| [June 18, 2013] |
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IDC Announces New Winners of HPC Innovation Excellence Awards
LEIPZIG, Germany --(Business Wire)--
International Data Corporation (IDC)
today announced the fifth round of recipients of the HPC
Innovation Excellence Award at the ISC'13
supercomputer industry conference in Leipzig, Germany. Prior winners
were announced at the ISC'11, SC'11, ISC'12, and SC'12 supercomputing
conferences.
The HPC Innovation Excellence Award recognizes noteworthy achievements
by users of high performance computing (HPC) technologies. The program's
main goals are to showcase return on investment (ROI) and scientific
success stories involving HPC; to help other users better understand the
benefits of adopting HPC and justify HPC investments, especially for
small and medium-size businesses (SMBs); to demonstrate the value of HPC
to funding bodies and politicians; and to expand public support for
increased HPC investments.
"IDC research has shown that HPC can impact innovation cycles greatly
and can potentially generate ROI. The award program aims to collect a
large set of success stories across many research disciplines,
industries, and application areas," said Chirag Dekate, Research
Manager, High Performance Computing at IDC. "The winners achieved clear
success in applying HPC to greatly improve business ROI, scientific
advancement, and/or engineering successes. Many of the achievements also
directly benefit society."
Winners of the first four rounds of awards, announced in 2011 and 2012,
included 24 organizations from the U.S., three from the People's
Republic of China, one from Canada, two from India, and one each from
Australia and Spain.
The new award winners and project leaders announced at ISC'13 are as
follows (contact IDC for additional details about the projects):
-
Alenia Aermacchi (Italy). Engineers at Alenia Aermacchi
utilized technical computing and scientific computing tools in the
"Clean Sky" project to design a new generation of environmentally
friendly aircraft. While seeking the most promising configuration, the
engineers shaped two different wings to fulfill separately the two
goals of enhancing aerodynamic performance and reducing wing weight.
This was accomplished through the use of computational fluid dynamics
(CFD) and other technical computing tools. The two promising
configurations enhanced cruise efficiency by 2.5% and reduced the wing
weigh by 4%. Lead: Enrica Marentino
-
High Performance GeoComputing Laboratory at the University of
California at San Diego (U.S.). The High Performance
GeoComputing Laboratory, University of California at San Diego, has
developed a highly scalable and efficient GPU-based finite difference
code based on AWP-ODC, a community code developed and supported by the
Southern California Earthquake Center for large-scale earthquake
simulations. AWP-ODC-GPU achieved perfect scalability on the Oak Ridge
National Laboratory's Titan supercomputer and was used to simulate
realistic 0-10 Hz earthquake ground motions, the largest-ever
earthquake simulation performed. This code was re-structured to enable
maximized throughput, reduced time-to-solution, and scalability. The
code achieved 100% parallel efficiency on 8,192 GPUs and sustained
2.33 petaflop/sec. on Titan. Moreover, this GPU-powered code has been
transformed to calculate Strain Green Tensors, resulting in a 110-fold
speedup in key strain tensor calculations critical to probabilistic
seismic hazard analysis. This achievement makes a California
state-wide hazard model a goal reachable with existing supercomputers.
The performance of the code is expected to take physics-based seismic
hazard analysis to a new level using petascale, heterogeneous
computing resources, saving more than 500 million core-hours as
required by building engineering design. Lead: Yifeng Cui
-
DOD High Performance Computing Modernization Program (U.S.).
This HPCMP-supported project, within the armor/anti-armor portfolio,
provided direct support to the Warfighter program. The fundamental
goals for using modeling and simulation in support of the
armor/anti-armor development programs were to reduce time, resources,
and risk while improving the quality of information available to
designers, users, and decision makers. HPCMP capabilities enabled the
development and testing of new armor/anti-armor capabilities in the
following areas: propulsion, interior ballistics, external trajectory
determination, terminal ballistics, warhead analysis, and sensors. The
total upper bound ROI amounted to $935 million. Lead: Deborah
Schwartz
-
DOD High Performance Computing Modernization Program (U.S.).
