A method for luminosity determination based on real-time hit reconstruction with the LHCb silicon pixel detector

LHCb Collaboration; Elena Graverini; Daniele Passaro; Marco Adinolfi; Jake Amey; Jozie J Cottee Meldrum; Zahra Ghorbanimoghaddam; Alex M Marshall; Camille A Normand; Konstantinos A.  Petridis; Jonas H Rademacker; Jake Reich; Anatoly Solomin; Jaap J Velthuis; Rui Wang; Benedict D C Westhenry; Sean J Williams; Zak Williams

doi:10.1088/1748-0221/21/04/P04011

A method for luminosity determination based on real-time hit reconstruction with the LHCb silicon pixel detector

LHCb Collaboration, Elena Graverini^*, Daniele Passaro^*, Marco Adinolfi, Jake Amey, Jozie J Cottee Meldrum, Zahra Ghorbanimoghaddam, Alex M Marshall, Camille A Normand, Konstantinos A. Petridis, Jonas H Rademacker, Jake Reich, Anatoly Solomin, Jaap J Velthuis, Rui Wang, Benedict D C Westhenry, Sean J Williams, Zak Williams

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

Abstract

The data acquisition system of the upgraded LHCb experiment includes the fast reconstruction of all hits in the vertex locator (VELO) pixel detector at the beam-crossing rate of 40 MHz, implemented as on-the-fly clustering embedded in the firmware of the readout board FPGAs. The availability of a high rate of reconstructed clusters in real time enables a new fast approach for measuring luminosity and monitoring the LHCb luminous region, directly at the detector readout level. This methodology has been implemented as an array of real-time cluster counters in the VELO readout FPGAs and has been in operation since the start of the 2024 physics run of LHCb. This paper describes the methodology and its features and performance, both on proton-proton and lead-lead collision data. The method shows a statistical resolution better than the percent level, and a sensitivity to variable running conditions of the same level. This is achieved with an intrinsic time granularity better than 100 ms, undersampled to 3 s for analysis purposes. Nonlinear behaviour is compatible with zero in a luminosity range including the LHCb Run 3 operating point.

Original language	English
Article number	P04011
Number of pages	32
Journal	Journal of Instrumentation
Volume	21
Issue number	4
DOIs	https://doi.org/10.1088/1748-0221/21/04/P04011
Publication status	Published - 15 Apr 2026

Bibliographical note

Publisher Copyright:
© 2026 Institute of Physics. All rights reserved.

Access to Document

10.1088/1748-0221/21/04/P04011Licence: CC BY

Handle.net

Persistent link

Cite this

LHCb Collaboration, Graverini, E., Passaro, D., Adinolfi, M., Amey, J., Cottee Meldrum, J. J., Ghorbanimoghaddam, Z., Marshall, A. M., Normand, C. A., Petridis, K. A., Rademacker, J. H., Reich, J., Solomin, A., Velthuis, J. J., Wang, R., Westhenry, B. D. C., Williams, S. J., & Williams, Z. (2026). A method for luminosity determination based on real-time hit reconstruction with the LHCb silicon pixel detector. Journal of Instrumentation, 21(4), Article P04011. https://doi.org/10.1088/1748-0221/21/04/P04011

@article{7009b5af98f8466baf25d33d630853a5,

title = "A method for luminosity determination based on real-time hit reconstruction with the LHCb silicon pixel detector",

abstract = "The data acquisition system of the upgraded LHCb experiment includes the fast reconstruction of all hits in the vertex locator (VELO) pixel detector at the beam-crossing rate of 40 MHz, implemented as on-the-fly clustering embedded in the firmware of the readout board FPGAs. The availability of a high rate of reconstructed clusters in real time enables a new fast approach for measuring luminosity and monitoring the LHCb luminous region, directly at the detector readout level. This methodology has been implemented as an array of real-time cluster counters in the VELO readout FPGAs and has been in operation since the start of the 2024 physics run of LHCb. This paper describes the methodology and its features and performance, both on proton-proton and lead-lead collision data. The method shows a statistical resolution better than the percent level, and a sensitivity to variable running conditions of the same level. This is achieved with an intrinsic time granularity better than 100 ms, undersampled to 3 s for analysis purposes. Nonlinear behaviour is compatible with zero in a luminosity range including the LHCb Run 3 operating point.",

