Enabling and scaling biomolecular simulations of 100 million atoms on petascale machines with a multicore-optimized Message-driven runtim
International audienceExtreme scale parallel computing systems will have tens of thousands of option...
The Petascale Computing Enabling Technologies (PCET) project addressed challenges arising from curre...
c © The Authors 2015. This paper is published with open access at SuperFri.org Extreme scale paralle...
A 100-million-atom biomolecular simulation with NAMD is one of the three benchmarks for the NSF-fund...
Scientific applications in nanoscience, combustion modeling, fusion energy simulations, climate mode...
Remote atomic memory operations are critical for achieving high-performance synchronization in tight...
Multicore chips have become the standard building blocks for all current and future massively parall...
This paper introduces a conceptual 100BillionTransistor (100BT) SuperComputers-on-a-Chip consisting ...
Although the challenges to achieving petascale computing within the next decade are daunting, severa...
We describe the PetaByte-scale computing challenges posed by the next generation of particle physics...
The "internet of everything" envisions trillions of connected objects loaded with high-bandwidth sen...
already exist and run on Petascale class Supercomputers [1]. Modelers, programmers, and computer arc...
Within the next decade it will be possible to build chip multiprocessors with thousands of cores. We...
Atomic operations are crucial for most modern parallel and concurrent algorithms, which necessitates...
In this chapter we will argue that studying such multi-scale multi-science systems gives rise to inh...
International audienceExtreme scale parallel computing systems will have tens of thousands of option...
The Petascale Computing Enabling Technologies (PCET) project addressed challenges arising from curre...
c © The Authors 2015. This paper is published with open access at SuperFri.org Extreme scale paralle...
A 100-million-atom biomolecular simulation with NAMD is one of the three benchmarks for the NSF-fund...
Scientific applications in nanoscience, combustion modeling, fusion energy simulations, climate mode...
Remote atomic memory operations are critical for achieving high-performance synchronization in tight...
Multicore chips have become the standard building blocks for all current and future massively parall...
This paper introduces a conceptual 100BillionTransistor (100BT) SuperComputers-on-a-Chip consisting ...
Although the challenges to achieving petascale computing within the next decade are daunting, severa...
We describe the PetaByte-scale computing challenges posed by the next generation of particle physics...
The "internet of everything" envisions trillions of connected objects loaded with high-bandwidth sen...
already exist and run on Petascale class Supercomputers [1]. Modelers, programmers, and computer arc...
Within the next decade it will be possible to build chip multiprocessors with thousands of cores. We...
Atomic operations are crucial for most modern parallel and concurrent algorithms, which necessitates...
In this chapter we will argue that studying such multi-scale multi-science systems gives rise to inh...
International audienceExtreme scale parallel computing systems will have tens of thousands of option...
The Petascale Computing Enabling Technologies (PCET) project addressed challenges arising from curre...
c © The Authors 2015. This paper is published with open access at SuperFri.org Extreme scale paralle...