Your search keyword '"Coronary CT Angiography (CTA)"' showing total 6 results

1. Evaluation of a timing integrated circuit architecture for continuous crystal and SiPM based PET systems

Author

A. Ros, Ricardo Colom-Palero, R Gadea-Girones, I V Perino, Ramón J. Aliaga, V. Herrero-Bosch, and José Monzó

Subjects

Computer science, Physics::Instrumentation and Detectors, Integrated circuit, PET PET/CT, Signal, Timing detectors, law.invention, Time-to-digital converter, TECNOLOGIA ELECTRONICA, Silicon photomultiplier, law, Front-end electronics for detector readout, Electronic engineering, Digital signal, Instrumentation, Gamma camera, Mathematical Physics, Electronic circuit, Electronic detector readout concepts (solid-state), business.industry, Detector, Electrical engineering, Analog signal, SPECT, business, Coronary CT angiography (CTA)

Abstract

[EN] Improving timing resolution in positron emission tomography (PET), thus having fine time information of the detected pulses, is important to increase the reconstructed images signal to noise ratio (SNR) [1]. In the present work, an integrated circuit topology for time extraction of the incoming pulses is evaluated. An accurate simulation including the detector physics and the electronics with different configurations has been developed. The selected architecture is intended for a PET system based on a continuous scintillation crystal attached to a SiPM array. The integrated circuit extracts the time stamp from the first few photons generated when the gamma-ray interacts with the scintillator, thus obtaining the best time resolution. To get the time stamp from the detected pulses, a time to digital converter (TDC) array based architecture has been proposed as in [2] or [3]. The TDC input stage uses a current comparator to transform the analog signal into a digital signal. Individually configurable trigger levels allow us to avoid false triggers due to signal noise. Using a TDC per SiPM configuration results in a very area consuming integrated circuit. One solution to this problem is to join several SiPM outputs to one TDC. This reduces the number of TDCs but, on the other hand, the first photons will be more difficult to be detected. For this reason, it is important to simulate how the time resolution is degraded when the number of TDCs is reduced. Following this criteria, the best configuration will be selected considering the trade-off between achievable time resolution and the cost per chip. A simulation is presented that uses Geant4 for simulation of the physics process and, for the electronic blocks, spice and Matlab. The Geant4 stage simulates the gamma-ray interaction with the scintillator, the photon shower generation and the first stages of the SiPM. The electronics simulation includes an electrical model of the SiPMarray and all the integrated circuitry that generates the time stamps. Time resolution results are analyzed using Matlab. The goal is to analyze the best resolution achievable with the SiPM and its degradation due to different circuitry configurations., This work was supported by local government Conselleria d’Educacio — Generalitat Valenciana research program GV/2011/068.

Published

2013

2. Programmable integrated front-end for SiPM/PMT PET detectors with continuous scintillating crystal

Author

Jose M. Benlloch, Ricardo Colom-Palero, J.M. Monzo, C. Montoliu, A. Ros, V. Herrero-Bosch, Antonio González, and Ramón J. Aliaga

Subjects

Photomultiplier, medicine.medical_specialty, Coronary CT Angiography (CTA), Physics::Instrumentation and Detectors, Preamplifier, Computer science, Bandwidth (signal processing), Detector, PET PET/CT, Particle detector, Semiconductor detector, Front and back ends, TECNOLOGIA ELECTRONICA, Silicon photomultiplier, Front-end electronics for detector readout, SPECT, medicine, Electronic engineering, Analogue electronic circuits, Medical physics, Instrumentation, Gamma camera, Mathematical Physics

Abstract

[EN] AMIC architecture has been introduced in previous works in order to provide a generic and expandable solution for implementing large number of outputs SiPM array/PMT detectors. The underlying idea in AMIC architecture is to calculate the moments of the detected light distribution in an analog fashion. These moments provide information about energy, x/y position, etc. of the light distribution of the detected event. Moreover this means that a small set of signals contains most of the information of the event, thus reducing the number of channels to be acquired. This paper introduces a new front-end device AMIC2GR which implements the AMIC architecture improving the features of the former integrated devices. Higher bandwidth and filtering coefficient precision along with a lower noise allow to apply some detector enhancements. Inhomogeneity among detector elements throughout the array can be reduced. Depth of interaction measurements can be obtained from the light distribution analysis. Also a common trigger signal can be obtained for the whole detector array. Finally AMIC2GR preamplifier stage close to SiPM output signals optimizes signal to noise ratio, which allows to reduce SiPM gain by using lower operating voltages thus reducing dark noise, This work was supported by Universitat Politecnica de Val ` encia ` through research program PAID06-10-2212.

