Additionally, the partners will demonstrate applications of transparent connectivity and Glimmerglass' Photonic Multicasting technology at the SC 2003 conference, in the National Center for Data Mining at the UIC booth, to be held in Phoenix Arizona, November 15th – 21st, 2003.

The partnership recognizes the potential associated with the convergence of two new technologies, Grid middleware and affordable lambda networks, which is leading to the creation of LambdaGrids. Lambdas are wavelengths of laser light used to send parallel streams of data over a single optical fiber. These links are the superhighways, over which information between Grid computing nodes flows.

The Glimmerglass System 300E enables "streaming computing", the streaming of information, whether high-resolution imagery or massive databases, among the elements of the LambdaGrid with little or no latency. Grid developers, such as EVL, will experiment with the Glimmerglass system to dynamically offload large data-communications flows over optical networking test-beds. Because the Glimmerglass system switches lambdas transparently without detection and signal regeneration, it is "future-proof", able to support any transmission speed or protocol, such as Gigabit Ethernet, 10 Gigabit Ethernet and beyond, including standards not yet available today.

Using streaming computing, Glimmerglass and EVL will investigate the potential benefits of the System 300’s Photonic Multicasting, in which the Glimmerglass system replicates and transmits a lambda-stream carrying data to multiple computing resources on the LambdaGrid network. Separate, correlated operations can thus be simultaneously performed on each lambda-stream copy, such as a stereo rendering of image data. The Glimmerglass system can efficiently generate and transmit exact, synchronized copies of any lambda-stream without relying on higher layer protocols, such as TCP/IP or SONET.

EVL expects a paradigm shift in high-performance networks as applications move to new Grid-based system architectures, such as the OptIPuter, where the optical network acts like an enormous systems bus, connecting various data, computing and visualization components that are distributed globally. "The functional richness of elements like the Glimmerglass system is increasing all the time", stated Jason Leigh, Associate Professor of Computer Science at EVL. "Features such as Glimmerglass’ Photonic Multicasting technology should make it easier to advance my research on Amplified Collaborative Environments (ACEs), which arewar roomsfor distributed teams that share high-resolution immersive data visualizations.”

"Streaming computing’s lambda multicasting capability being developed by the EVL/Glimmerglass partnership have strong implications for my work on petabyte databases”, stated Robert Grossman, an EVL collaborator and Director of the National Center for Data Mining at the University of Illinois at Chicago. "With this technology, we can create virtual data warehouses on the fly from distributed databases by using lambda-streaming to dostreaming joins. As a first application, we will use streaming joins to improve distributed intrusion detection systems. This could be very important since distributed intrusion detection systems today produce so much data that a centralized data warehouse is no longer practical for real-time intrusion detection.”

EVL and Glimmerglass will collaborate to integrate their proof-of-concept investigations into applications-centric network middleware, enabling application developers to access advanced transparent connectivity capabilities of future LambdaGrids, thereby facilitating the adoption of these advanced micro-photonics products.