Your search keyword '"Stelzer, T."' showing total 3 results

1. Fast computation of MadGraph amplitudes on graphics processing unit (GPU).

Author

Hagiwara, K., Kanzaki, J., Li, Q., Okamura, N., and Stelzer, T.

Subjects

GRAPHICS processing units, STANDARD model (Nuclear physics), HIGGS bosons, NUCLEAR cross sections, NUMERICAL analysis, HELICITY of nuclear particles

Abstract

Continuing our previous studies on QED and QCD processes, we use the graphics processing unit (GPU) for fast calculations of helicity amplitudes for general Standard Model (SM) processes. Additional HEGET codes to handle all SM interactions are introduced, as well as the program MG2CUDA that converts arbitrary MadGraph generated HELAS amplitudes (FORTRAN) into HEGET codes in CUDA. We test all the codes by comparing amplitudes and cross sections for multi-jet processes at the LHC associated with production of single and double weak bosons, a top-quark pair, Higgs boson plus a weak boson or a top-quark pair, and multiple Higgs bosons via weak-boson fusion, where all the heavy particles are allowed to decay into light quarks and leptons with full spin correlations. All the helicity amplitudes computed by HEGET are found to agree with those computed by HELAS within the expected numerical accuracy, and the cross sections obtained by gBASES, a GPU version of the Monte Carlo integration program, agree with those obtained by BASES (FORTRAN), as well as those obtained by MadGraph. The performance of GPU was over a factor of 10 faster than CPU for all processes except those with the highest number of jets. [ABSTRACT FROM AUTHOR]

Published

2013

2. Calculation of HELAS amplitudes for QCD processes using graphics processing unit (GPU).

Author

Hagiwara, K., Kanzaki, J., Okamura, N., Rainwater, D., and Stelzer, T.

Subjects

QUANTUM chromodynamics, GRAPHICS processing units, HELICITY of nuclear particles, SCATTERING amplitude (Physics), COMPUTER software, CENTRAL processing units, JETS (Nuclear physics)

Abstract

We use a graphics processing unit (GPU) for fast calculations of helicity amplitudes of quark and gluon scattering processes in massless QCD. New HEGET ( HELAS Evaluation with GPU Enhanced Technology) codes for gluon self-interactions are introduced, and a C++ program to convert the MadGraph generated FORTRAN codes into HEGET codes in CUDA (a C-platform for general purpose computing on GPU) is created. Because of the proliferation of the number of Feynman diagrams and the number of independent color amplitudes, the maximum number of final state jets we can evaluate on a GPU is limited to 4 for pure gluon processes ( gg→4 g), or 5 for processes with one or more quark lines such as $q\overline{q}\rightarrow 5g$ and qq→ qq+3 g. Compared with the usual CPU-based programs, we obtain 60-100 times better performance on the GPU, except for 5-jet production processes and the gg→4 g processes for which the GPU gain over the CPU is about 20. [ABSTRACT FROM AUTHOR]

Published

2010

3. Fast calculation of HELAS amplitudes using graphics processing unit (GPU).

Author

Hagiwara, K., Kanzaki, J., Okamura, N., Rainwater, D., and Stelzer, T.

Subjects

HELICITY of nuclear particles, GRAPHICS processing units, COLLISIONS (Physics), SCATTERING (Physics), ATOM-atom collisions

Abstract

We use the graphics processing unit (GPU) for fast calculations of helicity amplitudes of physics processes. As our first attempt, we compute $u\overline{u}\rightarrow n\gamma$ ( n=2 to 8) processes in pp collisions at $\sqrt{s}=14$ TeV by transferring the MadGraph generated HELAS amplitudes (FORTRAN) into newly developed HEGET ( HELAS Evaluation with GPU Enhanced Technology) codes written in CUDA, a C-platform developed by NVIDIA for general purpose computing on the GPU. Compared with the usual CPU programs, we obtain a 40–150 times better performance on the GPU. [ABSTRACT FROM AUTHOR]

Published

2010