A massively scalable Time-to-Digital Converter with a PLL-free calibration system in a commercial 130 nm process

A 33.6 ps LSB Time-to-Digital converter was designed in 130 nm BiCMOS technology. The core of the converter is a differential 9-stage ring oscillator, based on a multi-path architecture. A novel version of this design is proposed, along with an analytical model of linearity. The model allowed us to...

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Autores principales: Martinelli, Fulvio, Valerio, Pierpaolo, Cardarelli, Roberto, Charbon, Edoardo, Iacobucci, Giuseppe, Nessi, Marzio, Paolozzi, Lorenzo
Lenguaje:eng
Publicado: 2021
Materias:
hep-ex
Particle Physics - Experiment
physics.ins-det
Detectors and Experimental Techniques
Acceso en línea:https://dx.doi.org/10.1088/1748-0221/16/11/P11023
http://cds.cern.ch/record/2778450
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author Martinelli, Fulvio
Valerio, Pierpaolo
Cardarelli, Roberto
Charbon, Edoardo
Iacobucci, Giuseppe
Nessi, Marzio
Paolozzi, Lorenzo
author_facet Martinelli, Fulvio
Valerio, Pierpaolo
Cardarelli, Roberto
Charbon, Edoardo
Iacobucci, Giuseppe
Nessi, Marzio
Paolozzi, Lorenzo
author_sort Martinelli, Fulvio
collection CERN
description A 33.6 ps LSB Time-to-Digital converter was designed in 130 nm BiCMOS technology. The core of the converter is a differential 9-stage ring oscillator, based on a multi-path architecture. A novel version of this design is proposed, along with an analytical model of linearity. The model allowed us to understand the source of the performance superiority (in terms of linearity) of our design and to predict further improvements. The oscillator is integrated in a event-by-event self-calibration system that allows avoiding any PLL-based synchronization. For this reason and for the compactness and simplicity of the architecture, the proposed TDC is suitable for applications in which a large number of converters and a massive parallelization are required such as High-Energy Physics and medical imaging detector systems. A test chip for the TDC has been fabricated and tested. The TDC shows a DNL≤1.3 LSB, an INL≤2 LSB and a single-shot precision of 19.5 ps (0.58 LSB). The chip dissipates a power of 5.4 mW overall.
id cern-2778450
institution Organización Europea para la Investigación Nuclear
language eng
publishDate 2021
record_format invenio
spelling cern-27784502023-01-31T08:10:57Zdoi:10.1088/1748-0221/16/11/P11023http://cds.cern.ch/record/2778450engMartinelli, FulvioValerio, PierpaoloCardarelli, RobertoCharbon, EdoardoIacobucci, GiuseppeNessi, MarzioPaolozzi, LorenzoA massively scalable Time-to-Digital Converter with a PLL-free calibration system in a commercial 130 nm processhep-exParticle Physics - Experimentphysics.ins-detDetectors and Experimental TechniquesA 33.6 ps LSB Time-to-Digital converter was designed in 130 nm BiCMOS technology. The core of the converter is a differential 9-stage ring oscillator, based on a multi-path architecture. A novel version of this design is proposed, along with an analytical model of linearity. The model allowed us to understand the source of the performance superiority (in terms of linearity) of our design and to predict further improvements. The oscillator is integrated in a event-by-event self-calibration system that allows avoiding any PLL-based synchronization. For this reason and for the compactness and simplicity of the architecture, the proposed TDC is suitable for applications in which a large number of converters and a massive parallelization are required such as High-Energy Physics and medical imaging detector systems. A test chip for the TDC has been fabricated and tested. The TDC shows a DNL≤1.3 LSB, an INL≤2 LSB and a single-shot precision of 19.5 ps (0.58 LSB). The chip dissipates a power of 5.4 mW overall.A 33.6 ps LSB Time-to-Digital converter was designed in 130 nm BiCMOS technology. The core of the converter is a differential 9-stage ring oscillator, based on a multi-path architecture. A novel version of this design is proposed, along with an analytical model of linearity. The model allowed us to understand the source of the performance superiority (in terms of linearity) of our design and to predict further improvements. The oscillator is integrated in a event-by-event self-calibration system that allows avoiding any PLL-based synchronization. For this reason and for the compactness and simplicity of the architecture, the proposed TDC is suitable for applications in which a large number of converters and a massive parallelization are required such as High-Energy Physics and medical imaging detector systems. A test chip for the TDC has been fabricated and tested. The TDC shows a DNL$\leq$1.3 LSB, an INL$\leq$2 LSB and a single-shot precision of 19.5 ps (0.58 LSB). The chip dissipates a power of 5.4 mW overall.arXiv:2107.10162oai:cds.cern.ch:27784502021-07-21
spellingShingle hep-ex
Particle Physics - Experiment
physics.ins-det
Detectors and Experimental Techniques
Martinelli, Fulvio
Valerio, Pierpaolo
Cardarelli, Roberto
Charbon, Edoardo
Iacobucci, Giuseppe
Nessi, Marzio
Paolozzi, Lorenzo
A massively scalable Time-to-Digital Converter with a PLL-free calibration system in a commercial 130 nm process
title A massively scalable Time-to-Digital Converter with a PLL-free calibration system in a commercial 130 nm process
title_full A massively scalable Time-to-Digital Converter with a PLL-free calibration system in a commercial 130 nm process
title_fullStr A massively scalable Time-to-Digital Converter with a PLL-free calibration system in a commercial 130 nm process
title_full_unstemmed A massively scalable Time-to-Digital Converter with a PLL-free calibration system in a commercial 130 nm process
title_short A massively scalable Time-to-Digital Converter with a PLL-free calibration system in a commercial 130 nm process
title_sort massively scalable time-to-digital converter with a pll-free calibration system in a commercial 130 nm process
topic hep-ex
Particle Physics - Experiment
physics.ins-det
Detectors and Experimental Techniques
url https://dx.doi.org/10.1088/1748-0221/16/11/P11023
http://cds.cern.ch/record/2778450
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