Dr. Valentina Fioretti Profile

Dr. Valentina Fioretti

Researcher at INAF - Osservatorio di Astrofisica e Scienza dello Spazio

SPIE Involvement:

Author

Publications (40)

Proceedings Article | 21 August 2024 Poster + Paper

Poster + Paper

Towards a response function for the COSI anticoincidence system: preliminary results from Geant4 simulations

Alex Ciabattoni, Valentina Fioretti, John Tomsick, Andreas Zoglauer, Pierre Jean, Daniel Alvarez Franco, Peter von Ballmoos, Andrea Bulgarelli, Cristian Vignali, Nicolò Parmiggiani, Gabriele Panebianco, Luca Castaldini

Proceedings Volume 13093, 130937Y (2024) https://doi.org/10.1117/12.3020252

KEYWORDS: Photons, Simulations, Reflection, Analytic models, Specular reflections, Surface finishing, Silicon photomultipliers, Absorption, Crystals, Scintillation

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Proceedings Article | 25 July 2024 Poster + Paper

Poster + Paper

A reliable and automated orchestrator for the computing system of the ASTRI project

I. Abu, F. Gianotti, M. Lodi, G. Malaspina, M. De Benedetto, F. Fiordoliva, M. Costi, G. Mancini, M. Sardo, M. Rosi, A. Bulgarelli, L. Castaldini, A. Tacchini, V. Conforti, A. Costa, V. Fioretti, S. Gallozzi, F. Lucarelli, K. Munari, N. Parmiggiani, V. Pastore, F. Russo, S. Scuderi, G. Tosti, M. Trifoglio

Proceedings Volume 13101, 131013B (2024) https://doi.org/10.1117/12.3018971

KEYWORDS: Printed circuit board testing, Telescopes, Data storage, Atmospheric Cherenkov telescopes, Data acquisition, Computing systems, Reliability, Observatories, Data transmission, Astronomy

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The ASTRI (”Astrofisica con Specchi a Tecnologia Replicante Italiana”) program, led by the Italian National Institute for Astrophysics (INAF), is an international collaboration focused on developing and operating an array of nine 4-meter class, dual-mirror Imaging Atmospheric Cherenkov Telescopes (IACTs). These telescopes are designed to detect gamma-ray radiation at energies above 1 TeV. The ASTRI Mini-Array is being constructed at the Teide Observatory in Tenerife, Canary Islands. To support the development, installation, and operation of the ASTRI Mini-Array, a dedicated on-site Information and Communication Technology (ICT) Infrastructure has been designed. This ICT infrastructure hosts the Computing System for the SCADA (Supervisory Control and Data Acquisition) software, which monitors, controls, and acquires data from the ASTRI Mini-Array telescopes and associated auxiliary hardware. The deployment model for SCADA is based on a combination of containers, bare metal servers, and virtual machines, all of which communicate seamlessly. Containerization techniques, paired with advanced orchestration systems such as Kubernetes, enhance the system’s efficiency. In this paper, we detail the virtual and containerized environment system, which employs the concept of Infrastructure as Code (IaC) in conjunction with a container orchestration system. IaC enhances portability, automation, agility, and version control, while the orchestration system automates deployment, scalability, load balancing, resource management, recovery, and container version management. Together, IaC and container orchestration significantly simplify the infrastructure and application management. IaC automates the provisioning of basic infrastructure, while container orchestration ensures that containerized applications run efficiently and reliably. This architecture allows us to manage the entire SCADA system with ease, enabling rapid deployment of the entire system—both the environment and applications—at the Teide Observatory or other test sites.

Proceedings Article | 25 July 2024 Presentation + Paper

Presentation + Paper

Methodology for the integration of the array control and data acquisition system with array elements of the Cherenkov Telescope Array Observatory

B. Lopez, P. Aubert, L. Baroncelli, P. Bolle, P. Bruno, A. Bulgarelli, S. Caroff, L. Castaldini, V. Conforti, A. Costa, L. David, G. De Cesare, E. de Ona Wilhelm, A. Di Piano, K. Egberts, R. Fernandez, V. Fioretti, S. Fukami, E. Garcia, H. Gasparyan, S. Germani, F. Incardona, D. Kostunin, E. Lyard, G. Maurin, D. Melkumyan, K. Munari, T. Murach, A. Muraczewski, N. Nakhjiri, D. Neise, I. Oya, G. Panebianco, N. Parmiggiani, V. Pollet, I. Sadeh, S. Sah, A. Sarkar, M. Schefer, T. Schmidt, D. Soldevila, C. Steppa, A. Tramacere, R. Valles, T. Vuillaume, F. Werner

Proceedings Volume 13101, 131010H (2024) https://doi.org/10.1117/12.3017493

KEYWORDS: Integration, Atmospheric Cherenkov telescopes, Observatories, Data acquisition, Control systems, Software development

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The Cherenkov Telescope Array Observatory (CTAO) is the next-generation atmospheric Cherenkov gammaray Observatory. CTAO will be constructed on two sites, one array in the Northern and the other in the Southern hemisphere, containing telescopes of three different sizes, for covering different energy domains. To combine and orchestrate the different telescopes and auxiliary instruments (array elements), the Array Control and Data Acquisition (ACADA) system is the central element for the Observatory on-site operations: it controls, supervises, and handles the data generated by the array elements. Considering the criticality of the ACADA system for future Observatory operations, corresponding quality assurance provisions have been made at the different steps of the software development lifecycle, with focus on continuous integration and testing at all levels. To enable higher-level tests of the software deployed on a distributed system, an ACADA test cluster has been set up to facilitate testing and debugging of issues in a more realistic environment. Furthermore, a separate software integration and test cluster has also been established that allows for the off-site testing of the integrated software packages of ACADA and of the corresponding array elements. Here the software integration can be prepared, interfaces and interactions can be tested, and on-site procedures that are required later in the process can be checked beforehand, only limited by the simulation capabilities that are delivered as part of the software packages. Once preparations and testing with the off-site test cluster are completed, the integrated software can be deployed at the target site. The software packages and setup parameters are kept under configuration control at all stages, and deployment steps are documented to ensure that installations are reproducible. This methodology has been applied for the first time in the context of the integration of ACADA with the first CTAO Large-sized Telescope (LST-1) in October 2023.

Proceedings Article | 25 July 2024 Poster + Paper

Poster + Paper

The science alert generation system of the Cherenkov Telescope Array Observatory

A. Bulgarelli, S. Caroff, L. Castaldini, P. Aubert, G. De Cesare, A. Di Piano, V. Fioretti, G. Maurin, G. Panebianco, N. Parmiggiani, V. Pollet, T. Vuillaume, I. Oya, C. Steppa, K. Egberts

Proceedings Volume 13101, 1310129 (2024) https://doi.org/10.1117/12.3017825

KEYWORDS: Data acquisition, Telescopes, Atmospheric Cherenkov telescopes, Observatories, Databases, Gamma radiation, Data processing, Data analysis, Control systems, Reconstruction algorithms

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Proceedings Article | 25 July 2024 Poster + Paper

Poster + Paper

ASTRI Mini-Array on-site information and communication technology infrastructure

F. Gianotti, I. Abu, M. Lodi, A. Tacchini, G. Malaspina, M. De Benedetto, F. Fiordoliva, M. Costi, G. Mancini, D. Gregori, M. Pinetti, M. Sardo, D. Fuzzati, M. Rosi, D. Obbi, P. Bruno, A. Bulgarelli, L. Castaldini, V. Conforti, A. Costa, V. Fioretti, S. Gallozzi, C. Grivel, F. Incardona, G. Leto, F. Lucarelli, K. Munari, N. Parmiggiani, V. Pastore, F. Russo, S. Scuderi, G. Tosti, M. Trifoglio