This HPC innovation comprised a suite of cutting-edge computational
efficiency enhancement methodologies applied to complex
missile-related, aero-propulsive problems with combustion. These
methodologies were integrated into CRAFT CFD® and CRUNCH CFD®, two CFD
codes in widespread use by DoD to support missle design and
evaluation, and encompassed gas-phase/multi-phase combustion as well
as laminar/turbulent chemistry, including tabulated/neural network
approaches, reduced/adaptive chemistry, turbulent scalar fluctuation
model (SFM) and GPU acceleration. By leveraging state-of-the-art HPC
resources provided by DoD HPCMP, these innovative methodologies
delivered higher-fidelity predictive capabilities to the analysis of
missile systems/components, thereby enabling CFD to serve as a
cost-effective design tool and virtual testbed for missile evaluation. Lead:
John West
-
ESTECO and Airworks Engineering (Italy). Airworks, a
multidisciplinary company for mechanical engineering, was facing the
challenge of improving efficiency in converting wind energy into
electrical power by optimizing the whole assembly of a wind power unit
rotor. Experts in the firm's wind power unit, specialists in CAD
(computer-aided design) and CFD (computational fluid dynamics)
professionals from different organizations were involved in a complex
design scenario and needed to collaborate effectively. Engineers from
the University of Trieste prepared the parametric CAD model and set up
CFD simulations, while Airworks developed aerodynamic performance
calculations of the wind rotor blade and subsequently performed the
optimization analysis. The technical computing-driven solution enabled
the seamless execution of inter-organizational simulation workflows.
With the set up of the optimization workflow, Airworks professionals
were able to explore and evaluate new parametric geometry, leading to
innovative designs. The end result was a wind turbine design with an
outstanding power coefficient and an annual energy production increase
as high as 1.26%. Lead: Paolo Vercesi
-
University College London and NAG HECTOR dCSE (UK). HPC experts
from Numerical Algorithms Group (NAG), working under NAG's
Computational Science and Engineering (CSE) support service for
HECToR, the UK's national academic supercomputing facility, have
optimized a Quantum (News - Alert) Monte-Carlo application for multicore
architectures, resulting in a performance increase of a factor of
four. The objectives of this dCSE project were to enable the CASINO
Quantum Monte Carlo code to effectively use the multicore processors
of HECToR's Cray XT supercomputer and thus model more complex physical
systems with greater efficiency. Shared memory techniques were
introduced to allow larger models to be computed with greater
efficiency by enabling multiple MPI processes on a single node to
share a common data set, thus reducing the number of nodes needed for
a given simulation. Further work including hierarchical parallelism
with OpenMP and I/O optimizations improved the scalability of the
code, enabling CASINO to run 60-80% faster for simulations using more
than 10,000 cores. Following NAG's work, the scientists were able to
run on 40,000 cores of the Jaguar petascale supercomputer at Oak Ridge
National Laboratory. It is estimated that this dCSE work saved 12
million AUs (allocation units) for a one year research project on
HECToR, equivalent to savings of as much as £760,000 and the potential
for future savings of up to several million pounds. Lead: HECToR
dCSE
-
University of Warwick and NAG HECTOR dCSE (UK). HPC experts
from NAG, working under NAG's Computational Science and Engineering
(CSE) support service for HECToR, the UK's national academic
supercomputing facility, have improved the scalability and performance
of DL_POLY_3, a widely used software package for studying molecular
dynamics. The 20-fold improvement in performance achieved by this
project enabled a study of egg-shell formation that was infeasible
with previous performance. DL_POLY_3 is a general-purpose package for
classical molecular dynamics (MD) simulations from STFC Daresbury
Laboratory. University of Warwick researchers Mark Rodger and David
Quigley, in collaboration with colleagues at the University of
Sheffield, used DL_POLY_3 and the HECToR supercomputers to study the
role of a protein called ovocleidin-17 (OC-17) in chicken eggshell
formation. Significant performance improvements were needed to make
the modeling possible in feasible timescales using the HECToR
supercomputers, especially in terms of parallel I/O. Lead: HECToR
dCSE
-
Bottero S.p.A. (Italy). Bottero has recently introduced the
EMOC, a completely new family of Mold Opening and Closing (MOC)
mechanisms for the hollow glass industry. This complex project
combined the innovation, in terms of mold movement (speed and
precision), cooling system, maintenance facility ("top mounted"), and
maintaining compatibility with previous standards. This
multidimensional aspect led to hard space constraints, requiring
complex 3D kinematic schema, and required advanced CFD simulation and
design tools. A high performance level was required for this
mechanism, particularly regarding clamping forces in closed positions,
force available at the beginning of the molds stroke, reduced closing
time, absence of vibrations during movement, and robustness with
respect to irregularities in air supply. CFD tools and simulation
techniques were utilized to improve the design in EMOC. Lead:
Alberto Marino
-
Polestar Racing (Sweden). The Polestar Racing vehicle model had
to be modified without considering the chassis design parameters,
which were previously the core of the optimization analysis. Design
simulation acquired an even greater importance as the best combination
of the front-to-rear weight, aerodynamics, and brake distribution had
to be executed in three days. Polestar Racing utilized a suite of
simulation tools from MSC (News - Alert) Software, the Lap Time Simulation (LTS)
in-house code, and modeFRONTIER to devise a technical computing-driven
approach to improve performance. The resulting improvements in weight,
aerodynamics, and brake distribution led to lap time reductions
ranging from 0.19 to 0.50 seconds. Lead: Per Blomberg
-
RENCI (U.S.). Scientists and researchers at the Renaissance
Computing Institute (RENCI) developed a comprehensive informatics
framework called NCGENES, enabling medical decision support by
systemizing genomic analysis and high performance computing to mine
genomic data for clinical and research use. The framework tackles one
of the biggest challenges in genomic medicine - the need for automated
sorting of the millions of variants generated by genome-scale
sequencing to identify the very few with actual clinical relevance.
