Geneva, 26 June 2003. Scientists at CERN1 and the California Institute of Technology2 (Caltech) have set a new Internet2 land speed record using the next-generation Internet protocol IPv6. The team sustained a single stream Transfer Control Protocol (TCP) rate of 983 megabits per second for more than one hour between CERN and Chicago, a distance of more than 7,000 kilometres. This is equivalent to transferring a full CD in 5.6 seconds.
The performance is remarkable because it overcomes two important challenges: IPv6 forwarding at Gigabit-per-second speeds, and high-speed TCP performance across high bandwidth/latency networks. This major step towards demonstrating how effectively IPv6 can be used should encourage scientists and engineers in many sectors of society to deploy the next-generation Internet protocol, Caltech researchers say.
This latest record by CERN and Caltech is a further step in an ongoing research-and-development program to develop high-speed global networks as the foundation of next generation data-intensive Grids. Caltech and CERN also hold the current Internet2 land speed record in the IPv4 class, where IPv4 is the traditional Internet protocol that carries 90 percent of the world's network traffic today. In collaboration with the Stanford Linear Accelerator Center (SLAC), Los Alamos National Laboratory, and the companies Cisco Systems, Level 3, and Intel, the team transferred one terabyte of data across 10,037 kilometres in less than one hour, from Sunnyvale, California, USA, to Geneva, Switzerland. This corresponds to a sustained TCP rate of 2.38 gigabits per second for more than one hour.
Multi-gigabit-per-second IPv4 and IPv6 end-to-end network performance will lead to new research and business models. People will be able to form "virtual organizations" of planetary scale, sharing in a flexible way their collective computing and data resources. In particular, this is vital for projects on the frontiers of science and engineering, projects such as particle physics, astronomy, bioinformatics, global climate modelling, and seismology.
Olivier Martin, head of external networking at CERN and manager of the DataTAG3 project, said, "These new records clearly demonstrate the maturity of IPv6 protocols and the availability of suitable off-the-shelf commercial products. They also establish the feasibility of transferring very large amounts of data using a single TCP/IP stream rather than multiple streams as has been customarily done until now by most researchers as a quick fix to TCP/IP's congestion avoidance algorithms. I am optimistic that the various research groups working on this issue will now quickly release new TCP/IP stacks having much better resilience to packet losses on long-distance multi-gigabit-per-second paths, thus allowing similar or even better records to be established across shared Internet backbones."
Harvey Newman, professor of physics at Caltech, said, "This is a major milestone towards our dynamic vision of globally distributed analysis in data-intensive, next-generation high-energy physics experiments. Terabyte-scale data transfers on demand, by hundreds of small groups and thousands of scientists and students spread around the world, is a basic element of this vision; one that our recent records show is realistic. IPv6, with its increased address space and security features is vital for the future of global networks, and especially for organizations such as ours, where scientists from all world regions are building computing clusters on an increasing scale, and where we use computers including wireless laptop and mobile devices in all aspects of our daily work."
"In the future, the use of IPv6 will allow us to avoid network address translations that tend to impede the use of video-advanced technologies for real-time collaboration," Newman added. "These developments also will empower the broader research community to use peer-to-peer and other advanced grid architectures in support of their computationally intensive scientific goals."
The team used the optical networking capabilities of the LHCnet, DataTAG, and StarLight and gratefully acknowledges support from the DataTAG project sponsored by the European Commission (EU Grant IST-2001-32459), the DOE Office of Science, High Energy and Nuclear Physics Division (DOE Grants DE-FG03-92-ER40701 and DE-FC02-01ER25459), and the National Science Foundation (Grants ANI 9730202, ANI-0230967, and PHY-0122557).
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at Caltech: Robert Tindol :+ 1 (626) 395-3631