Optical Network is Key to Next-Generation Research Cyberinfrastructure

[Kevin Meynell <meynell@xxxxxxxxxx>]

Optical Network is Key to Next-Generation Research Cyberinfrastructure

11 June 2008, San Diego, CA and Las Vegas, NV -- 
The director of the California Institute for 
Telecommunications and Information Technology 
(Calit2 - http://www.calit2.net/), a partnership 
of UC San Diego (http://www.ucsd.edu/) and UC 
Irvine (http://www.uci.edu/), said today that all 
the pieces are in place for a revolution in the 
usability of remote high performance computers to 
advance science across many disciplines. He urged 
early adopter application scientists to drive the 
creation of end-to-end dedicated lightpaths 
connecting remote supercomputers to their labs, 
greatly enhancing their local capability to 
analyze visually massive datasets generated by 
the TeraGrid (http://www.teragrid.org/) terascale to petascale computers.

In a featured keynote today at the TeraGrid 08 
Conference being held in Las Vegas this week, 
Calit2 Director Larry Smarr said the last ten 
years have established the state, regional, 
national, and global optical networks needed for 
this revolution, but the bottleneck is on the 
user's campus. However, as a result of research 
funded by the National Science Foundation (NSF) 
(http://www.nsf.gov/), there now is a clear path 
forward to removing this last bottleneck.

This opens the possibility for end users of the 
NSF's TeraGrid to begin to adopt these optical 
network technologies. The TeraGrid integrates 
high-performance computers, data resources and 
tools, and high-end experimental facilities from 
the eleven partner sites around the country.

"The NSF-funded OptIPuter project has been 
exploring for six years how user-controlled, 
wide-area, high-bandwidth lightpaths termed 
'lambdas' – on fiber optics can provide direct 
uncongested access to global data repositories, 
scientific instruments and high performance 
computational resources from the researchers' 
Linux clusters in their campus laboratories," 
said Smarr. "This research is now being rapidly 
adopted because universities are beginning to 
acquire lambda access through state or regional 
optical networks interconnected with the National 
LambdaRail (http://www.nlr.net/), the Internet2 
Dynamic Circuit Network 
(http://www.internet2.edu/network/dc/), and the 
Global Lambda Integrated Facility (http://www.glif.is/)."

The OptIPuter project, led by Smarr, is not 
designed to scale to millions of sites like the 
normal shared Internet, but to create private 
networks with much higher levels of data volume, 
accuracy, and timeliness for a few data-intensive 
research and education sites. Led by Calit2, the 
San Diego Supercomputer Center (SDSC - 
(http://www.sdsc.edu/), and the University of 
Illinois at Chicago's Electronic Visualization 
Laboratory (EVL - http://www.evl.uic.edu/), 
OptIPuter ties together the efforts of researchers from over a dozen campuses.

The OptIPuter uses dedicated lightpaths to form 
end-to-end uncongested 1- or 10-Gbps Internet 
protocol (IP) networks. The OptIPuter's dedicated 
network infrastructure – and supporting software 
– has a number of significant advantages over 
shared Internet connections, including high 
bandwidth, controlled performance (no jitter), 
lower cost per unit bandwidth, and security. The 
OptIPuter essentially completes the Grid program, 
said Smarr. In addition to allowing the end user 
to discover, reserve, and integrate remote 
computers, storage, and instruments, the 
OptIPuter enables the user to do the same for 
dedicated lambdas, creating a high-performance LambdaGrid.

In his talk, Smarr described how the 
user-configurable OptIPuter global platform is 
already being used for research in collaborative 
work environments, digital cinema, biomedical 
instrumentation, and marine microbial 
metagenomics. He issued a challenge to the 
TeraGrid users to begin to adopt this technology 
to support remote use of the TeraGrid resources.

"OptIPuter technologies can enhance the ability 
of scientists to use remote high-performance 
computing resources from their local labs, 
particularly applications with persistent large 
data flows, real-time visualization and 
collaboration, and remote steering", Smarr said.

A key OptIPuter technology, the OptIPortal, was 
prototyped by EVL and developed by Calit2 under 
the NSF-funded OptIPuter partnership. The 
OptIPortal is a networked and scalable, 
high-resolution LCD tiled display system, driven 
by a PC graphics cluster. Designed for the user's 
laboratory, each OptIPortal can be constructed 
with commodity commercial displays and 
processors. While most of the PC clusters run 
Linux, there are some that run on Mac (Calit2@UC 
Irvine and UCSD's Scripps Institution of 
Oceanography) or on Windows (UCSD's National 
Center for Microscopy and Imaging Research) clusters.

OptIPortals are the appropriate termination 
device for 10 Gbps lambdas, allowing the end user 
to choose the right amount of local storage, 
compute, and graphics capacity needed for their 
application, said Smarr. In addition, the tiled 
walls provide the scalable pixel real estate 
necessary to analyze visually the complexity of supercomputing runs.

