Your search keyword '"R. Wheadon"' showing total 9 results

1. A 64 channels ASIC for the readout of the silicon strip detectors of the PANDA micro-vertex detector

Author

G. Mazza, D. Calvo, F. Cossio, P. De Remigis, M. Mignone, R. Wheadon, L. Silvestrin, and M. Tessaro

Subjects

Instrumentation, Mathematical Physics

Abstract

The ToASt ASIC is a 64 channel integrated circuit designed for the readout of the double-sided silicon strip sensors that will equip the micro-vertex detector of the PANDA experiment. The ToASt ASIC operates with a 160 MHz clock, which defines also the time resolution. A common time stamp is distributed to all channels to provide a common time reference for time of arrival and time over threshold measurements. Two 160 Mb/s serial lines provide the interface to the data concentrator. ToASt is implemented in a commercial 110 nm CMOS technology with triplicated logic to protect against single event upsets.

Published

2023

2. A radiation tolerant 12 bit, 160 MS/s data conversion and transmission ASIC for the CMS electromagnetic calorimeter

Author

G. Mazza, S. Argirò, G. Dellacasa, M. Mignone, D. Soldi, J. Varela, and R. Wheadon

Subjects

Hardware_INTEGRATEDCIRCUITS, Hardware_ARITHMETICANDLOGICSTRUCTURES, Instrumentation, Mathematical Physics

Abstract

The readout electronics for the CMS electromagnetic calorimeter is undergoing a re-design in order to cope with the LHC ugrade. In particular, a fourfold increase in the sampling frequency (from 40 to 160 MS/s) is required. Therefore a new readout ASIC has been developed. The ASIC, named LiTE-DTU, is designed in a CMOS 65 nm technology. The LiTE-DTU embeds two 12 bit, 160 MS/s ADCs, a time window based sample selection, lossless data compression and 1.28 Gb/s serialization. An on-chip PLL provides the 1.28 GHz clock required by the ADCs and the serializers from the 160 MHz clock.

Published

2022

3. A four-dimensional photon detector for PET application

Author

B. Liu, A. Del Guerra, Maria Ionica, Matteo Morrocchi, Maria Giuseppina Bisogni, M.A. Piliero, G. Pirrone, Francesco Pennazio, V. Postolache, R. Wheadon, Giovanni Ambrosi, Piergiorgio Cerello, M. Boretto, and Filippo Bosi

Subjects

gas and liquid scintillators), Photon, Lateral surface, Physics::Instrumentation and Detectors, Astrophysics::High Energy Astrophysical Phenomena, Instrumentation, Physics::Medical Physics, Physics::Optics, PET PET/CT, 01 natural sciences, Collimated light, 030218 nuclear medicine & medical imaging, Crystal, 03 medical and health sciences, 0302 clinical medicine, Optics, Silicon photomultiplier, EMCCDs etc), 0103 physical sciences, APDs, medicine, Gamma camera, SPECT, PET PET/CT, coronary CT angiography (CTA), Photon detectors for UV, visible and IR photons (solid-state) (PIN diodes, APDs, Si-PMTs, G-APDs, CCDs, EBCCDs, EMCCDs etc), Scintillators, scintillation and light emission processes (solid, gas and liquid scintillators), Mathematical Physics, visible and IR photons (solid-state) (PIN diodes, Gamma camera, coronary CT angiography (CTA), Photon detectors for UV, Physics, EBCCDs, medicine.diagnostic_test, 010308 nuclear & particles physics, business.industry, Detector, Si-PMTs, CCDs, scintillation and light emission processes (solid, Positron emission tomography, SPECT, G-APDs, Scintillators, business

Abstract

We analyzed a photon detector for positron emission tomography with high spatial resolution and depth of interaction capability. The detector is composed of a monolithic LYSO scintillator crystal coupled on top and bottom sides to two custom SiPM arrays. We investigated the ability to reconstruct the DOI of the 511 keV photon comparing the number of triggered SiPMs on the two sides of the module. Acquisitions were performed scanning the lateral surface of the crystal with a collimated 511 keV photon beam at different incident positions. A standard deviation of 1.5 mm in depth of interaction was obtained at the center of the module.

Published

2016

4. Particle beam microstructure reconstruction and coincidence discrimination in PET monitoring for hadron therapy.

Author

E Kostara, G Sportelli, N Belcari, N Camarlinghi, P Cerello, A Del Guerra, V Ferrero, E Fiorina, G Giraudo, M Morrocchi, F Pennazio, M Pullia, A Rivetti, M D Rolo, V Rosso, R Wheadon, and M G Bisogni

Subjects

HADRONS, PARTICLE beams, COINCIDENCE, POSITRON emission tomography, RADIOACTIVE decay, PROTON beams, ION beams

