TY - GEN
T1 - Copernicus
T2 - 2011 International Conference for High Performance Computing, Networking, Storage and Analysis, SC11
AU - Pronk, Sander
AU - Larsson, Per
AU - Pouya, Iman
AU - Bowman, Gregory R.
AU - Haque, Imran S.
AU - Beauchamp, Kyle
AU - Hess, Berk
AU - Pande, Vijay S.
AU - Kasson, Peter M.
AU - Lindahl, Erik
PY - 2011
Y1 - 2011
N2 - Biomolecular simulation is a core application on supercomputers, but it is exceptionally difficult to achieve the strong scaling necessary to reach biologically relevant timescales. Here, we present a new paradigm for parallel adaptive molecular dynamics and a publicly available implementation: Copernicus. This framework combines performance-leading molecular dynamics parallelized on three levels (SIMD, threads, and message-passing) with kinetic clustering, statistical model building and real-time result monitoring. Copernicus enables execution as single parallel jobs with automatic resource allocation. Even for a small protein such as villin (9,864 atoms), Copernicus exhibits near-linear strong scaling from 1 to 5,376 AMD cores. Starting from extended chains we observe structures 0.6 Å from the native state within 30h, and achieve sufficient sampling to predict the native state without a priori knowledge after 80-90h. To match Copernicus'efficiency, a classical simulation would have to exceed 50 microseconds per day, currently infeasible even with custom hardware designed for simulations.
AB - Biomolecular simulation is a core application on supercomputers, but it is exceptionally difficult to achieve the strong scaling necessary to reach biologically relevant timescales. Here, we present a new paradigm for parallel adaptive molecular dynamics and a publicly available implementation: Copernicus. This framework combines performance-leading molecular dynamics parallelized on three levels (SIMD, threads, and message-passing) with kinetic clustering, statistical model building and real-time result monitoring. Copernicus enables execution as single parallel jobs with automatic resource allocation. Even for a small protein such as villin (9,864 atoms), Copernicus exhibits near-linear strong scaling from 1 to 5,376 AMD cores. Starting from extended chains we observe structures 0.6 Å from the native state within 30h, and achieve sufficient sampling to predict the native state without a priori knowledge after 80-90h. To match Copernicus'efficiency, a classical simulation would have to exceed 50 microseconds per day, currently infeasible even with custom hardware designed for simulations.
UR - http://www.scopus.com/inward/record.url?scp=83155193238&partnerID=8YFLogxK
U2 - 10.1145/2063384.2063465
DO - 10.1145/2063384.2063465
M3 - Conference contribution
AN - SCOPUS:83155193238
SN - 9781450307710
T3 - Proceedings of 2011 SC - International Conference for High Performance Computing, Networking, Storage and Analysis
BT - Proceedings of 2011 SC - International Conference for High Performance Computing, Networking, Storage and Analysis
Y2 - 12 November 2011 through 18 November 2011
ER -