TY - JOUR
T1 - Intelligent pixel detectors
T2 - 42nd International Conference on High Energy Physics, ICHEP 2024
AU - Badea, Anthony
AU - Bean, Alice
AU - Berry, Doug
AU - Dickinson, Jennet
AU - DiPetrillo, Karri
AU - Fahim, Farah
AU - Gray, Lindsey
AU - Di Guglielmo, Giuseppe
AU - Jiang, David
AU - Kovach-Fuentes, Rachel
AU - Maksimovic, Petar
AU - Mills, Corrinne
AU - Neubauer, Mark S.
AU - Parpillon, Benjamin
AU - Shekar, Danush
AU - Swartz, Morris
AU - Syal, Chinar
AU - Tran, Nhan
AU - Yoo, Jieun
N1 - Thank you to all those included in the acknowledgements of Ref [1] as well as the ICHEP organizers. AB is supported by Schmidt Sciences, LLC and utilized the UChicago AI+Science computing cluster for part of this work.
PY - 2025/4/29
Y1 - 2025/4/29
N2 - Detectors at future high energy colliders will face enormous technical challenges. Disentangling the unprecedented numbers of particles expected in each event will require highly granular silicon pixel detectors with billions of readout channels. With event rates as high as 40 MHz, these detectors will generate petabytes of data per second. To enable discovery within strict bandwidth and latency constraints, future trackers must be capable of fast, power efficient, and radiation hard data-reduction at the source. We are developing a radiation hard readout integrated circuit (ROIC) in 28nm CMOS with on-chip machine learning (ML) for future intelligent pixel detectors. We will show track parameter predictions using a neural network within a single layer of silicon and hardware tests on the first tape-outs produced with TSMC. Preliminary results indicate that reading out featurized clusters from particles above a modest momentum threshold could enable using pixel information at 40 MHz. The ICHEP presentation and proceedings are largely based on the work in Refs [1, 2].
AB - Detectors at future high energy colliders will face enormous technical challenges. Disentangling the unprecedented numbers of particles expected in each event will require highly granular silicon pixel detectors with billions of readout channels. With event rates as high as 40 MHz, these detectors will generate petabytes of data per second. To enable discovery within strict bandwidth and latency constraints, future trackers must be capable of fast, power efficient, and radiation hard data-reduction at the source. We are developing a radiation hard readout integrated circuit (ROIC) in 28nm CMOS with on-chip machine learning (ML) for future intelligent pixel detectors. We will show track parameter predictions using a neural network within a single layer of silicon and hardware tests on the first tape-outs produced with TSMC. Preliminary results indicate that reading out featurized clusters from particles above a modest momentum threshold could enable using pixel information at 40 MHz. The ICHEP presentation and proceedings are largely based on the work in Refs [1, 2].
UR - https://www.scopus.com/pages/publications/105004809801
UR - https://www.scopus.com/pages/publications/105004809801#tab=citedBy
M3 - Conference article
AN - SCOPUS:105004809801
SN - 1824-8039
VL - 476
JO - Proceedings of Science
JF - Proceedings of Science
M1 - 1074
Y2 - 18 July 2024 through 24 July 2024
ER -