Proceedings Volume 13101, 1310136 (2024) https://doi.org/10.1117/12.3018973

KEYWORDS: Printed circuit board testing, Telescopes, Switches, Connectors, Control systems, Internet, Data acquisition, Data centers, Cameras, Atmospheric Cherenkov telescopes

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The ASTRI ("Astrofisica con Specchi a Tecnologia Replicante Italiana") is a collaborative international effort led by the Italian National Institute for Astrophysics (INAF) for developing an array of nine 4m-class dual-mirror Imaging Atmospheric Cherenkov Telescopes (IACTs) sensitive to gamma-ray radiation at energies above 1 TeV. The array is placed at the Teide Observatory in Tenerife, in the Canary Islands. In order to support the development, installation, and operations of the ASTRI Mini-Array, an on-site Information and Communication Technology (ICT) Infrastructure has been designed. This paper describes the design of this ICT infrastructure, which includes various subsystems dedicated primarily to host the Supervisory Control and Data Acquisition (SCADA) software whose aim is to control and monitor the array of telescopes and to perform data acquisition and data quality control. For each subsystem, the best technology solutions were chosen. A dedicated Virtual System based on ProxMox for telescope control, to ensure the easy control and management combined with high reliability and continuity of service was implemented. To ensure the throughput of tens of MB/s the data acquisition and dispatch operations were realized bare metal from the camera and frontier server, combined with a dedicated BeeGFS-based storage system to ensure the necessary performance and provide a distributed, shared and concurrent filesystem. The high performances of the online data quality control and of the Monitoring System are guaranteed by a Kubernetes Technology approach, which also improves the automation, the scaling and deployment. These subsystems and ASTRI telescopes are interconnected by the high-performance network, so special attention has been focused on the network topology to ensure both reliability and data transfer throughput, both in the local network and for transmission to the remote archive facility in Rome where the data are transferred as soon as they are available. The entire ICT infrastructure was engineered to have no Single Point of Failure (SPOF) and to ensure high availability, because there will be no one dedicated to its maintenance on-site at Teide and during the night. Therefore, all the most critical systems have been designed in hot redundancy, that is, capable of supporting a failure without service interruption.

Proceedings Article | 25 July 2024 Presentation + Paper

Presentation + Paper

The first release of the Cherenkov Telescope Array Observatory array control and data acquisition software

I. Oya, P. Aubert, L. Baroncelli, P. Bolle, P. Bruno, A. Bulgarelli, S. Caroff, L. Castaldini, V. Conforti, A. Costa, L. David, G. De Cesare, E. de Ona Wilhelmli, A. Di Piano, K. Egberts, R. Fernandez, V. Fioretti, S. Fukami, E. Garcia, E. García, H. Gasparyan, S. Germani, C. Hoischen, F. Incardona, D. Kostunin, B. Lopez, E. Lyard, G. Maurin, D. Melkumyan, K. Munari, T. Murach, A. Muraczewski, N. Nakhjiri, D. Neise, G. Panebianco, N. Parmiggiani, E. Pietriga, V. Pollet, I. Sadeh, S. Sah, A. Sarkar, M. Schefer, T. Schmidt, D. Soldevila, C. Steppa, D. Torres, A. Tramacere, R. Vallés, T. Vuillaume, F. Werner

Proceedings Volume 13101, 131011D (2024) https://doi.org/10.1117/12.3017568

KEYWORDS: Telescopes, Atmospheric Cherenkov telescopes, Data acquisition, Control systems, Observatories, Design, Astronomy

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The Cherenkov Telescope Array Observatory (CTAO) is the next-generation atmospheric Cherenkov gamma-ray project. CTAO will be deployed at two sites, one in the Northern and the other in the Southern Hemisphere, containing telescopes of three different sizes for covering different energy domains. The commissioning of the first CTAO Large-sized Telescope (LST-1) is being finalized at the CTAO Northern site. Additional calibration and environmental monitoring instruments such as laser imaging detection and ranging (LIDAR) instruments and weather stations will support the telescope operations. The Array Control and Data Acquisition (ACADA) system is the central element for onsite CTAO operations. ACADA controls, supervises, and handles the data generated by the telescopes and the auxiliary instruments. It will drive the efficient planning and execution of observations while handling the several Gb/s camera data generated by each CTAO telescope. The ACADA system contains the CTAO Science Alert Generation Pipeline – a real-time data processing and analysis pipeline, dedicated to the automatic generation of science alert candidates as data are being acquired. These science alerts, together with external alerts arriving from other scientific instruments, will be managed by the Transients Handler (TH) component. The TH informs the Short-term Scheduler of ACADA about interesting science alerts, enabling the modification of ongoing observations at sub-minute timescales. The capacity for such fast reactions – together with the fast movement of CTAO telescopes – makes CTAO an excellent instrument for studying high-impact astronomical transient phenomena. The ACADA software is based on the Alma Common Software (ACS) framework, and written in C++, Java, Python, and Javascript. The first release of the ACADA software, ACADA REL1, was finalized in July 2023, and integrated after a testing campaign with the LST-1 finalized in October 2023. This contribution describes the design and status of the ACADA software system.

SPIE Journal Paper | 23 January 2024 Open Access

Open Access

Software architecture and development approach for the ASTRI Mini-Array project at the Teide Observatory

Andrea Bulgarelli, Fabrizio Lucarelli, Gino Tosti, Vito Conforti, Nicolò Parmiggiani, Joseph Hillary Schwarz, Juan Guillermo Alvarez Gallardo, Lucio Angelo Antonelli, Mauricio Araya, Matteo Balbo, Leonardo Baroncelli, Ciro Bigongiari, Pietro Bruno, Milvia Capalbi, Martina Cardillo, Guillermo Andres Rodriguez Castillo, Osvaldo Catalano, Antonio Alessio Compagnino, Mattia Corpora, Alessandro Costa, Silvia Crestan, Giuseppe Cusumano, Antonino D’Aì, Valentina Fioretti, Stefano Gallozzi, Stefano Germani, Fulvio Gianotti, Valentina Giordano, Andrea Giuliani, Alessandro Grillo, Isaias Huerta, Federico Incardona, Simone Iovenitti, Nicola La Palombara, Valentina La Parola, Marco Landoni, Saverio Lombardi, Maria Cettina Maccarone, Rachele Millul, Teresa Mineo, Gabriela Montenegro, Davide Mollica, Kevin Munari, Antonio Pagliaro, Giovanni Pareschi, Valerio Pastore, Matteo Perri, Fabio Pintore, Patrizia Romano, Federico Russo, Ricardo Zanmar Sanchez, Pierluca Sangiorgi, Francesco Gabriele Saturni, Nestor Sayes, Eva Sciacca, Vitalii Sliusar, Salvatore Scuderi, Alessandro Tacchini, Vincenzo Testa, Massimo Trifoglio, Antonio Tutone, Stefano Vercellone, Roland Walter, for the ASTRI Project

JATIS, Vol. 10, Issue 01, 017001, (January 2024) https://doi.org/10.1117/12.10.1117/1.JATIS.10.1.017001

KEYWORDS: Software development, Telescopes, Data modeling, Computer architecture, Control systems, Atmospheric Cherenkov telescopes, Data acquisition, Data archive systems, Design, Cameras

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Proceedings Article | 31 August 2022 Poster + Paper

Poster + Paper

Geant4 simulation of the residual background in the ATHENA wide field imager from protons deflected by the charged particle diverter

Gábor Galgóczi, Jean-Paul Breuer, Valentina Fioretti, Jakub Zlámal, Norbert Werner, Vojtěch Čalkovský, Nathalie Boudin, Ivo Ferreira, Matteo Guainazzi, Andreas von Kienlin, Simone Lotti, Teresa Mineo, Silvano Molendi, Emanuele Perinati

