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First Evaluation of the CPU, GPGPU and MIC Architectures for Real Time Particle Tracking based on Hough Transform at the LHC
Recent innovations focused around {\em parallel} processing, either through systems containing multiple processors or processors containing multiple cores, hold great promise for enhancing the performance of the trigger at the LHC and extending its physics program. The flexibility of the CMS/ATLAS t...
| Autores principales: | , , , , |
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| Lenguaje: | eng |
| Publicado: |
2013
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| Materias: | |
| Acceso en línea: | https://dx.doi.org/10.1088/1748-0221/9/04/P04005 http://cds.cern.ch/record/1621781 |
| _version_ | 1780933205687271424 |
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| author | Halyo, V. LeGresley, P. Lujan, P. Karpusenko, V. Vladimirov, A. |
| author_facet | Halyo, V. LeGresley, P. Lujan, P. Karpusenko, V. Vladimirov, A. |
| author_sort | Halyo, V. |
| collection | CERN |
| description | Recent innovations focused around {\em parallel} processing, either through systems containing multiple processors or processors containing multiple cores, hold great promise for enhancing the performance of the trigger at the LHC and extending its physics program. The flexibility of the CMS/ATLAS trigger system allows for easy integration of computational accelerators, such as NVIDIA's Tesla Graphics Processing Unit (GPU) or Intel's \xphi, in the High Level Trigger. These accelerators have the potential to provide faster or more energy efficient event selection, thus opening up possibilities for new complex triggers that were not previously feasible. At the same time, it is crucial to explore the performance limits achievable on the latest generation multicore CPUs with the use of the best software optimization methods. In this article, a new tracking algorithm based on the Hough transform will be evaluated for the first time on a multi-core Intel Xeon E5-2697v2 CPU, an NVIDIA Tesla K20c GPU, and an Intel \xphi\ 7120 coprocessor. Preliminary time performance will be presented. |
| id | cern-1621781 |
| institution | Organización Europea para la Investigación Nuclear |
| language | eng |
| publishDate | 2013 |
| record_format | invenio |
| spelling | cern-16217812022-08-10T20:36:47Zdoi:10.1088/1748-0221/9/04/P04005http://cds.cern.ch/record/1621781engHalyo, V.LeGresley, P.Lujan, P.Karpusenko, V.Vladimirov, A.First Evaluation of the CPU, GPGPU and MIC Architectures for Real Time Particle Tracking based on Hough Transform at the LHCOther Fields of PhysicsRecent innovations focused around {\em parallel} processing, either through systems containing multiple processors or processors containing multiple cores, hold great promise for enhancing the performance of the trigger at the LHC and extending its physics program. The flexibility of the CMS/ATLAS trigger system allows for easy integration of computational accelerators, such as NVIDIA's Tesla Graphics Processing Unit (GPU) or Intel's \xphi, in the High Level Trigger. These accelerators have the potential to provide faster or more energy efficient event selection, thus opening up possibilities for new complex triggers that were not previously feasible. At the same time, it is crucial to explore the performance limits achievable on the latest generation multicore CPUs with the use of the best software optimization methods. In this article, a new tracking algorithm based on the Hough transform will be evaluated for the first time on a multi-core Intel Xeon E5-2697v2 CPU, an NVIDIA Tesla K20c GPU, and an Intel \xphi\ 7120 coprocessor. Preliminary time performance will be presented.Recent innovations focused around parallel processing, either through systems containingmultiple processors or processors containing multiple cores, holdgreat promise for enhancing the performance of the trigger at the LHCand extending its physics program. The flexibility of the CMS/ATLAStrigger system allows for easy integration of computationalaccelerators, such as NVIDIA's Tesla Graphics Processing Unit (GPU) orIntel's Xeon Phi, in the High Level Trigger. These accelerators have thepotential to provide faster or more energy efficient event selection,thus opening up possibilities for new complex triggers that were notpreviously feasible. At the same time, it is crucial to explore theperformance limits achievable on the latest generation multicore CPUswith the use of the best software optimization methods. In thisarticle, a new tracking algorithm based on the Hough transform will beevaluated for the first time on multi-core Intel i7-3770 and IntelXeon E5-2697v2 CPUs, an NVIDIA Tesla K20c GPU, and an Intel Xeon Phi7120 coprocessor. Preliminary time performance will be presented.Recent innovations focused around {\em parallel} processing, either through systems containing multiple processors or processors containing multiple cores, hold great promise for enhancing the performance of the trigger at the LHC and extending its physics program. The flexibility of the CMS/ATLAS trigger system allows for easy integration of computational accelerators, such as NVIDIA's Tesla Graphics Processing Unit (GPU) or Intel's \xphi, in the High Level Trigger. These accelerators have the potential to provide faster or more energy efficient event selection, thus opening up possibilities for new complex triggers that were not previously feasible. At the same time, it is crucial to explore the performance limits achievable on the latest generation multicore CPUs with the use of the best software optimization methods. In this article, a new tracking algorithm based on the Hough transform will be evaluated for the first time on a multi-core Intel Xeon E5-2697v2 CPU, an NVIDIA Tesla K20c GPU, and an Intel \xphi\ 7120 coprocessor. Preliminary time performance will be presented.arXiv:1310.7556oai:cds.cern.ch:16217812013-10-28 |
| spellingShingle | Other Fields of Physics Halyo, V. LeGresley, P. Lujan, P. Karpusenko, V. Vladimirov, A. First Evaluation of the CPU, GPGPU and MIC Architectures for Real Time Particle Tracking based on Hough Transform at the LHC |
| title | First Evaluation of the CPU, GPGPU and MIC Architectures for Real Time Particle Tracking based on Hough Transform at the LHC |
| title_full | First Evaluation of the CPU, GPGPU and MIC Architectures for Real Time Particle Tracking based on Hough Transform at the LHC |
| title_fullStr | First Evaluation of the CPU, GPGPU and MIC Architectures for Real Time Particle Tracking based on Hough Transform at the LHC |
| title_full_unstemmed | First Evaluation of the CPU, GPGPU and MIC Architectures for Real Time Particle Tracking based on Hough Transform at the LHC |
| title_short | First Evaluation of the CPU, GPGPU and MIC Architectures for Real Time Particle Tracking based on Hough Transform at the LHC |
| title_sort | first evaluation of the cpu, gpgpu and mic architectures for real time particle tracking based on hough transform at the lhc |
| topic | Other Fields of Physics |
| url | https://dx.doi.org/10.1088/1748-0221/9/04/P04005 http://cds.cern.ch/record/1621781 |
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