The OptIPuter project prefers OptIPortal clusters 
to run on SDSC's Rocks 
(http://www.rocksclusters.org/), an open-source 
Linux cluster distribution that enables end users 
to easily build computational clusters, grid 
endpoints and visualization tiled-display walls. 
Rocks is developed under an NSF-funded SDCI 
project led by SDSC's Philip Papadopoulos, who is 
also a co-principal investigator on the OptIPuter 
project. There are currently over 1,300 
registered clusters running Rocks, providing a 
global and vibrant open-source software 
community. The Rocks 'Rolls' provide a convenient 
method of distribution of software innovations coming from community members.

OptIPortals range in size from four to 60 tiles, 
offering screen resolutions ranging from 8 
million pixels to the nearly-a-billion-pixel 
HIPerSpace wall – the highest-resolution display 
system in the world, located in the Calit2 
building on the UCSD campus. OptIPortals do not 
need to be restricted to planar tiled walls, 
Smarr said. Smarr showed pictures of Calit2's 
StarCAVE immersive environment driven by 34 
high-definition projectors, and a 60-LCD 
semi-cylindrical tiled wall autostereo Varrier 
display, both providing three-dimensional virtual 
reality, driven by the same type of Linux 
clusters that drive the HIPerWall, all connected 
at multiples of 10Gbps to the OptIPuter.

To handle multi-gigabit video streams, OptIPuter 
researchers at EVL developed the Scalable 
Adaptive Graphics Environment (SAGE), specialized 
graphics middleware that supports collaborative 
scientific visualization environments with 
potentially hundreds of megapixels of contiguous 
display resolution. In collaborative scientific 
visualization, it is crucial to share 
high-resolution imagery as well as 
high-definition video among groups of collaborators at local or remote sites.

SAGE enables the real-time streaming of extremely 
high-resolution content such as 
ultra-high-resolution 2D and 3D computer graphics 
from remote rendering and compute clusters and 
storage devices, as well as high-definition video 
camera output to scalable tiled display walls 
over high-speed networks. SAGE serves as a window 
manager, allowing users to move, resize, and 
overlap windows as easily as on standard desktop 
computers. SAGE also has standard collaboration 
desktop tools, such as image viewer, video 
player, and desktop sharing capabilities, 
enabling participants to resize, pan, zoom and move through the data.

In addition to SAGE other windowing software 
environments have been developed by research 
groups that were not part of the original NSF 
proposal, including the Calit2 lab of UCSD 
Professor Falko Kuester, developer of Cluster 
CGX, which allows OpenGL applications to be 
displayed on a visualization cluster like a tiled display.

Although scalable visualization displays have 
been under development for over a decade, first 
as arrays of projectors, the use of commodity 
hardware and open-source software in the 
OptIPortal makes this visualization power 
affordable to individual researchers. The typical 
cost of an N-tiled wall is about the same as N/2 
deskside PCs. As a result, adoption of 
OptIPortals has been rapid over the past two 
years. Besides the United States there are 
OptIPortals installed in Australia , Taiwan, 
China, Japan, Korea, Canada, the UK ,the 
Netherlands, Switzerland, the Czech Republic, and 
Russia, as well as a number of corporations.

However, there has been a critical 'missing link' 
blocking widespread adoption of the 
OptIPuter/OptIPortal metacomputer: few campuses 
have installed the optical fiber paths needed to 
connect from the regional optical network campus 
gateway to the end user. Smarr quoted NSF 
Director Arden Bement, who three years ago said 
prophetically: "Those massive conduits [e.g. NLR 
lambdas] are reduced to two-lane roads at most 
college and university campuses. Improving 
cyberinfrastructure will transform the 
capabilities of campus-based scientists."

To make effective use of the 10Gbps lightpaths 
from the TeraGrid resources to the campus 
gateways, Smarr said, "the user's campus must 
invest in the equivalent of city data freeway 
systems of switched optical fibers connecting the 
campus gateway to specific buildings and inside 
the buildings to the user's lab."

A full scale experiment of this vision is 
underway at UCSD with funds provided by the 
campus and an NSF-funded Major Research 
Instrumentation grant called Quartzite, which has 
SDSC's Papadopoulos as PI and Calit2's Smarr as 
one of the co-PIs. The Quartzite optical 
infrastructure includes a hybrid packet-circuit 
switched environment, interconnecting over 45 
installed 10Gbps channels crisscrossing the UC 
San Diego campus, with 15 more planned by the end 
of this year. More than 400 endpoints are 
connected to Quartzite through access or direct 
connection to the core switch. Geographically, 
these are located in seven different buildings, 
including 17 laboratories within these buildings. 
Large projects (CAMERA, CineGrid) use Quartzite directly.

The Quartzite switching complex is able to switch 
packets, wavelengths or entire fiber paths, 
allowing fast configuration, under software 
control, of the different types of network 
layouts and capabilities required by the end 
user. This optical complex will provide this year 
an aggregate bandwidth of ~½ Terabit/sec from 
dedicated lightpaths coming into a central, 
reconfigurable switching complex and from there 
connecting to UCSD researchers. This testbed also 
enables a broad set of 'Green 
Cyberinfrastructure' research projects to be 
conducted on a campus scale. As a result, we can 
experiment at UCSD with one model of the 'campus 
of the future', from which robust solutions can 
be provided to other interested campuses.

