As the quality of experimental measurements increases, so does the need for Monte Carlo-generated simulated events — both with respect to the total amount and to their precision. In perturbative methods, this involves the evaluation of higher order corrections to the leading order (LO) scattering amplitudes, including real emissions and loop corrections. Although experimental uncertainties today are larger than those of simulations, at the High Luminosity LHC experimental uncertainties are expected to be smaller than the theoretical uncertainty for events generated below next-to-leading order (NLO) precision. As forecasted hardware resources will not meet CPU requirements for these simulation needs, speeding up NLO event generation is a necessity. In recent years, collaborators across Europe and the United States have been working on CPU vectorisation of LO event generation within the Mad- Graph5_aMC@NLO framework, as well as porting it to GPUs, to major success. Recently, development has also started on vectorising NLO event generation. Due to the more complicated nature of NLO amplitudes this development faces several difficulties not accounted for in the LO development, but it shows promise. Here, we present these issues as well as the current status of our eventparallel NLO implementation.
Hardware acceleration for next-to-leading order event generation within MadGraph5_aMC@NLO / Z. Wettersten, O. Mattelaer, S. Roiser, A. Valassi, M. Zaro. - In: EPJ WEB OF CONFERENCES. - ISSN 2100-014X. - 337:(2025), pp. 01230.1-01230.8. (Intervento presentato al convegno 27th International Conference on Computing in High Energy and Nuclear Physics (CHEP 2024) tenutosi a Krakow nel 2024) [10.1051/epjconf/202533701230].
Hardware acceleration for next-to-leading order event generation within MadGraph5_aMC@NLO
M. ZaroUltimo
2025
Abstract
As the quality of experimental measurements increases, so does the need for Monte Carlo-generated simulated events — both with respect to the total amount and to their precision. In perturbative methods, this involves the evaluation of higher order corrections to the leading order (LO) scattering amplitudes, including real emissions and loop corrections. Although experimental uncertainties today are larger than those of simulations, at the High Luminosity LHC experimental uncertainties are expected to be smaller than the theoretical uncertainty for events generated below next-to-leading order (NLO) precision. As forecasted hardware resources will not meet CPU requirements for these simulation needs, speeding up NLO event generation is a necessity. In recent years, collaborators across Europe and the United States have been working on CPU vectorisation of LO event generation within the Mad- Graph5_aMC@NLO framework, as well as porting it to GPUs, to major success. Recently, development has also started on vectorising NLO event generation. Due to the more complicated nature of NLO amplitudes this development faces several difficulties not accounted for in the LO development, but it shows promise. Here, we present these issues as well as the current status of our eventparallel NLO implementation.
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