Abstract

Positron emission tomography is one of the most mature techniques for monitoring the particles range in hadron therapy, aiming to reduce treatment uncertainties and therefore the extent of safety margins in the treatment plan. In-beam PET monitoring has been already performed using inter-spill and post-irradiation data, i.e. while the particle beam is off or paused. The full beam acquisition procedure is commonly discarded because the particle spills abruptly increase the random coincidence rates and therefore the image noise. This is because random coincidences cannot be separated by annihilation photons originating from radioactive decays and cannot be corrected with standard random coincidence techniques due to the time correlation of the beam-induced background with the ion beam microstructure. The aim of this paper is to provide a new method to recover in-spill data to improve the images obtained with full-beam PET acquisitions. This is done by estimating the temporal microstructure of the beam and thus selecting input PET events that are less likely to be random ones. The PET detector we used was the one developed within the INSIDE project and tested at the CNAO synchrotron-based facility. The data were taken on a PMMA phantom irradiated with 72 MeV proton pencil beams. The obtained results confirm the possibility of improving the acquired PET data without any external signal coming from the synchrotron or ad hoc detectors. [ABSTRACT FROM AUTHOR]

Published

2019

5. Full-beam performances of a PET detector with synchrotron therapeutic proton beams.

Author

M A Piliero, F Pennazio, M G Bisogni, N Camarlinghi, P G Cerello, A Del Guerra, V Ferrero, E Fiorina, G Giraudo, M Morrocchi, C Peroni, G Pirrone, G Sportelli, and R Wheadon

Subjects

POSITRON emission tomography, PROTON therapy, TREATMENT effectiveness

Abstract

Treatment quality assessment is a crucial feature for both present and next-generation ion therapy facilities. Several approaches are being explored, based on prompt radiation emission or on PET signals by -decaying isotopes generated by beam interactions with the body. In-beam PET monitoring at synchrotron-based ion therapy facilities has already been performed, either based on inter-spill data only, to avoid the influence of the prompt radiation, or including both in-spill and inter-spill data. However, the PET images either suffer of poor statistics (inter-spill) or are more influenced by the background induced by prompt radiation (in-spill). Both those problems are expected to worsen for accelerators with improved duty cycle where the inter-spill interval is reduced to shorten the treatment time. With the aim of assessing the detector performance and developing techniques for background reduction, a test of an in-beam PET detector prototype was performed at the CNAO synchrotron-based ion therapy facility in full-beam acquisition modality. Data taken with proton beams impinging on PMMA phantoms showed the system acquisition capability and the resulting activity distribution, separately reconstructed for the in-spill and the inter-spill data. The coincidence time resolution for in-spill and inter-spill data shows a good agreement, with a slight deterioration during the spill. The data selection technique allows the identification and rejection of most of the background originated during the beam delivery. The activity range difference between two different proton beam energies (68 and 72 MeV) was measured and found to be in sub-millimeter agreement with the expected result. However, a slightly longer (2 mm) absolute profile length is obtained for in-spill data when compared to inter-spill data. [ABSTRACT FROM AUTHOR]

Published

2016

6. Proton therapy monitoring: spatiotemporal emission reconstruction with prompt gamma timing and implementation with PET detectors.

Author

Pennazio F, Ferrero V, D'Onghia G, Garbolino S, Fiorina E, Marti Villarreal OA, Mas Milian F, Monaco V, Monti V, Patera A, Werner J, Wheadon R, and Rafecas M

Subjects

Gamma Rays therapeutic use, Humans, Monte Carlo Method, Photons therapeutic use, Positron-Emission Tomography, Proton Therapy

Abstract

Objective . In this study we introduce spatiotemporal emission reconstruction prompt gamma timing (SER-PGT), a new method to directly reconstruct the prompt photon emission in the space and time domains inside the patient in proton therapy. Approach . SER-PGT is based on the numerical optimisation of a multidimensional likelihood function, followed by a post-processing of the results. The current approach relies on a specific implementation of the maximum-likelihood expectation maximisation algorithm. The robustness of the method is guaranteed by the complete absence of any information about the target composition in the algorithm. Main results . Accurate Monte Carlo simulations indicate a range resolution of about 0.5 cm (standard deviation) when considering 10 7 primary protons impinging on an homogeneous phantom. Preliminary results on an anthropomorphic phantom are also reported. Significance . By showing the feasibility for the reconstruction of the primary particle range using PET detectors, this study provides significant basis for the development of an hybrid in-beam PET and prompt photon device., (Creative Commons Attribution license.)

Published

2022

7. Particle beam microstructure reconstruction and coincidence discrimination in PET monitoring for hadron therapy.

Author

Kostara E, Sportelli G, Belcari N, Camarlinghi N, Cerello P, Del Guerra A, Ferrero V, Fiorina E, Giraudo G, Morrocchi M, Pennazio F, Pullia M, Rivetti A, Rolo MD, Rosso V, Wheadon R, and Bisogni MG

Subjects

Humans, Image Processing, Computer-Assisted, Proton Therapy instrumentation, Radiotherapy Planning, Computer-Assisted, Radiotherapy, Image-Guided instrumentation, Safety, Synchrotrons, Uncertainty, Positron-Emission Tomography, Proton Therapy methods, Radiotherapy, Image-Guided methods