Proceedings Volume 12181, 1218140 (2022) https://doi.org/10.1117/12.2629994

KEYWORDS: Sensors, Magnetism, X-ray telescopes, Scattering, Computer aided design, X-rays, Solid modeling, Particles, Charged particle optics, Optical filters

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Proceedings Article | 31 August 2022 Poster + Paper

Poster + Paper

Athena charged particle diverter simulations: effects of micro-roughness on proton scattering using Geant4

Jean-Paul Breuer, Gábor Galgóczi, Valentina Fioretti, Jakub Zlámal, Petr Liska, Norbert Werner, Giovanni Santin, Nathalie Boudin, Ivo Ferreira, Matteo Guainazzi, Andreas von Kienlin, Simone Lotti, Teresa Mineo, Silvano Molendi, Emanuele Perinati

Proceedings Volume 12181, 1218143 (2022) https://doi.org/10.1117/12.2630076

KEYWORDS: Scattering, Particles, Computer simulations, Surface roughness, X-rays, X-ray telescopes, Statistical modeling

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Proceedings Article | 29 August 2022 Poster + Paper

Poster + Paper

The online observation quality system software architecture for the ASTRI Mini-Array project

N. Parmiggiani, A. Bulgarelli, L. Baroncelli, A. Addis, V. Fioretti, A. Di Piano, M. Capalbi, O. Catalano, V. Conforti, M. Fiori, F. Gianotti, S. Iovenitti, F. Lucarelli, M. C. Maccarone, T. Mineo, S. Lombardi, V. Pastore, F. Russo, P. Sangiorgi, S. Scuderi, G. Tosti, M. Trifoglio, L. Zampieri

Proceedings Volume 12189, 121892H (2022) https://doi.org/10.1117/12.2629278

KEYWORDS: Atmospheric Cherenkov telescopes, Data acquisition, Cameras, Control systems, Telescopes, Interferometry, Data centers, Software development, Computer architecture, Quality systems

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Proceedings Article | 29 August 2022 Presentation + Paper

Presentation + Paper

The Software Architecture and development approach for the ASTRI Mini-Array gamma-ray air-Cherenkov experiment at the Observatorio del Teide

A. Bulgarelli, F. Lucarelli, G. Tosti, V. Conforti, N. Parmiggiani, J. H. Schwarz, L. A. Antonelli, L. Baroncelli, C. Bigongiari, M. Capalbi, M. Cardillo, G. A. Rodriguez Castillo, O. Catalano, A. A. Compagnino, M. Corpora, A. Costa, S. Crestan, G. Cusumano, A. D'Ai', V. Fioretti, S. Gallozzi, S. Germani, F. Gianotti, V. Giordano, A. Giuliani, P. G. Bruno, J. G. Green, A. Grillo, F. Incardona, S. Iovenitti, N. La Palombara, V. La Parola, M. Landoni, S. Lombardi, M. C. Maccarone, R. Millul, T. Mineo, D. Mollica, A. Pagliaro, G. Pareschi, V. Pastore, M. Perri, F. Pintore, P. Romano, F. Russo, P. Sangiorgi, F. G. Saturni, E. Sciacca, S. Scuderi, A. Tacchini, V. Testa, M. Trifoglio, A. Tutone, S. Vercellone

Proceedings Volume 12189, 121890D (2022) https://doi.org/10.1117/12.2629164

KEYWORDS: Data modeling, Atmospheric Cherenkov telescopes, Control systems, Software development, Telescopes, Data processing, Data archive systems, Data acquisition, Calibration, Computer architecture

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Proceedings Article | 29 August 2022 Presentation + Paper

Presentation + Paper

The Array Data Acquisition System software architecture of the ASTRI Mini-Array project

Vito Conforti, Fulvio Gianotti, Valerio Pastore, Massimo Trifoglio, Andrea Bulgarelli, Antonio Addis, Leonardo Baroncelli, Milvia Capalbi, Valentina Fioretti, Nicolò Parmiggiani, Pierluca Sangiorgi, Mattia Corpora, Osvaldo Catalano, Alessandro Costa, Federico Incardona, F. Russo

Proceedings Volume 12189, 121890N (2022) https://doi.org/10.1117/12.2626600

KEYWORDS: Atmospheric Cherenkov telescopes, Cameras, Data acquisition, Telescopes, Computer architecture, Binary data, Double positive medium, Data storage, Data conversion, Control systems, Astronomical software, Software

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SPIE Journal Paper | 15 February 2022 Open Access

Open Access

Mitigating the effects of particle background on the Athena Wide Field Imager

Eric Miller, Catherine Grant, Marshall Bautz, Silvano Molendi, Ralph Kraft, Paul Nulsen, Esra Bulbul, Steven Allen, David Burrows, Tanja Eraerds, Valentina Fioretti, Fabio Gastaldello, David Hall, Michael W. Hubbard, Jonathan Keelan, Norbert Meidinger, Emanuele Perinati, Arne Rau, Dan Wilkins

JATIS, Vol. 8, Issue 01, 018001, (February 2022) https://doi.org/10.1117/12.10.1117/1.JATIS.8.1.018001

KEYWORDS: Particles, Signal to noise ratio, Sensors, Camera shutters, Signal attenuation, Imaging systems, Signal detection, X-rays, Photons, X-ray imaging

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The Wide Field Imager (WFI) flying on Athena will usher in the next era of studying the hot and energetic Universe. Among Athena’s ambitious science programs are observations of faint, diffuse sources limited by statistical and systematic uncertainty in the background produced by high-energy cosmic ray particles. These particles produce easily identified “cosmic-ray tracks” along with less easily identified signals produced by secondary photons or x-rays generated by particle interactions with the instrument. Such secondaries produce identical signals to the x-rays focused by the optics and cannot be filtered without also eliminating these precious photons. As part of a larger effort to estimate the level of unrejected background and mitigate its effects, we here present results from a study of background-reduction techniques that exploit the spatial correlation between cosmic-ray particle tracks and secondary events. We use Geant4 simulations to generate a realistic particle background signal, sort this into simulated WFI frames, and process those frames in a similar way to the expected flight and ground software to produce a realistic WFI observation containing only particle background. The technique under study, self-anti-coincidence (SAC), then selectively filters regions of the detector around particle tracks, turning the WFI into its own anti-coincidence detector. We show that SAC is effective at improving the systematic uncertainty for observations of faint, diffuse sources, but at the cost of statistical uncertainty due to a reduction in signal. If sufficient pixel pulse-height information is telemetered to the ground for each frame, then this technique can be applied selectively based on the science goals, providing flexibility without affecting the data quality for other science. The results presented here are relevant for any future silicon-based pixelated x-ray imaging detector and could allow the WFI and similar instruments to probe to truly faint x-ray surface brightness.