Published

2012

3. AMIC: an expandable integrated analog front-end for light distribution moments analysis

Author

Vicente Herrero, M. Spaggiari, R. Gadea, J.M. Monzo, Ramón J. Aliaga, and Christoph Lerche

Subjects

Coronary CT Angiography (CTA), Computer science, business.industry, Preamplifier, Detector, Electrical engineering, Integrated circuit, PET PET/CT, Current divider, law.invention, Moment (mathematics), TECNOLOGIA ELECTRONICA, Analog front-end, Application-specific integrated circuit, law, Front-end electronics for detector readout, SPECT, Analogue electronic circuits, business, Instrumentation, Gamma camera, Mathematical Physics, Voltage

Abstract

In this article we introduce AMIC (Analog Moments Integrated Circuit), a novel analog Application Specific Integrated Circuit (ASIC) front-end for Positron Emission Tomography (PET) applications. Its working principle is based on mathematical analysis of light distribution through moments calculation. Each moment provides useful information about light distribution, such as energy, position, depth of interaction, skewness (deformation due to border effect) etc. A current buffer delivers a copy of each input current to several processing blocks. The current preamplifier is designed in order to achieve unconditional stability under high input capacitance, thus allowing the use of both Photo-Multiplier Tubes (PMT) and Silicon Photo-Multipliers (SiPM). Each processing block implements an analog current filtering by multiplying each input current by a programmable 8-bit coefficient. The latter is implemented through a high linear MOS current divider ladder, whose high sensitivity to variations in output voltages requires the integration of an extremely stable fully differential current collector. Output currents are then summed and sent to the output stage, that provides both a buffered output current and a linear rail-to-rail voltage for further digitalization. Since computation is purely additive, the 64 input channels of AMIC do not represent a limitation in the number of the detector's outputs. Current outputs of various AMIC structures can be combined as inputs of a final AMIC, thus providing a fully expandable structure. In this version of AMIC, 8 programmable blocks for moments calculation are integrated, as well as an I2C interface in order to program every coefficient. Extracted layout simulation results demonstrate that the information provided by moment calculation in AMIC helps to improve tridimensional positioning of the detected event. A two-detector test-bench is now being used for AMIC prototype characterization and preliminary results are presented. © 2011 IOP Publishing Ltd and SISSA.

Published

2011

4. Evaluation of a timing integrated circuit architecture for continuous crystal and SiPM based PET systems

Author

Universitat Politècnica de València. Departamento de Ingeniería Electrónica - Departament d'Enginyeria Electrònica, Universitat Politècnica de València. Instituto de Instrumentación para Imagen Molecular - Institut d'Instrumentació per a Imatge Molecular, Generalitat Valenciana, Monzó Ferrer, José María, Ros García, Ana, Herrero Bosch, Vicente, Perino Vicentini, Ivan Virgilio, Aliaga Varea, Ramón José, Gadea Gironés, Rafael, Colom Palero, Ricardo José, Universitat Politècnica de València. Departamento de Ingeniería Electrónica - Departament d'Enginyeria Electrònica, Universitat Politècnica de València. Instituto de Instrumentación para Imagen Molecular - Institut d'Instrumentació per a Imatge Molecular, Generalitat Valenciana, Monzó Ferrer, José María, Ros García, Ana, Herrero Bosch, Vicente, Perino Vicentini, Ivan Virgilio, Aliaga Varea, Ramón José, Gadea Gironés, Rafael, and Colom Palero, Ricardo José

Abstract

[EN] Improving timing resolution in positron emission tomography (PET), thus having fine time information of the detected pulses, is important to increase the reconstructed images signal to noise ratio (SNR) [1]. In the present work, an integrated circuit topology for time extraction of the incoming pulses is evaluated. An accurate simulation including the detector physics and the electronics with different configurations has been developed. The selected architecture is intended for a PET system based on a continuous scintillation crystal attached to a SiPM array. The integrated circuit extracts the time stamp from the first few photons generated when the gamma-ray interacts with the scintillator, thus obtaining the best time resolution. To get the time stamp from the detected pulses, a time to digital converter (TDC) array based architecture has been proposed as in [2] or [3]. The TDC input stage uses a current comparator to transform the analog signal into a digital signal. Individually configurable trigger levels allow us to avoid false triggers due to signal noise. Using a TDC per SiPM configuration results in a very area consuming integrated circuit. One solution to this problem is to join several SiPM outputs to one TDC. This reduces the number of TDCs but, on the other hand, the first photons will be more difficult to be detected. For this reason, it is important to simulate how the time resolution is degraded when the number of TDCs is reduced. Following this criteria, the best configuration will be selected considering the trade-off between achievable time resolution and the cost per chip. A simulation is presented that uses Geant4 for simulation of the physics process and, for the electronic blocks, spice and Matlab. The Geant4 stage simulates the gamma-ray interaction with the scintillator, the photon shower generation and the first stages of the SiPM. The electronics simulation includes an electrical model of the SiPMarray and all the integrated circuitr