Abstract

Positron emission tomography is one of the most mature techniques for monitoring the particles range in hadron therapy, aiming to reduce treatment uncertainties and therefore the extent of safety margins in the treatment plan. In-beam PET monitoring has been already performed using inter-spill and post-irradiation data, i.e. while the particle beam is off or paused. The full beam acquisition procedure is commonly discarded because the particle spills abruptly increase the random coincidence rates and therefore the image noise. This is because random coincidences cannot be separated by annihilation photons originating from radioactive decays and cannot be corrected with standard random coincidence techniques due to the time correlation of the beam-induced background with the ion beam microstructure. The aim of this paper is to provide a new method to recover in-spill data to improve the images obtained with full-beam PET acquisitions. This is done by estimating the temporal microstructure of the beam and thus selecting input PET events that are less likely to be random ones. The PET detector we used was the one developed within the INSIDE project and tested at the CNAO synchrotron-based facility. The data were taken on a PMMA phantom irradiated with 72 MeV proton pencil beams. The obtained results confirm the possibility of improving the acquired PET data without any external signal coming from the synchrotron or ad hoc detectors.

Published

2019

8. Carbon ions beam therapy monitoring with the INSIDE in-beam PET.

Author

Pennazio F, Battistoni G, Bisogni MG, Camarlinghi N, Ferrari A, Ferrero V, Fiorina E, Morrocchi M, Sala P, Sportelli G, Wheadon R, and Cerello P

Subjects

Humans, Monte Carlo Method, Radiometry methods, Synchrotrons, Heavy Ion Radiotherapy, Phantoms, Imaging, Positron-Emission Tomography methods, Proton Therapy, Radiometry instrumentation, Radiotherapy Planning, Computer-Assisted methods

Abstract

In vivo range monitoring techniques are necessary in order to fully take advantage of the high dose gradients deliverable in hadrontherapy treatments. Positron emission tomography (PET) scanners can be used to monitor beam-induced activation in tissues and hence measure the range. The INSIDE (Innovative Solutions for In-beam DosimEtry in Hadrontherapy) in-beam PET scanner, installed at the Italian National Center of Oncological Hadrontherapy (CNAO, Pavia, Italy) synchrotron facility, has already been successfully tested in vivo during a proton therapy treatment. We discuss here the system performance evaluation with carbon ion beams, in view of future in vivo tests. The work is focused on the analysis of activity images obtained with therapeutic treatments delivered to polymethyl methacrylate (PMMA) phantoms, as well as on the test of an innovative and robust Monte Carlo simulation technique for the production of reliable prior activity maps. Images are reconstructed using different integration intervals, so as to monitor the activity evolution during and after the treatment. Three procedures to compare activity images are presented, namely Pearson correlation coefficient, Beam's eye view and overall view. Images of repeated irradiations of the same treatments are compared to assess the integration time necessary to provide reproducible images. The range agreement between simulated and experimental images is also evaluated, so as to validate the simulation capability to provide sound prior information. The results indicate that at treatment end, or at most 20 s afterwards, the range measurement is reliable within 1-2 mm, when comparing both different experimental sessions and data with simulations. In conclusion, this work shows that the INSIDE in-beam PET scanner performance is promising towards its in vivo test with carbon ions.

Published

2018

9. Full-beam performances of a PET detector with synchrotron therapeutic proton beams.

Author

Piliero MA, Pennazio F, Bisogni MG, Camarlinghi N, Cerello PG, Del Guerra A, Ferrero V, Fiorina E, Giraudo G, Morrocchi M, Peroni C, Pirrone G, Sportelli G, and Wheadon R

Subjects

Humans, Image Processing, Computer-Assisted methods, Phantoms, Imaging, Positron-Emission Tomography instrumentation, Proton Therapy instrumentation, Synchrotrons instrumentation

Abstract

Treatment quality assessment is a crucial feature for both present and next-generation ion therapy facilities. Several approaches are being explored, based on prompt radiation emission or on PET signals by [Formula: see text]-decaying isotopes generated by beam interactions with the body. In-beam PET monitoring at synchrotron-based ion therapy facilities has already been performed, either based on inter-spill data only, to avoid the influence of the prompt radiation, or including both in-spill and inter-spill data. However, the PET images either suffer of poor statistics (inter-spill) or are more influenced by the background induced by prompt radiation (in-spill). Both those problems are expected to worsen for accelerators with improved duty cycle where the inter-spill interval is reduced to shorten the treatment time. With the aim of assessing the detector performance and developing techniques for background reduction, a test of an in-beam PET detector prototype was performed at the CNAO synchrotron-based ion therapy facility in full-beam acquisition modality. Data taken with proton beams impinging on PMMA phantoms showed the system acquisition capability and the resulting activity distribution, separately reconstructed for the in-spill and the inter-spill data. The coincidence time resolution for in-spill and inter-spill data shows a good agreement, with a slight deterioration during the spill. The data selection technique allows the identification and rejection of most of the background originated during the beam delivery. The activity range difference between two different proton beam energies (68 and 72 MeV) was measured and found to be in sub-millimeter agreement with the expected result. However, a slightly longer (2 mm) absolute profile length is obtained for in-spill data when compared to inter-spill data.

Published

2016