Proceedings Article | 23 August 2021 Poster + Paper

Poster + Paper

Design and characterization of a prototype proton response matrix for the XMM-Newton mission

V. Fioretti, T. Mineo, R. Amato, S. Lotti, C. Macculi, S. Molendi, F. Gastaldello, G. Lanzuisi, M. Cappi, M. Dadina, S. Ettori

Proceedings Volume 11822, 118221F (2021) https://doi.org/10.1117/12.2594120

KEYWORDS: X-rays, Mirrors, Optical filters, Molybdenum, Scattering, Cameras, Physics, Device simulation, Electrodes, Sensors

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Proceedings Article | 13 December 2020 Paper

Paper

The XGIS instrument on-board THESEUS: Monte Carlo simulations for response, background, and sensitivity

Riccardo Campana, Fabio Fuschino, Claudio Labanti, Sandro Mereghetti, Enrico Virgilli, Valentina Fioretti, Mauro Orlandini, John Buchan Stephen, Lorenzo Amati

Proceedings Volume 11444, 114448P (2020) https://doi.org/10.1117/12.2560981

KEYWORDS: Monte Carlo methods, Gamma ray imaging, Spectroscopy, Instrument modeling, Visual process modeling, Photon transport, Device simulation, Pollution control, Sensors

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Proceedings Article | 6 July 2018 Presentation + Paper

Presentation + Paper

Estimates for the background of the ATHENA X-IFU instrument: the cosmic rays contribution

Simone Lotti, Claudio Macculi, Matteo D'Andrea, Valentina Fioretti, Paolo Dondero, Alfonso Mantero, Gabriele Minervini, Andrea Argan, Luigi Piro

Proceedings Volume 10699, 106991Q (2018) https://doi.org/10.1117/12.2313236

KEYWORDS: Particles, Sensors, Electrons, Monte Carlo methods, Data modeling, Bismuth, Physics, Gold, Signal detection

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Proceedings Article | 6 July 2018 Paper

Paper

The DAQ system support to the AIV activities of the ASTRI camera proposed for the Cherenkov Telescope Array

V. Conforti, F. Gianotti, M. Trifoglio, A. Bulgarelli, V. Fioretti, O. Catalano, M. Capalbi, P. Sangiorgi

Proceedings Volume 10707, 1070724 (2018) https://doi.org/10.1117/12.2312131

KEYWORDS: Data acquisition, Cameras, Telescopes

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The Cherenkov Telescope Array (CTA), the next generation ground-based observatory for very high-energy gamma rays, is being built and will be operated by an international consortium. Two arrays will be located in the northern and southern hemispheres. Each telescope array will operate different numbers and types of telescopes. The Italian National Institute for Astrophysics (INAF) is leading the ASTRI (Astrofisica con Specchi a Tecnologia Replicante Italiana) project in the framework of the small size class of telescopes (SST). A first goal of the ASTRI project is the realization of an end-to-end prototype in dual-mirror configuration (SST-2M). The ASTRI camera focal plane is composed of a matrix of silicon photo-multiplier sensors managed by innovative front-end and back-end electronics. The ASTRI SST2M prototype is installed in Italy at the INAF “M.G. Fracastoro” observing station located at Serra La Nave, 1735 m a.s.l. on Mount Etna, Sicily. The ASTRI Data AcQuisition (DAQ) system acquires, packet by packet, the camera data from the back-end electronics. The packets are then stored locally in one raw file as soon as they arrive. During the acquisition, the DAQ system groups the packets by data type (scientific, calibration, engineering) before processing and storing the data in FITS format. All the files are then transferred to the on-site archive. In addition, we implemented a quick-look component the allows the operator to display the camera data during the acquisition. A graphical user interface enables the operator to configure, monitor and control the DAQ software. Furthermore, we implemented the control panel algorithms within the framework of the Alma Common Software, in order to integrate the DAQ software within the ASTRI control software. The ASTRI DAQ system supports the camera AIV activities and operations. We provide the instrument workstation to support the AIV activities in the laboratory, and the camera server on-site. In this paper, we assess the ASTRI DAQ system as it has performed the AIV tasks for the ASTRI SST-2M prototype.

Proceedings Article | 6 July 2018 Paper

Paper

Simulating modulated x-ray calibration sources for future x-ray missions using GEANT4

C. de Vries, V. Fioretti, J.-W. den Herder, E. Schyns, S. Pinto

Proceedings Volume 10699, 1069965 (2018) https://doi.org/10.1117/12.2305475

KEYWORDS: X-rays, Electrons, Calibration, Silicon, Chromium, Copper, Sensors, Beryllium, X-ray sources, Particles

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Proceedings Article | 6 July 2018 Presentation + Paper

Presentation + Paper

The e-ASTROGAM gamma-ray space observatory for the multimessenger astronomy of the 2030s

V. Tatischeff, A. De Angelis, M. Tavani, I. Grenier, U. Oberlack, L. Hanlon, R. Walter, A. Argan, P. von Ballmoos, A. Bulgarelli, I. Donnarumma, M. Hernanz, I. Kuvvetli, M. Mallamaci, M. Pearce, A. Zdziarski, A. Aboudan, M. Ajello, G. Ambrosi, D. Bernard, E. Bernardini, V. Bonvicini, A. Brogna, M. Branchesi, C. Budtz-Jorgensen, A. Bykov, R. Campana, M. Cardillo, S. Ciprini, P. Coppi, P. Cumani, R. M. Curado da Silva, D. De Martino, R. Diehl, M. Doro, V. Fioretti, S. Funk, G. Ghisellini, J. E. Grove, F. Giordano, C. Hamadache, D. Hartmann, M. Hayashida, J. Isern, G. Kanbach, J. Kiener, J. Knödlseder, C. Labanti, P. Laurent, M. Leising, O. Limousin, F. Longo, K. Mannheim, M. Marisaldi, M. Martinez, N. Mazziotta, J. McEnery, S. Mereghetti, G. Minervini, A. Moiseev, A. Morselli, K. Nakazawa, P. Orleanski, J. Paredes, B. Patricelli, J. Peyré, G. Piano, M. Pohl, R. Rando, M. Roncadelli, F. Tavecchio, D. Thompson, R. Turolla, A. Ulyanov, A. Vacchi, X. Wu, A. Zoglauer

Proceedings Volume 10699, 106992J (2018) https://doi.org/10.1117/12.2315151

KEYWORDS: Gamma radiation, Polarization, Astronomy, Space telescopes, Pulsars, Polarimetry, Telescopes, Sensors, Observatories, Gamma-ray astronomy

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Proceedings Article | 6 July 2018 Presentation + Paper

Presentation + Paper

Evaluation of the ATHENA/WFI instrumental background

Andreas von Kienlin, Tanja Eraerds, Esra Bulbul, Valentine Fioretti, Fabio Gastaldello, Catherine Grant, David Hall, Andrew Holland, Jonathan Keelan, Norbert Meidinger, Silvano Molendi, Emanuele Perinati, Arne Rau

Proceedings Volume 10699, 106991I (2018) https://doi.org/10.1117/12.2311987

KEYWORDS: Particles, Sensors, Electrons, X-rays, Physics, Monte Carlo methods, Molybdenum, Aluminum, Optical filters, Cameras

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Proceedings Article | 6 July 2018 Paper

Paper

The Geant4 mass model of the ATHENA Silicon Pore Optics and its effect on soft proton scattering

Valentina Fioretti, Andrea Bulgarelli, Simone Lotti, Claudio Macculi, Teresa Mineo, Luigi Piro, Debora Bruno, Massimo Cappi, Mauro Dadina

Proceedings Volume 10699, 106993J (2018) https://doi.org/10.1117/12.2312729

KEYWORDS: Scattering, Silicon, Mirrors, X-rays, Coating, Physics, Particles, Solar radiation models, Reflection, X-ray telescopes

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Given the unprecedented effective area, the new ATHENA Silicon Pore Optics (SPO) focusing technology, the dynamic and variable L2 environment, where no X-ray mission has flown up to date, a dedicated Geant4 simulation campaign is needed to evaluate the impact of low energy protons scattering on the ATHENA mirror surface and the induced residual background level on its X-ray detectors. The Geant4 mass model of ATHENA SPO is built as part of the ESA AREMBES project activities using the BoGEMMS framework. An SPO mirror module row is the atomic unit of the mass model, allowing the simulation of the full structure by means of 20 independent runs, one for each row. No reflecting coating is applied in the model: this simplification implies small differences (few percentages) in the proton flux, while reducing the number of volumes composing the mass model and the consequent simulation processing time. Thanks to the BoGEMMS configuration files, both single pores, mirror modules or the entire SPO row can be built with the same Geant4 geometry. The conical approximation used for the Si plates transmits 20% less photons than the actual SPO design, simulated with a ray-tracing code. Assuming the same transmission reduction for protons, a 20% uncertainty can be accepted given the overall uncertainties of the input fluxes. Both Remizovich, in its elastic approximation, and Coulomb single scattering Geant4 models are used in the interaction of mono-energetic proton beams with a single SPO pore. The scattering efficiency for the first model is almost twice the efficiency obtained with the latter but for both cases we obtain similar polar and azimuthal angular distributions, with about 70-75% of scatterings generated by single or double reflections. The soft proton flux modelled for the plasma sheet region is used as input for the simulation of soft proton funneling by the full SPO mass model. A much weaker soft proton vignetting than the one observed by XMM-Newton EPIC detectors is generated by ATHENA mirrors. The residual soft proton flux reaching the focal plane, defined as a 15 cm radius, is 10⁴ times lower than the input L2 soft proton population entering the mirror, at the same energy, with rates comparable or higher than the ones observed in XMM EPIC-pn most intense soft proton flares.

