The DEEP (Dynamical Exascale Entry Platform) project aims to provide a first implementation of a novel architecture for heterogeneous high-performance computing.This architecture consists of a standard HPC Cluster and – tightly coupled –a cluster of many-core processors called Booster. This concept offers application developers the opportunity to run different parts of their program on the best fitting part of the machine striving for an optimal overall performance. In order to take advantage of this architecture applications require some adaption. To provide optimal support to the application developers the DEEP concept includes a high-level programming model that helps to separate a given program to the Cluster and Booster parts of the DE...
Cluster computers are dominating high performance computing (HPC) today. The success of this archite...
Particle in cell simulations represent an excellent paradigm for codesign efforts. PIC codes are sim...
We perform a scaling and performance portability study of the particle-in-cell scheme for plasma phy...
Homogeneous cluster architectures dominating high-performance computing (HPC) today are challenged, ...
Homogeneous cluster architectures, which used to dominate high-performance computing (HPC), are chal...
On the way towards Exascale the needed hardware for supercomputing is struggling to keep delivering ...
Striving at pushing the applications scalability to the limits, the DEEP project proposed an alterna...
The DEEP projects have developed a variety of hardware and software technologies aiming at improving...
On the way to explore the path to Exascale, the DEEP/-ER projects take a radically different approac...
We examine an alternative approach to heterogeneous cluster-computing in the many-core era for Earth...
We examine an alternative approach to heterogeneous cluster-computing in the many-core era for Earth...
Accelerators arrived to HPC when the power bill for achieving Flop performance with traditional, hom...
The European Dynamical Exascale Entry Platform (DEEP) is an example of a new type of heterogeneous s...
Cluster computers are dominating high-performance computing (HPC) today. The success of this archite...
This thesis discusses how to optimize computational physics software for speed through maximizing th...
Cluster computers are dominating high performance computing (HPC) today. The success of this archite...
Particle in cell simulations represent an excellent paradigm for codesign efforts. PIC codes are sim...
We perform a scaling and performance portability study of the particle-in-cell scheme for plasma phy...
Homogeneous cluster architectures dominating high-performance computing (HPC) today are challenged, ...
Homogeneous cluster architectures, which used to dominate high-performance computing (HPC), are chal...
On the way towards Exascale the needed hardware for supercomputing is struggling to keep delivering ...
Striving at pushing the applications scalability to the limits, the DEEP project proposed an alterna...
The DEEP projects have developed a variety of hardware and software technologies aiming at improving...
On the way to explore the path to Exascale, the DEEP/-ER projects take a radically different approac...
We examine an alternative approach to heterogeneous cluster-computing in the many-core era for Earth...
We examine an alternative approach to heterogeneous cluster-computing in the many-core era for Earth...
Accelerators arrived to HPC when the power bill for achieving Flop performance with traditional, hom...
The European Dynamical Exascale Entry Platform (DEEP) is an example of a new type of heterogeneous s...
Cluster computers are dominating high-performance computing (HPC) today. The success of this archite...
This thesis discusses how to optimize computational physics software for speed through maximizing th...
Cluster computers are dominating high performance computing (HPC) today. The success of this archite...
Particle in cell simulations represent an excellent paradigm for codesign efforts. PIC codes are sim...
We perform a scaling and performance portability study of the particle-in-cell scheme for plasma phy...