The innovative framework also provides a proof of principle for how
genomic medicine can be carried out in a practical manner. NCGENES
breaks new ground by guiding and defining best practices for the use
of whole genome sequencing as a diagnostic tool to aid patients and
clinicians in making sense of medical informatics. Lead: Phil Owen
-
RENCI - ADCIRC Surge Guidance System (U.S.). This system uses
the coupled coastal circulation, storm surge, and wind wave model
ADCIRC+SWAN to produce high-resolution forecasts of storm surge, near
shore waves, and water inundation when tropical or extra-tropical
storms threaten the U.S. Atlantic or Gulf Coasts. The complete system,
the ADCIRC Surge Guidance System (ASGS), includes an advanced
web-based display (NC-Coastal Emergency and Risk Assessment). During
an active storm, ASGS is run 2-4 times each day on a 150-node Dell
PowerEdge M610/cluster (2 x 2.8Ghz Intel (News - Alert) Nehalem-EP 5560, quad core)
at the Renaissance Computing Institute (RENCI). The outputs from these
runs are incorporated into guidance and forecasting efforts by the
National Weather Service, the National Hurricane Center, and agencies
such as the U.S. Coast Guard, the U.S. Army Corps of Engineers, FEMA,
and local and regional emergency management personnel. The resulting
forecasts are used for evacuation decisions, to position supplies and
response personnel, for search and rescue, and for other event-based
decision support as needed. Lead: Rick Luettich, Brian Blanton
"The Council on Competitiveness would like to congratulate all the
winners of the HPC Innovation Excellence Award and thank all of those
who submitted entries. The significance of HPC to the private sector
will only be fully appreciated when examples such as these are
recognized for their economic value," said Dr. Cynthia McIntyre, Senior
Vice President for the HPC Initiative at the Council
on Competitiveness.
IDC welcomes award entries from anywhere in the world. Entries may be
submitted at any time by completing the brief form available at https://www.hpcuserforum.com/innovationaward/.
New winners will be announced multiple times each year. Submissions must
contain a clear description of the dollar value or scientific value
received in order to qualify. The HPC User Forum Steering Committee
performs an initial ranking of the submissions, after which domain and
vertical experts are called on, as needed, to evaluate the submissions.
HPC Innovation Excellence Award sponsors include Adaptive Computing,
Altair, AMD (News - Alert), Ansys, Cray, Avetec/DICE, the Boeing Company, the Council
on Competitiveness, Department of Defense, Department of Energy, Ford
Motor Company, Hewlett Packard, HPCwire, insideHPC, Intel, Microsoft (News - Alert),
National Science Foundation, NCSA, Platform Computing, Scientific
Computing, and SGI.
The next round of HPC Innovation Excellence Award winners will be
announced at SC'13 in November 2013.
About IDC
International Data Corporation (IDC) is the premier global provider of
market intelligence, advisory services, and events for the information
technology, telecommunications, and consumer technology markets. IDC
helps IT professionals, business executives, and the investment
community to make fact-based decisions on technology purchases and
business strategy. More than 1,000 IDC analysts provide global,
regional, and local expertise on technology and industry opportunities
and trends in over 110 countries. For more than 49 years, IDC has
provided strategic insights to help our clients achieve their key
business objectives. IDC is a subsidiary of IDG, the world's leading
technology media, research, and events company. You can learn more about
IDC by visiting www.idc.com.
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of their respective holders.

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