Proceedings Article | 22 August 2016 Paper

Paper

The Cherenkov Telescope Array Observatory: top level use cases

A. Bulgarelli, K. Kosack, J. Hinton, G. Tosti, U. Schwanke, J. Schwarz, P. Colomé, V. Conforti, B. Khelifi, J. Goullon, R. Ong, S. Markoff, J. L. Contreras, F. Lucarelli, L. Antonelli, C. Bigongiari, C. Boisson, Z. Bosnjak, S. Brau-Nogué, A. Carosi, A. Chen, G. Cotter, S. Covino, M. Daniel, G. De Cesare, E. de Ona Wilhelmi, M. Della Volpe, F. Di Pierro, V. Fioretti, M. Füßling, M. Garczarczyk, M. Gaug, J. F. Glicenstein, P. Goldoni, D. Götz, P. Grandi, M. Heller, G. Hermann, S. Inoue, J. Knödlseder, J.-P. Lenain, E. Lindfors, S. Lombardi, P. Luque-Escamilla, G. Maier, M. Marisaldi, C. Mundell, N. Neyroud, K. Noda, P. O'Brien, P. O. Petrucci, J. Martí Ribas, M. Ribó, J. Rodriguez, P. Romano, J. Schmid, N. Serre, H. Sol, F. Schussler, A. Stamerra, T. Stolarczyk, J. Vandenbrouck, S. Vercellone, S. Vergani, A. Zech, A. Zoli

Proceedings Volume 9913, 991331 (2016) https://doi.org/10.1117/12.2232224

KEYWORDS: Observatories, Atmospheric Cherenkov telescopes, Telescopes, Software development, Astronomy, Software engineering, Physics, Telecommunications, Error analysis, Galactic astronomy

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Today the scientific community is facing an increasing complexity of the scientific projects, from both a technological and a management point of view. The reason for this is in the advance of science itself, where new experiments with unprecedented levels of accuracy, precision and coverage (time and spatial) are realised. Astronomy is one of the fields of the physical sciences where a strong interaction between the scientists, the instrument and software developers is necessary to achieve the goals of any Big Science Project. The Cherenkov Telescope Array (CTA) will be the largest ground-based very high-energy gamma-ray observatory of the next decades. To achieve the full potential of the CTA Observatory, the system must be put into place to enable users to operate the telescopes productively. The software will cover all stages of the CTA system, from the preparation of the observing proposals to the final data reduction, and must also fit into the overall system. Scientists, engineers, operators and others will use the system to operate the Observatory, hence they should be involved in the design process from the beginning. We have organised a workgroup and a workflow for the definition of the CTA Top Level Use Cases in the context of the Requirement Management activities of the CTA Observatory. Scientists, instrument and software developers are collaborating and sharing information to provide a common and general understanding of the Observatory from a functional point of view. Scientists that will use the CTA Observatory will provide mainly Science Driven Use Cases, whereas software engineers will subsequently provide more detailed Use Cases, comments and feedbacks. The main purposes are to define observing modes and strategies, and to provide a framework for the flow down of the Use Cases and requirements to check missing requirements and the already developed Use-Case models at CTA sub-system level. Use Cases will also provide the basis for the definition of the Acceptance Test Plan for the validation of the overall CTA system. In this contribution we present the organisation and the workflow of the Top Level Use Cases workgroup.

Proceedings Article | 9 August 2016 Paper

Paper

The ASTRI mini-array software system (MASS) implementation: a proposal for the Cherenkov Telescope Array

Claudio Tanci, Gino Tosti, Vito Conforti, Joseph Schwarz, Elisa Antolini, L. Antonelli, Andrea Bulgarelli, Ciro Bigongiari, Pietro Bruno, Rodolfo Canestrari, Milvia Capalbi, Enrico Cascone, Osvaldo Catalano, Andrea Di Paola, Federico Di Pierro, Valentina Fioretti, Stefano Gallozzi, Daniele Gardiol, Fulvio Gianotti, Enrico Giro, Alessandro Grillo, Nicola La Palombara, Giuseppe Leto, Saverio Lombardi, Maria Maccarone, Giovanni Pareschi, Federico Russo, Pierluca Sangiorgi, Salvo Scuderi, Luca Stringhetti, Vincenzo Testa, Massimo Trifoglio, Stefano Vercellone, Andrea Zoli

Proceedings Volume 9913, 99133L (2016) https://doi.org/10.1117/12.2231294

KEYWORDS: Atmospheric Cherenkov telescopes, Telescopes, Data acquisition, Prototyping, Control systems, Cameras, Imaging systems, Data archive systems, Human-machine interfaces, Lanthanum

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Proceedings Article | 8 August 2016 Paper

Paper

The ICT monitoring system of the ASTRI SST-2M prototype proposed for the Cherenkov Telescope Array

F. Gianotti, P. Bruno, A. Tacchini, V. Conforti, V. Fioretti, C. Tanci, A. Grillo, G. Leto, G. Malaguti, M. Trifoglio

Proceedings Volume 9913, 99132I (2016) https://doi.org/10.1117/12.2231609

KEYWORDS: Atmospheric Cherenkov telescopes, Telecommunications, Printed circuit board testing, Computing systems, Prototyping, Telescopes, Optical proximity correction, Human-machine interfaces, Telecommunications, Computing systems, Control systems, Astronomical telescopes

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Proceedings Article | 29 July 2016 Paper

Paper

Instrument workstation for the EGSE of the Near Infrared Spectro-Photometer instrument (NISP) of the EUCLID mission

M. Trifoglio, F. Gianotti, V. Conforti, E. Franceschi, J. Stephen, A. Bulgarelli, V. Fioretti, E. Maiorano, L. Nicastro, L. Valenziano, A. Zoli, N. Auricchio, A. Balestra, D. Bonino, C. Bonoli, F. Bortoletto, V. Capobianco, T. Chiarusi, L. Corcione, S. Debei, A. De Rosa, S. Dusini, F. Fornari, F. Giacomini, G. Guizzo, S. Ligori, A. Margiotta, N. Mauri, E. Medinaceli, G. Morgante, L. Patrizii, C. Sirignano, G. Sirri, F. Sortino, L. Stanco, M. Tenti

Proceedings Volume 9904, 990460 (2016) https://doi.org/10.1117/12.2234219

KEYWORDS: Data storage, Near infrared, Computing systems, Data processing, Sensors, Data archive systems, Data modeling, Control systems, Databases, Data conversion

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Proceedings Article | 29 July 2016 Paper