"Quartzite provides the 'golden spike' which 
allows completion of end-to-end 10Gbps lightpaths 
running from TeraGrid sites to the remote user's 
lab", said Smarr, adding: "Like the OptIPortal, 
Quartzite was designed using commercial 
technologies that can be easily installed on any campus."

With this complete end-to-end OptIPuter now in 
hand, the stage is set for a wide variety of 
applications to be developed over this global 
high performance cyberinfrastructure. "When we 
were conceptualizing the OptIPuter seven years 
ago, I always thought that remote supercomputer 
users would provide the killer applications," 
said Smarr, the founding director in 1985 of the 
National Center for Supercomputing Applications 
(NCSA). "TeraGrid users are located in research 
campuses across the nation, but they all share 
the characteristic that they need to carry out 
interactive visual analysis of massive datasets 
generated by a remote supercomputer."

Smarr showed a number of DoE, NASA, and NSF 
supercomputer centers that have large tiled 
projector walls located in the center for visual 
analysis of these complexities. "The time has 
come to take that capability out to end users in 
their labs with local OptIPortals connected to 
the supercomputer center using the OptIPuter," 
said Smarr. "I believe that we will see early 
adopters step forward in the next year to set up 
prototypes of this cyberarchitecture."

Smarr described the work of one such early 
adopter, Michael Norman, UCSD Professor of 
Physics, recently named SDSC's Chief Scientific 
Officer. Norman is designing an OptIPortal in the 
new SDSC building, to be dedicated in October 
2008, for use by his Laboratory for Computational 
Astrophysics. It will be connected over the UCSD 
optical complex described above to the TeraGrid 
10Gbps backbone and National LambdaRail and used 
to visualize results from his cosmology 
simulations on the NSF's Petascale Track II 
machines at the Texas Advanced Computing Center 
and at the University of Tennessee/Oak Ridge 
National Laboratory's National Institute for 
Computational Sciences. Norman plans to stage and 
analyze the terabytes of data generated at SDSC, 
using the campus optical fiber network to move 
the data into specialized OptIPortals at Calit2, 
such as the StarCAVE and HIPerSpace wall.

To make this OptIPuter distributed analysis more 
efficient, EVL has developed LambdaRAM, which can 
prefetch data from disk storage and temporarily 
store it in the cluster's Random Access Memory 
(RAM), masking the substantial disk I/O latency, 
and then move the data from this 'staging' 
computer to the computer running the simulation. 
Smarr showed how NASA Goddard Space Flight Center 
in Maryland uses the OptIPuter and LambdaRAM to 
optimize the use of NLR for severe storm and 
hurricane forecasts carried out at the Project 
Columbia supercomputer at NASA Ames in Mountain 
View, California, and to zoom and pan 
interactively through ultra-high-resolution 
images on local OptIPortals at Goddard. EVL 
modified LambdaRAM so that it would work 
seamlessly with legacy applications to locally 
access large data files generated by the remote supercomputer.

Finally, Smarr described how, with the 
integration of high definition and digital cinema 
video streams, which easily fit inside a 10 Gbps 
lightpath, the OptIPuter architecture is rapidly 
creating an OptIPlanet Collaboratory in which 
multiple scientists can analyze a complex dataset 
while seeing and talking to each other as if they 
were physically in the same room. Smarr showed 
photos of 'telepresence' sessions in January and 
May 2008 where this was demonstrated on a global 
basis between Calit2 at UC San Diego and the 
100-Megapixel 'OzIPortal', constructed earlier 
this year at the University of Melbourne in 
Australia, connected over a transpacific gigabit 
lightpath on Australia's Academic and Research 
Network (AARNet). "Petascale problems will 
require geographically distributed 
multidisciplinary teams analyzing enormous data 
sets—a perfect application of the OptIPlanet Collaboratory," said Smarr.

In conclusion, Smarr said, "After a decade of 
research carried out at dozens of institutions, 
we are seeing the OptIPuter take off on a global 
basis. I look forward to working with many of the 
TeraGrid '08 participants as they become early 
adopters of this innovative, high performance 
cyberinfrastructure—rebalancing the local 
analysis and network connectivity with the 
awesome growth NSF has made possible in the emerging petascale computers."

In addition to Smarr and Papadapoulos, 
co-principal investigators on the OptIPuter 
initiative include Calit2's Thomas DeFanti; Jason 
Leigh, from the University of Illinois at 
Chicago; and Mark Ellisman, from UC San Diego. 
The project manager is Maxine Brown, from the 
University of Illinois at Chicago. Andrew Chien, 
now Vice President of Research at Intel, served 
as the system software architect while he was at UCSD.

The NSF-funded TeraGrid links compute resources 
among 11 partner sites across the U.S. It 
currently has a combined compute capability 
approaching one petaflop (10^15 calculations per 
second), or equal to the computing power of about 200,000 typical laptops.

The full press release including photographs may 
be found at http://www.calit2.net/newsroom/release.php?id=1307