Published

2013

5. Programmable integrated front-end for SiPM/PMT PET detectors with continuous scintillating crystal

Author

Universitat Politècnica de València. Departamento de Ingeniería Electrónica - Departament d'Enginyeria Electrònica, Universitat Politècnica de València. Instituto de Instrumentación para Imagen Molecular - Institut d'Instrumentació per a Imatge Molecular, Universitat Politècnica de València, Herrero Bosch, Vicente, Monzó Ferrer, José María, Ros García, Ana, Aliaga Varea, Ramón José, González Martínez, Antonio Javier, Montoliu, C., Colom Palero, Ricardo José, Benlloch Baviera, Jose María, Universitat Politècnica de València. Departamento de Ingeniería Electrónica - Departament d'Enginyeria Electrònica, Universitat Politècnica de València. Instituto de Instrumentación para Imagen Molecular - Institut d'Instrumentació per a Imatge Molecular, Universitat Politècnica de València, Herrero Bosch, Vicente, Monzó Ferrer, José María, Ros García, Ana, Aliaga Varea, Ramón José, González Martínez, Antonio Javier, Montoliu, C., Colom Palero, Ricardo José, and Benlloch Baviera, Jose María

Abstract

[EN] AMIC architecture has been introduced in previous works in order to provide a generic and expandable solution for implementing large number of outputs SiPM array/PMT detectors. The underlying idea in AMIC architecture is to calculate the moments of the detected light distribution in an analog fashion. These moments provide information about energy, x/y position, etc. of the light distribution of the detected event. Moreover this means that a small set of signals contains most of the information of the event, thus reducing the number of channels to be acquired. This paper introduces a new front-end device AMIC2GR which implements the AMIC architecture improving the features of the former integrated devices. Higher bandwidth and filtering coefficient precision along with a lower noise allow to apply some detector enhancements. Inhomogeneity among detector elements throughout the array can be reduced. Depth of interaction measurements can be obtained from the light distribution analysis. Also a common trigger signal can be obtained for the whole detector array. Finally AMIC2GR preamplifier stage close to SiPM output signals optimizes signal to noise ratio, which allows to reduce SiPM gain by using lower operating voltages thus reducing dark noise

Published

2012

6. AMIC: an expandable integrated analog front-end for light distribution moments analysis

Author

Universitat Politècnica de València. Departamento de Ingeniería Electrónica - Departament d'Enginyeria Electrònica, Universitat Politècnica de València. Instituto Universitario de Aplicaciones de las Tecnologías de la Información - Institut Universitari d'Aplicacions de les Tecnologies de la Informació, Universitat Politècnica de València. Instituto de Instrumentación para Imagen Molecular - Institut d'Instrumentació per a Imatge Molecular, Spaggiari, Michele, Herrero Bosch, Vicente, Lerche, Christoph Werner, Aliaga Varea, Ramón José, Monzó Ferrer, José María, Gadea Gironés, Rafael, Universitat Politècnica de València. Departamento de Ingeniería Electrónica - Departament d'Enginyeria Electrònica, Universitat Politècnica de València. Instituto Universitario de Aplicaciones de las Tecnologías de la Información - Institut Universitari d'Aplicacions de les Tecnologies de la Informació, Universitat Politècnica de València. Instituto de Instrumentación para Imagen Molecular - Institut d'Instrumentació per a Imatge Molecular, Spaggiari, Michele, Herrero Bosch, Vicente, Lerche, Christoph Werner, Aliaga Varea, Ramón José, Monzó Ferrer, José María, and Gadea Gironés, Rafael

Abstract

In this article we introduce AMIC (Analog Moments Integrated Circuit), a novel analog Application Specific Integrated Circuit (ASIC) front-end for Positron Emission Tomography (PET) applications. Its working principle is based on mathematical analysis of light distribution through moments calculation. Each moment provides useful information about light distribution, such as energy, position, depth of interaction, skewness (deformation due to border effect) etc. A current buffer delivers a copy of each input current to several processing blocks. The current preamplifier is designed in order to achieve unconditional stability under high input capacitance, thus allowing the use of both Photo-Multiplier Tubes (PMT) and Silicon Photo-Multipliers (SiPM). Each processing block implements an analog current filtering by multiplying each input current by a programmable 8-bit coefficient. The latter is implemented through a high linear MOS current divider ladder, whose high sensitivity to variations in output voltages requires the integration of an extremely stable fully differential current collector. Output currents are then summed and sent to the output stage, that provides both a buffered output current and a linear rail-to-rail voltage for further digitalization. Since computation is purely additive, the 64 input channels of AMIC do not represent a limitation in the number of the detector's outputs. Current outputs of various AMIC structures can be combined as inputs of a final AMIC, thus providing a fully expandable structure. In this version of AMIC, 8 programmable blocks for moments calculation are integrated, as well as an I2C interface in order to program every coefficient. Extracted layout simulation results demonstrate that the information provided by moment calculation in AMIC helps to improve tridimensional positioning of the detected event. A two-detector test-bench is now being used for AMIC prototype characterization and preliminary results are presented. © 20

Published

2011