Your search keyword '"Ilaria Neri"' showing total 2 results

1. GPU-based low-level trigger system for the standalone reconstruction of the ring-shaped hit patterns in the RICH Cherenkov detector of NA62 experiment

Author

Alessandro Lonardo, Roberto Piandani, Pierluigi Paolucci, Andrea Biagioni, A. Cotta Ramusino, Massimiliano Fiorini, Paolo Cretaro, Mauro Piccini, M. Martinelli, S. Chiozzi, R. Fantechi, Francesco Simula, A. Gianoli, Luca Pontisso, Piero Vicini, Ottorino Frezza, Davide Rossetti, S. Di Lorenzo, E. Pastorelli, Ilaria Neri, F. Lo Cicero, G. Lamanna, M. Sozzi, and Roberto Ammendola

Subjects

010308 nuclear & particles physics, Cherenkov detector, Computer science, business.industry, Detector, Graphics processing unit, NA62 experiment, 01 natural sciences, NO, 030218 nuclear medicine & medical imaging, law.invention, 03 medical and health sciences, 0302 clinical medicine, Trigger concepts and systems (hardware and software), Trigger algorithms, law, 0103 physical sciences, Instrumentation, Mathematical Physics, Latency (engineering), business, Field-programmable gate array, Cherenkov radiation, Computer hardware, Data transmission

Abstract

This project aims to exploit the parallel computing power of a commercial Graphics Processing Unit (GPU) to implement fast pattern matching in the Ring Imaging Cherenkov (RICH) detector for the level 0 (L0) trigger of the NA62 experiment. In this approach, the ring-fitting algorithm is seedless, being fed with raw RICH data, with no previous information on the ring position from other detectors. Moreover, since the L0 trigger is provided with a more elaborated information than a simple multiplicity number, it results in a higher selection power. Two methods have been studied in order to reduce the data transfer latency from the readout boards of the detector to the GPU, i.e., the use of a dedicated NIC device driver with very low latency and a direct data transfer protocol from a custom FPGA-based NIC to the GPU. The performance of the system, developed through the FPGA approach, for multi-ring Cherenkov online reconstruction obtained during the NA62 physics runs is presented.

Published

2017

2. NaNet: a configurable NIC bridging the gap between HPC and real-time HEP GPU computing

Author

Alessandro Lonardo, A. Cotta Ramusino, Luca Pontisso, Piero Vicini, Laura Tosoratto, Fabrizio Ameli, Michele Martinelli, Pierluigi Paolucci, Andrea Biagioni, F. Lo Cicero, M. Sozzi, Gianluca Lamanna, Francesco Simula, Ottorino Frezza, Massimiliano Fiorini, Ilaria Neri, Francesco Simeone, Davide Rossetti, Elena Pastorelli, and Roberto Ammendola

Subjects

Remote direct memory access, Bridging (networking), Computer science, Computing (architecture, GRID for recording, Trigger concepts and systems (hardware and software), Computing (architecture, farms, GRID for recording, storage, archiving, and distribution of data), NA62 experiment, farms, NO, storage, archiving, Network interface controller, Computer architecture, Instrumentation, Mathematical Physics, and distribution of data), Transport layer, Detectors and Experimental Techniques, General-purpose computing on graphics processing units, Field-programmable gate array, PCI Express

Abstract

NaNet is a FPGA-based PCIe Network Interface Card (NIC) design with GPUDirect and Remote Direct Memory Access (RDMA) capabilities featuring a configurable and extensible set of network channels. The design currently supports both standard—Gbe (1000BASE-T) and 10GbE (10Base-R)—and custom—34 Gbps APElink and 2.5 Gbps deterministic latency KM3link—channels, but its modularity allows for straightforward inclusion of other link technologies. The GPUDirect feature combined with a transport layer offload module and a data stream processing stage makes NaNet a low-latency NIC suitable for real-time GPU processing. In this paper we describe the NaNet architecture and its performances, exhibiting two of its use cases: the GPU-based low-level trigger for the RICH detector in the NA62 experiment at CERN and the on-/off-shore data transport system for the KM3NeT-IT underwater neutrino telescope.

Published

2015