Ciena, Caltech demo 100G payload over single wavelength

Dec. 8, 2008
DECEMBER 8, 2008 -- Unlike previous 100G tests that combined two 40G optical signals or inversely multiplexed ten 10G optical signals, Ciena and Caltech say their demonstration offered the first true, single wavelength transmission of a 100G data stream, through 80 km of fiber.

DECEMBER 8, 2008 -- Ciena Corp. (search for Ciena) today announced the successful demonstration of what it claims was the industry's first true, single-wavelength 100G optical transmission during the Supercomputing Conference 2008 (SC08), held in late November. Driven by Ciena's expertise in optical technologies and the California Institute of Technology's (Caltech) commitment to the advancement of high-performance distributed computing methods, the live demonstration enabled 100-Gbit/sec connectivity between computer clusters using a single wavelength.

Unlike previous 100G tests that combined two 40G optical signals or inversely multiplexed ten 10G optical signals, Ciena and Caltech say their demonstration offered the first true, single wavelength transmission of a 100G data stream, through 80 km of fiber. Ciena electrically combined ten 10-Gigabit Ethernet (10-GbE) signals from switches in the Caltech exhibit area onto a single wavelength for transmission over Ciena's CN 4200 RS FlexSelect Advanced Services Platform, then returned the separated 10-GbE signals back to Caltech's booth. The transmission featured an actual line rate of 112 Gbits/sec and a true 100-Gbit/sec OTN-framed payload using enhanced forward error correction (EFEC). And, by interoperating with leading switching technologies and using FDT, a production-ready TCP application developed by Caltech, more than one petabyte (one million gigabytes) of data, roughly equivalent to that of 125,000 full-length DVDs, was transferred during a 12-hour period.

"The collaborative efforts of Ciena and our Caltech-led high energy physics team represent a critical milestone in the industry's roadmap for transitioning from 10G to 100G links, particularly across existing transoceanic fiber spans," reports Professor Harvey Newman of Caltech, head of the high energy physics team and chair of the U.S. Large Hadron Collider (LHC) Users Organization's Executive Committee. "Faster link transmission of this kind allows, for example, Caltech and researchers from CERN to instantly share critical data associated with the LHC project by increasing the capacity and efficiency of the U.S. Large Hadron Collider Network (USLHCNet). In particular, we hope developments such as these will afford physicists and students throughout the world the opportunity to participate directly in the LHC program and potentially make important scientific discoveries," he adds.

In real-word applications, where there are bi-directional links involved (one 100G wavelength in each direction), the maximum capacity for data flowing in both directions is 200G. In this context of a bi-directional model, the demonstration achieved a net payload average of 191 Gbits/sec during the 12-hour period, as sourced and measured by the Caltech TCP application.

The full C-band tunable transceiver in Ciena's CN 4200 RS used dual polarization RZ-DQPSK modulation, allowing for deployment alongside 10G and 40G channels on existing DWDM systems and enabling scalability up to 8 Tbits/sec capacity on an U optical fiber with existing Ciena DWDM systems. The transceiver's hardware technology employs a flexible architecture that is capable of adapting to any standard 10G client rate utilizing standard XFP optical modules, while the firmware allows for rapid adaptation to emerging OTN standards, say Ciena representatives.

"This demonstration illustrates Ciena's dedication to optical innovation and ensures our customers are provided a view into the next phase of transport technologies and the possibilities ahead," contends Steve Alexander, chief technology officer at Ciena. "With this technical accomplishment, we've set the stage for taking today's service-driven networks to new levels of capacity with even greater potential for the advancement of next-generation applications."


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