Paper

EGSE customization for the Euclid NISP Instrument AIV/AIT activities

E. Franceschi, M. Trifoglio, F. Gianotti, V. Conforti, J. Andersen, J. Stephen, L. Valenziano, N. Auricchio, A. Bulgarelli, A. De Rosa, V. Fioretti, E. Maiorano, G. Morgante, L. Nicastro, F. Sortino, A. Zoli, A. Balestra, D. Bonino, C. Bonoli, F. Bortoletto, V. Capobianco, L. Corcione, F. Dal Corso, S. Debei, D. Di Ferdinando, S. Dusini, R. Farinelli, F. Fornari, F. Giacomini, G. Guizzo, F. Laudisio, S. Ligori, N. Mauri, E. Medinaceli, L. Patrizii, C. Sirignano, G. Sirri, L. Stanco, M. Tenti, C. Valieri, S. Ventura

Proceedings Volume 9904, 99042T (2016) https://doi.org/10.1117/12.2234262

KEYWORDS: Space telescopes, Space operations, Telescopes, Space operations, Local area networks, Databases, Control systems, Fermium, Frequency modulation, Device simulation, Data modeling

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Proceedings Article | 27 July 2016 Paper

Paper

The Cherenkov Telescope array on-site integral sensitivity: observing the Crab

Valentina Fioretti, Andrea Bulgarelli, Fabian Schüssler

Proceedings Volume 9906, 99063O (2016) https://doi.org/10.1117/12.2231398

KEYWORDS: Atmospheric Cherenkov telescopes, Telescopes, Observatories, Reconstruction algorithms, Gamma radiation, Monte Carlo methods, Target detection, Wind energy, Photons, Space telescopes

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The Cherenkov Telescope Array (CTA) is the future large observatory in the very high energy (VHE) domain. Operating from 20 GeV to 300 TeV, it will be composed of tens of Imaging Air Cherenkov Telescopes (IACTs) displaced in a large area of a few square kilometers in both the southern and northern hemispheres. Thanks to the wide energy coverage and the tremendous boost in effective area (10 times better than the current IACTs), for the first time a VHE observatory will be able to detect transient phenomena in short exposures. The CTA/DATA On-Site Analysis (OSA) is the system devoted to the development of dedicated pipelines and algorithms to be used at the CTA site for the reconstruction, data quality monitoring, science monitoring and realtime science alerting during observations. The minimum exposure required to issue a science alert is not a general requirement of the observatory but is a function of the astrophysical object under study, because the ability to detect a given source is determined by the integral sensitivity which, in addition to the CTA Monte Carlo simulations, providing the energy-dependent instrument response (e.g. the effective area and the background rate), requires the spectral distribution of the science target. The OSA integral sensitivity is computed here for the most studied source at Gamma-rays, the Crab Nebula, for a set of exposures ranging from 1000 seconds to 50 hours, using the full CTA Southern array. The reason for the Crab Nebula selection as the first example of OSA integral sensitivity is twofold: (i) this source is characterized by a broad spectrum covering the entire CTA energy range; (ii) it represents, at the time of writing, the standard candle in VHE and it is often used as unit for the IACTs sensitivity. The effect of different Crab Nebula emission models on the CTA integral sensitivity is evaluated, to emphasize the need for representative spectra of the CTA science targets in the evaluation of the OSA use cases. Using the most complete model as input to the OSA integral sensitivity, we obtain a significant detection of the Crab nebula (about 10% of flux) even for a 1000 second exposure, for an energy threshold less than 10 TeV.

Proceedings Article | 26 July 2016 Paper

Paper

Software design of the ASTRI camera server proposed for the Cherenkov Telescope Array

Vito Conforti, Massimo Trifoglio, Fulvio Gianotti, Giuseppe Malaguti, Andrea Bulgarelli, Valentina Fioretti, Andrea Zoli, Osvaldo Catalano, Milvia Capalbi, Pierluca Sangiorgi

Proceedings Volume 9913, 99133G (2016) https://doi.org/10.1117/12.2230016

KEYWORDS: Cameras, Atmospheric Cherenkov telescopes, Telescopes, Data acquisition, Optical instrument design, Prototyping, Optical instrument design, Receivers, Data processing, Muons, Calibration

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The Italian National Institute for Astrophysics (INAF) is leading the ASTRI project within the ambitious Cherenkov Telescope Array (CTA), the next generation of ground-based observatories for very high energy gamma-ray astronomy. In the framework of the small sized telescopes (SST), a first goal of the ASTRI project is the realization of an end-to-end prototype in dual-mirror configuration (2M) with the camera composed of a matrix of Silicon photo-multiplier sensors managed by innovative front-end and back-end electronics. The prototype, named ASTRI SST-2M, is installed in Italy at the INAF “M.G. Fracastoro” observing station located at Serra La Nave, 1735 m a.s.l. on Mount Etna, Sicily. As a second step, the ASTRI project is focused on the implementation of a mini-array composed at least of nine ASTRI telescopes and proposed to be placed at the CTA southern site. This paper outlines the design of the camera server software that will be installed on the ASTRI mini-array. The software is based on the version installed on the ASTRI SST-2M prototype operating in a single telescope configuration. The migration from single telescope to mini-array context has required additional interfaces in order to guarantee high interoperability with other software and hardware components. In the mini-array configuration each camera communicates with its own camera server via a dedicated high rate data link. The primary goal of the camera server is to acquire the bulk data, packet by packet, without any data loss and to timestamp each packet very precisely. During array operation, the camera server receives from the SoftWare Array Trigger (SWAT) the list of science events that participate in stereo triggered events. These science events, and all others that are flagged either by the camera as interleaved calibration or by the camera server as possible single-muon events, are sent to the Array DAQ. All remaining science events will be discarded. A suitable buffer is provided to perform this processing on all the incoming event packets. The camera server provides interfaces to the array control software to allow for monitoring and control during array operations. In this paper we present the design of the camera server software with particular emphasis on the external interfaces. In addition, we report the results of the first integration activities and performance tests.

Proceedings Article | 26 July 2016 Paper

Paper

Software use cases to elicit the software requirements analysis within the ASTRI project

Vito Conforti, Elisa Antolini, Giacomo Bonnoli, Pietro Bruno, Andrea Bulgarelli, Milvia Capalbi, Valentina Fioretti, Dino Fugazza, Daniele Gardiol, Alessandro Grillo, Giuseppe Leto, Saverio Lombardi, Fabrizio Lucarelli, Maria Concetta Maccarone, Giuseppe Malaguti, Giovanni Pareschi, Federico Russo, Pierluca Sangiorgi, Joseph Schwarz, Salvatore Scuderi, Claudio Tanci, Gino Tosti, Massimo Trifoglio, Stefano Vercellone, Ricardo Zanmar Sanchez

Proceedings Volume 9913, 991340 (2016) https://doi.org/10.1117/12.2232292

KEYWORDS: Atmospheric Cherenkov telescopes, Telescopes, Prototyping, Telecommunications, Cameras, Data acquisition, Control systems, Calibration, Optical fiber cables, Error analysis

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The Italian National Institute for Astrophysics (INAF) is leading the Astrofisica con Specchi a Tecnologia Replicante Italiana (ASTRI) project whose main purpose is the realization of small size telescopes (SST) for the Cherenkov Telescope Array (CTA). The first goal of the ASTRI project has been the development and operation of an innovative end-to-end telescope prototype using a dual-mirror optical configuration (SST-2M) equipped with a camera based on silicon photo-multipliers and very fast read-out electronics. The ASTRI SST-2M prototype has been installed in Italy at the INAF “M.G. Fracastoro” Astronomical Station located at Serra La Nave, on Mount Etna, Sicily. This prototype will be used to test several mechanical, optical, control hardware and software solutions which will be used in the ASTRI mini-array, comprising nine telescopes proposed to be placed at the CTA southern site. The ASTRI mini-array is a collaborative and international effort led by INAF and carried out by Italy, Brazil and South-Africa. We present here the use cases, through UML (Unified Modeling Language) diagrams and text details, that describe the functional requirements of the software that will manage the ASTRI SST-2M prototype, and the lessons learned thanks to these activities. We intend to adopt the same approach for the Mini Array Software System that will manage the ASTRI miniarray operations. Use cases are of importance for the whole software life cycle; in particular they provide valuable support to the validation and verification activities. Following the iterative development approach, which breaks down the software development into smaller chunks, we have analysed the requirements, developed, and then tested the code in repeated cycles. The use case technique allowed us to formalize the problem through user stories that describe how the user procedurally interacts with the software system. Through the use cases we improved the communication among team members, fostered common agreement about system requirements, defined the normal and alternative course of events, understood better the business process, and defined the system test to ensure that the delivered software works properly. We present a summary of the ASTRI SST-2M prototype use cases, and how the lessons learned can be exploited for the ASTRI mini-array proposed for the CTA Observatory.

