While in the business world the cloud paradigm is typically implemented purchasing resources and services from third party providers (e.g. Amazon), in the scientific environment there's usually the ...need of on-premises IaaS infrastructures which allow efficient usage of the hardware distributed among (and owned by) different scientific administrative domains. In addition, the requirement of open source adoption has led to the choice of products like OpenStack by many organizations. We describe a use case of the Italian National Institute for Nuclear Physics (INFN) which resulted in the implementation of a unique cloud service, called 'Cloud Area Padovana', which encompasses resources spread over two different sites: the INFN Legnaro National Laboratories and the INFN Padova division. We describe how this IaaS has been implemented, which technologies have been adopted and how services have been configured in high-availability (HA) mode. We also discuss how identity and authorization management were implemented, adopting a widely accepted standard architecture based on SAML2 and OpenID: by leveraging the versatility of those standards the integration with authentication federations like IDEM was implemented. We also discuss some other innovative developments, such as a pluggable scheduler, implemented as an extension of the native OpenStack scheduler, which allows the allocation of resources according to a fair-share based model and which provides a persistent queuing mechanism for handling user requests that can not be immediately served. Tools, technologies, procedures used to install, configure, monitor, operate this cloud service are also discussed. Finally we present some examples that show how this IaaS infrastructure is being used.
The use of Application Specific Integrated Circuits (ASICs) in nuclear physics instrumentation is drastically increasing, thanks to the possibility of incorporating a large number of acquisition ...channels in compact devices. In this paper, we describe a SiPM-based application with CAEN Front-End Readout System 1 based on Citiroc 1A chip from Weeroc 2. Besides the use of this chip for well known single photon spectra and event counting, this paper exploits the possibility to acquire energy spectra directly from scintillators, paired with SiPM, through peak-and-hold readout. In particular, good energy resolutions have been achieved even with slow scintillators, like LYSO, CsI(Tl), and BGO, which have 40 ns, 1000 ns, and 300 ns of light decay time, respectively. These values are of the same order of magnitude of the shaping time of the Citiroc 1A chip (maximum value of 87.5 ns) in the case of LYSO, and higher in the case of CsI(Tl) and BGO. Several measurements have been performed using multiple radioactive γ sources and the resulting energy spectra demonstrate a resolution compatible with that found in literature 4 5 6 7, as well as with an alternative acquisition system based on a digitizer that implements an algorithm of Charge Integration in the FPGA 8.
The present work aims at optimizing the use of computing resources available at the grid Italian Tier-2 sites of the ALICE experiment at CERN LHC by making them accessible to interactive distributed ...analysis, thanks to modern solutions based on cloud computing. The scalability and elasticity of the computing resources via dynamic ("on-demand") provisioning is essentially limited by the size of the computing site, reaching the theoretical optimum only in the asymptotic case of infinite resources. The main challenge of the project is to overcome this limitation by federating different sites through a distributed cloud facility. Storage capacities of the participating sites are seen as a single federated storage area, preventing the need of mirroring data across them: high data access efficiency is guaranteed by location-aware analysis software and storage interfaces, in a transparent way from an end-user perspective. Moreover, the interactive analysis on the federated cloud reduces the execution time with respect to grid batch jobs. The tests of the investigated solutions for both cloud computing and distributed storage on wide area network will be presented.
In 2012, 14 Italian institutions participating in LHC Experiments won a grant from the Italian Ministry of Research (MIUR), with the aim of optimising analysis activities, and in general the Tier2 ...Tier3 infrastructure. We report on the activities being researched upon, on the considerable improvement in the ease of access to resources by physicists, also those with no specific computing interests. We focused on items like distributed storage federations, access to batch-like facilities, provisioning of user interfaces on demand and cloud systems. R&D on next-generation databases, distributed analysis interfaces, and new computing architectures was also carried on. The project, ending in the first months of 2016, will produce a white paper with recommendations on best practices for data-analysis support by computing centers.
Novel gamma spectroscopy measurements with ASIC front-end electronics Venturini, Y.; Garosi, P.; Saltarelli, A. ...
2023 IEEE Nuclear Science Symposium, Medical Imaging Conference and International Symposium on Room-Temperature Semiconductor Detectors (NSS MIC RTSD),
2023-Nov.-4
Conference Proceeding
Application Specific Integrated Circuits (ASIC) technology has the great advantage of providing the possibility to produce compact low power consumption devices with a large number of acquisition ...channels. In this work we want to investigate the capabilities of the CAEN A5202 FERS-5200 board in conjunction with several scintillator detectors. The A5202 board is an all-in-one front end optimized to work in conjunction with SiPM, it has a total of 64 channels, provided by two 32 channels ASIC Citiroc-1A chips. The number of channels can be further expanded by easily connecting more boards together via optical link. Each acquisition line performs the pulse height analysis (PHA), starting with two preamplifiers with different amplification gains. The preamplifiers are followed by an RC-CR2 shaper amplifier with a peaking time ranging from 12.5 ns to 87.5 ns with a 12.5 ns pitch. Finally, the energy of the incoming pulse is evaluated thanks to a peak detector which identifies and stores the maximum value of the shaped signal. The ASIC Citiroc chip is already being employed in cosmic rays measurements, as well as medicine applications like Wearable Positron Emission Tomography. We took measurements with a 6x6x15 mm3 Cerium-doped Lutetium Yttrium Orthosilicate (LYSO(Ce)) paired with a single 6x6 mm2 SiPM and a 22Na radioactive source. The energy resolution of the 511 keV annihilation peak is comparable with what obtained with the same crystal, radioactive source and a charge integration digitizer (CAEN DT5720A). We plan to test further the A5202 capabilities by taking more measurements with other sources and other scintillator crystals like Caesium Iodine (CsI), and Bismuth Germanate (BGO), but also with faster scintillators like Lanthanum Bromide (LaBr3) and Cerium Bromide (CeBr3).