-generation, optically based STAR TAP, and for other advanced research networks

The testbed for this project is an a four-node optical network, OMNInet, initially linking a core node on Northwestern University’s Chicago campus with a node at the University of Illinois at Chicago, the Canadian Network for the Advancement of Research, Industry and Education (CANARIE) CA*net4 node at its Chicago Point of Presence and a node at Northwestern’s Evanston campus. The sites are separated by distances of 5 to 20 miles, connected by dedicated technology trial-fiber service provided by SBC / Ameritech. Each node includes a Nortel Networks WDM photonic switch, an Optical Fiber Amplifier (OFA) and high performance router / switches. These sites will also have access to Nortel and SBC / Ameritech testing personnel, expertise, and equipment. Participants in this project, led by the Electronic Visualization Laboratory (EVL) at the University of Illinois at Chicago, include the International Center for Advanced Internet Research at Northwestern University, CANARIE, Argonne National Laboratory, MREN (Metropolitan Area Research and Education Network), Nortel and Ameritech.

Email: tom@uic.edu

Date: September 1, 2001 - August 31, 2004

Related Entries

Directory:

Events:

Papers:

Research:

Related Categories