Proceedings Article | 18 July 2016 Paper

Paper

The e-ASTROGAM gamma-ray space mission

V. Tatischeff, M. Tavani, P. von Ballmoos, L. Hanlon, U. Oberlack, A. Aboudan, A. Argan, D. Bernard, A. Brogna, A. Bulgarelli, A. Bykov, R. Campana, P. Caraveo, M. Cardillo, P. Coppi, A. De Angelis, R. Diehl, I. Donnarumma, V. Fioretti, A. Giuliani, I. Grenier, J. E. Grove, C. Hamadache, D. Hartmann, M. Hernanz, J. Isern, G. Kanbach, J. Kiener, J. Knödlseder, C. Labanti, P. Laurent, O. Limousin, F. Longo, M. Marisaldi, S. McBreen, J. McEnery, S. Mereghetti, F. Mirabel, A. Morselli, K. Nakazawa, J. Peyré, G. Piano, C. Pittori, S. Sabatini, L. Stawarz, D. Thompson, A. Ulyanov, R. Walter, X. Wu, A. Zdziarski, A. Zoglauer

Proceedings Volume 9905, 99052N (2016) https://doi.org/10.1117/12.2231601

KEYWORDS: Gamma radiation, Sensors, Polarization, Calibration, Compton scattering, Photons, Modulation, Monte Carlo methods, Scintillators, Electronics

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Proceedings Article | 18 July 2016 Paper

Paper

Monte Carlo simulations of soft proton flares: testing the physics with XMM-Newton

Valentina Fioretti, Andrea Bulgarelli, Giuseppe Malaguti, Daniele Spiga, Andrea Tiengo

Proceedings Volume 9905, 99056W (2016) https://doi.org/10.1117/12.2232537

KEYWORDS: X-ray telescopes, Physics, Monte Carlo methods, X-rays, X-ray optics, Scattering, Optical filters, Mirrors, Multiple scattering, Space telescopes

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Low energy protons (< 100 - 300 keV) in the Van Allen belt and the outer regions can enter the field of view of X-ray focusing telescopes, interact with the Wolter-I optics, and reach the focal plane. The funneling of soft protons was discovered after the damaging of the Chandra/ACIS Front-Illuminated CCDs in September 1999 after the first passages through the radiation belt. The use of special filters protects the XMM-Newton focal plane below an altitude of 70000 km, but above this limit the effect of soft protons is still present in the form of sudden ares in the count rate of the EPIC instruments that can last from hundreds of seconds to hours and can hardly be disentangled from X-ray photons, causing the loss of large amounts of observing time. The accurate characterization of (i) the distribution of the soft proton population, (ii) the physics interaction at play, and (iii) the effect on the focal plane, are mandatory to evaluate the background and design the proton magnetic diverter on board future X-ray focusing telescopes (e.g. ATHENA). Several solutions have been proposed so far for the primary population and the physics interaction, however the difficulty in precise angle and energy measurements in laboratory makes the smoking gun still unclear. Since the only real data available is the XMM-Newton spectrum of soft proton flares in orbit, we try to characterize the input proton population and the physics interaction by simulating, using the BoGEMMS framework, the proton interaction with a simplified model of the X-ray mirror module and the focal plane, and comparing the result with a real observation. The analysis of ten orbits of observations of the EPIC/pn instrument show that the detection of flares in regions far outside the radiation belt is largely influenced by the different orientation of the Earth's magnetosphere respect with XMM-Newton'os orbit, confirming the solar origin of the soft proton population. The Equator-S proton spectrum at 70000 km altitude is used for the proton population entering the optics, where a combined multiple and Firsov scattering is used as physics interaction. If the thick filter is used, the soft protons in the 30-70 keV energy range are the main contributors to the simulated spectrum below 10 keV. We are able to reproduce the proton vignetting observed in real data-sets, with a ~ 50% decrease from the inner to the outer region, but a maximum flux of ~ 0:01 counts cm² s^-1 keV^-1 is obtained below 10 keV, about 5 times lower than the EPIC/MOS detection and 100 times lower than the EPIC/pn one. Given the high variability of the are intensity, we conclude that an average spectrum, based on the analysis of a full season of soft proton events is required to compare Monte Carlo simulations with real events.

Proceedings Article | 18 July 2016 Paper

Paper

The Cryogenic AntiCoincidence detector for ATHENA X-IFU: a program overview

C. Macculi, A. Argan, M. D'Andrea, S. Lotti, M. Laurenza, L. Piro, M. Biasotti, D. Corsini, F. Gatti, G. Torrioli, M. Fiorini, S. Molendi, M. Uslenghi, T. Mineo, A. Bulgarelli, V. Fioretti, E. Cavazzuti

Proceedings Volume 9905, 99052K (2016) https://doi.org/10.1117/12.2231298

KEYWORDS: Sensors, Cryogenics, Particles, Staring arrays, Electrons, Silicon, Electronics, Principal component analysis, Satellites, Prototyping

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The ATHENA observatory is the second large-class ESA mission, in the context of the Cosmic Vision 2015 - 2025, scheduled to be launched on 2028 at L2 orbit. One of the two on-board instruments is the X-IFU (X-ray Integral Field Unit): it is a TES-based kilo-pixels order array able to perform simultaneous high-grade energy spectroscopy (2.5 eV at 6 keV) and imaging over the 5 arcmin FoV. The X-IFU sensitivity is degraded by the particles background which is induced by primary protons of both solar and Cosmic Rays origin, and secondary electrons. The studies performed by Geant4 simulations depict a scenario where it is mandatory the use of reduction techniques that combine an active anticoincidence detector and a passive electron shielding to reduce the background expected in L2 orbit down to the goal level of 0.005 cts/cm²/s/keV, so enabling the characterization of faint or diffuse sources (e.g. WHIM or Galaxy cluster outskirts). From the detector point of view this is possible by adopting a Cryogenic AntiCoincidence (CryoAC) placed within a proper optimized environment surrounding the X-IFU TES array. It is a 4-pixels detector made of wide area Silicon absorbers sensed by Ir TESes, and put at a distance < 1 mm below the TES-array. On October 2015 the X-IFU Phase A program has been kicked-off, and about the CryoAC is at present foreseen on early 2017 the delivery of the DM1 (Demonstration Model 1) to the FPA development team for integration, which is made of 1 pixel “bridgessuspended” that will address the final design of the CryoAC. Both the background studies and the detector development work is on-going to provide confident results about the expected residual background at the TES-array level, and the single pixel design to produce a detector for testing activity on 2016/2017. Here we will provide an overview of the CryoAC program, discussing some details about the background assessment having impact on the CryoAC design, the last single pixel characterization, the structural issues, followed by some programmatic aspects.