author = "\{LHCb Collaboration\} and Elena Graverini and Daniele Passaro and Marco Adinolfi and Jake Amey and \{Cottee Meldrum\}, \{Jozie J\} and Zahra Ghorbanimoghaddam and Marshall, \{Alex M\} and Normand, \{Camille A\} and Petridis, \{Konstantinos A.\} and Rademacker, \{Jonas H\} and Jake Reich and Anatoly Solomin and Velthuis, \{Jaap J\} and Rui Wang and Westhenry, \{Benedict D C\} and Williams, \{Sean J\} and Zak Williams",

year = "2026",

month = apr,

day = "15",

doi = "10.1088/1748-0221/21/04/P04011",

language = "English",

volume = "21",

journal = "Journal of Instrumentation",

issn = "1748-0221",

publisher = "Institute of Physics Publishing",

number = "4",

}

LHCb Collaboration, Graverini, E, Passaro, D, Adinolfi, M, Amey, J, Cottee Meldrum, JJ, Ghorbanimoghaddam, Z, Marshall, AM, Normand, CA, Petridis, KA , Rademacker, JH , Reich, J , Solomin, A , Velthuis, JJ, Wang, R, Westhenry, BDC, Williams, SJ & Williams, Z 2026, 'A method for luminosity determination based on real-time hit reconstruction with the LHCb silicon pixel detector', Journal of Instrumentation, vol. 21, no. 4, P04011. https://doi.org/10.1088/1748-0221/21/04/P04011

TY - JOUR

T1 - A method for luminosity determination based on real-time hit reconstruction with the LHCb silicon pixel detector

AU - LHCb Collaboration

AU - Graverini, Elena

AU - Passaro, Daniele

AU - Adinolfi, Marco

AU - Amey, Jake

AU - Cottee Meldrum, Jozie J

AU - Ghorbanimoghaddam, Zahra

AU - Marshall, Alex M

AU - Normand, Camille A

AU - Petridis, Konstantinos A.

AU - Rademacker, Jonas H

AU - Reich, Jake

AU - Solomin, Anatoly

AU - Velthuis, Jaap J

AU - Wang, Rui

AU - Westhenry, Benedict D C

AU - Williams, Sean J

AU - Williams, Zak

PY - 2026/4/15

Y1 - 2026/4/15

N2 - The data acquisition system of the upgraded LHCb experiment includes the fast reconstruction of all hits in the vertex locator (VELO) pixel detector at the beam-crossing rate of 40 MHz, implemented as on-the-fly clustering embedded in the firmware of the readout board FPGAs. The availability of a high rate of reconstructed clusters in real time enables a new fast approach for measuring luminosity and monitoring the LHCb luminous region, directly at the detector readout level. This methodology has been implemented as an array of real-time cluster counters in the VELO readout FPGAs and has been in operation since the start of the 2024 physics run of LHCb. This paper describes the methodology and its features and performance, both on proton-proton and lead-lead collision data. The method shows a statistical resolution better than the percent level, and a sensitivity to variable running conditions of the same level. This is achieved with an intrinsic time granularity better than 100 ms, undersampled to 3 s for analysis purposes. Nonlinear behaviour is compatible with zero in a luminosity range including the LHCb Run 3 operating point.

AB - The data acquisition system of the upgraded LHCb experiment includes the fast reconstruction of all hits in the vertex locator (VELO) pixel detector at the beam-crossing rate of 40 MHz, implemented as on-the-fly clustering embedded in the firmware of the readout board FPGAs. The availability of a high rate of reconstructed clusters in real time enables a new fast approach for measuring luminosity and monitoring the LHCb luminous region, directly at the detector readout level. This methodology has been implemented as an array of real-time cluster counters in the VELO readout FPGAs and has been in operation since the start of the 2024 physics run of LHCb. This paper describes the methodology and its features and performance, both on proton-proton and lead-lead collision data. The method shows a statistical resolution better than the percent level, and a sensitivity to variable running conditions of the same level. This is achieved with an intrinsic time granularity better than 100 ms, undersampled to 3 s for analysis purposes. Nonlinear behaviour is compatible with zero in a luminosity range including the LHCb Run 3 operating point.

U2 - 10.1088/1748-0221/21/04/P04011

DO - 10.1088/1748-0221/21/04/P04011

M3 - Article (Academic Journal)

SN - 1748-0221

VL - 21

JO - Journal of Instrumentation

JF - Journal of Instrumentation

IS - 4

M1 - P04011

ER -

A method for luminosity determination based on real-time hit reconstruction with the LHCb silicon pixel detector

Abstract

Bibliographical note

Access to Document

Handle.net

Fingerprint

Cite this