Proceedings Article | 11 July 2016 Paper

Paper

Updates on the background estimates for the X-IFU instrument onboard of the ATHENA mission

S. Lotti, C. Macculi, M. D'Andrea, L. Piro, S. Molendi, F. Gastaldello, T. Mineo, A. D'ai, A. Bulgarelli, V. Fioretti, C. Jacquey, M. Laurenza, P. Laurent

Proceedings Volume 9905, 990563 (2016) https://doi.org/10.1117/12.2232381

KEYWORDS: Particles, Monte Carlo methods, X-rays, Sensors, Mirrors, Electrons, Photons, Solar energy, Magnetism, Bismuth

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ATHENA is the second large mission in ESA Cosmic Vision 2015-2025, with a launch foreseen in 2028 towards the L2 orbit. The mission addresses the science theme “The Hot and Energetic Universe”, by coupling a high-performance X-ray Telescope with two complementary focal-plane instruments. One of these, the X-ray Integral Field Unit (X-IFU) is a TES based kilo-pixel array, providing spatially resolved high-resolution spectroscopy (2.5 eV at 6 keV) over a 5 arcmin FoV.

The background for this kind of detectors accounts for several components: the diffuse Cosmic Xray Background, the low energy particles (< ~100 keV) focalized by the mirrors and reaching the detector from inside the field of view, and the high energy particles (> ~100 MeV) crossing the spacecraft and reaching the focal plane from every direction. In particular, these high energy particles lose energy in the materials they cross, creating secondaries along their path that can induce an additional background component.

Each one of these components is under study of a team dedicated to the background issues regarding the X-IFU, with the aim to reduce their impact on the instrumental performances. This task is particularly challenging, given the lack of data on the background of X-ray detectors in L2, the uncertainties on the particle environment to be expected in such orbit, and the reliability of the models used in the Monte Carlo background computations. As a consequence, the activities addressed by the group range from the reanalysis of the data of previous missions like XMMNewton, to the characterization of the L2 environment by data analysis of the particle monitors onboard of satellites present in the Earth magnetotail, to the characterization of solar events and their occurrence, and to the validation of the physical models involved in the Monte Carlo simulations. All these activities will allow to develop a set of reliable simulations to predict, analyze and find effective solutions to reduce the particle background experienced by the X-IFU, ultimately satisfying the scientific requirement that enables the science of ATHENA.

While the activities are still ongoing, we present here some preliminary results already obtained by the group. The L2 environment characterization activities, and the analysis and validation of the physical processes involved in the Monte Carlo simulations are the core of an ESA activity named AREMBES (Athena Radiation Environment Models and Effects), for which the work presented here represents a starting point.

Proceedings Article | 25 July 2014 Paper

Paper

Monte Carlo simulations of gamma-ray space telescopes: a BoGEMMS multi-purpose application

Valentina Fioretti, Andrea Bulgarelli, Marco Tavani, Martino Marisaldi, Sabina Sabatini, Giuseppe Malaguti, Massimo Trifoglio, Fulvio Gianotti

Proceedings Volume 9144, 91443N (2014) https://doi.org/10.1117/12.2056442

KEYWORDS: Gamma radiation, Space telescopes, Monte Carlo methods, Particles, Telescopes, Device simulation, Silicon, Physics, X-ray telescopes, Computer simulations

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Proceedings Article | 25 July 2014 Paper

Paper

The ASTRI SST-2M telescope prototype for the Cherenkov Telescope Array: camera DAQ software architecture

Vito Conforti, Massimo Trifoglio, Andrea Bulgarelli, Fulvio Gianotti, Valentina Fioretti, Alessandro Tacchini, Andrea Zoli, Giuseppe Malaguti, Milvia Capalbi, Osvaldo Catalano

Proceedings Volume 9152, 91522D (2014) https://doi.org/10.1117/12.2054519

KEYWORDS: Cameras, Data acquisition, Data storage, Atmospheric Cherenkov telescopes, Prototyping, Telescopes, Computer architecture, Software development, Data archive systems, Data conversion

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Proceedings Article | 22 July 2014 Paper

Paper

A prototype for the real-time analysis of the Cherenkov Telescope Array

Andrea Bulgarelli, Valentina Fioretti, Andrea Zoli, Alessio Aboudan, Juan José Rodríguez-Vázquez, Gernot Maier, Etienne Lyard, Denis Bastieri, Saverio Lombardi, Gino Tosti, Adriano De Rosa, Sonia Bergamaschi, Matteo Interlandi, Domenico Beneventano, Giovanni Lamanna, Jean Jacquemier, Karl Kosack, Lucio Angelo Antonelli, Catherine Boisson, Jerzy Burkowski, Sara Buson, Alessandro Carosi, Vito Conforti, Jose Luis Contreras, Giovanni De Cesare, Raquel de los Reyes, Jon Dumm, Phil Evans, Lucy Fortson, Matthias Fuessling, Ricardo Graciani, Fulvio Gianotti, Paola Grandi, Jim Hinton, Brian Humensky, Jürgen Knödlseder, Giuseppe Malaguti, Martino Marisaldi, Nadine Neyroud, Luciano Nicastro, Stefan Ohm, Julian Osborne, Simon Rosen, Alessandro Tacchini, Eleonora Torresi, Vincenzo Testa, Massimo Trifoglio, Amanda Weinstein

Proceedings Volume 9145, 91452X (2014) https://doi.org/10.1117/12.2054744

KEYWORDS: Atmospheric Cherenkov telescopes, Telescopes, Data acquisition, Prototyping, Cameras, Observatories, Physics, Data communications, Monte Carlo methods, Data storage

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Proceedings Article | 18 July 2014 Paper

Paper

The control, monitor, and alarm system for the ICT equipment of the ASTRI SST-2M telescope prototype for the Cherenkov Telescope Array

Fulvio Gianotti, Valentina Fioretti, Claudio Tanci, Vito Conforti, Alessandro Tacchini, Giuseppe Leto, Stefano Gallozzi, Andrea Bulgarelli, Massimo Trifoglio, Giuseppe Malaguti, Andrea Zoli

Proceedings Volume 9152, 91521U (2014) https://doi.org/10.1117/12.2054713

KEYWORDS: Optical proximity correction, Atmospheric Cherenkov telescopes, Telescopes, Prototyping, Printed circuit board testing, Control systems, OLE for process control, Standards development, Computing systems, Internet

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Proceedings Article | 25 September 2012 Paper

Paper

BoGEMMS: the Bologna Geant4 multi-mission simulator

A. Bulgarelli, V. Fioretti, P. Malaguti, M. Trifoglio, F. Gianotti

Proceedings Volume 8453, 845335 (2012) https://doi.org/10.1117/12.926065

KEYWORDS: Particles, Physics, Monte Carlo methods, Optical filters, Space operations, Space telescopes, Computer architecture, 3D modeling, Data modeling, Sensors

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Proceedings Article | 25 September 2012 Paper

Paper

The low Earth orbit radiation environment and its impact on the prompt background of hard x-ray focusing telescopes

V. Fioretti, A. Bulgarelli, G. Malaguti, V. Bianchin, M. Trifoglio, F. Gianotti

Proceedings Volume 8453, 845331 (2012) https://doi.org/10.1117/12.926248

KEYWORDS: Particles, X-rays, Light emitting diodes, Hard x-rays, Atmospheric particles, Scintillators, Photons, Electrons, Sensors, X-ray telescopes

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Proceedings Article | 15 July 2008 Paper

Paper

A magnetic diverter for charged particle background rejection in the SIMBOL-X telescope

D. Spiga, V. Fioretti, A. Bulgarelli, E. Dell'Orto, L. Foschini, G. Malaguti, G. Pareschi, G. Tagliaferri, A. Tiengo

Proceedings Volume 7011, 70112Y (2008) https://doi.org/10.1117/12.789917

KEYWORDS: Magnetism, Particles, Electrons, Mirrors, Sensors, X-rays, Scattering, X-ray telescopes, Reflection, Reflectivity

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