GPU simulation with Opticks: The future of optical simulations for LZ

Oisín Creaner; Simon Blyth; Sam Eriksen; Lisa Gerhardt; Maria Elena Monzani; Quentin Riffard

doi:10.1051/epjconf/202125103037

GPU simulation with Opticks: The future of optical simulations for LZ

Oisín Creaner^*, Simon Blyth, Sam Eriksen, Lisa Gerhardt, Maria Elena Monzani, Quentin Riffard

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Conference Contribution (Conference Proceeding)

Abstract

The LZ collaboration aims to directly detect dark matter by using a liquid xenon Time Projection Chamber (TPC). In order to probe the dark matter signal, observed signals are compared with simulations that model the detector response. The most computationally expensive aspect of these simulations is the propagation of photons in the detector’s sensitive volume. For this reason, we propose to offload photon propagation modelling to the Graphics Processing Unit (GPU), by integrating Opticks into the LZ simulations workflow. Opticks is a system which maps Geant4 geometry and photon generation steps to NVIDIA’s OptiX GPU raytracing framework. This paradigm shift could simultaneously achieve a massive speed-up and an increase in accuracy for LZ simulations. By using the technique of containerization through Shifter, we will produce a portable system to harness the NERSC supercomputing facilities, including the forthcoming Perlmutter supercomputer, and enable the GPU processing to handle different detector configurations. Prior experience with using Opticks to simulate JUNO indicates the potential for speed-up factors over 1000× for LZ, and by extension other experiments requiring photon propagation simulations.

Original language	English
Title of host publication	EPJ Web of Conferences
Editors	Chérifa Boukacem-Zeghmouri, Vladimir Buzek, Heidi Gautschi, Jamshed Iqbal, Michel Paul Léonard, Paulo Limão-Vieira, Maria S. Madjarska, Thierry Maré, Nigel Mason, Biswajeet Pradhan, Maria Beatriz Silva, Jun Sun, Ming-Jun Zhang, Zhien Zhang
Publisher	EDP Sciences
Number of pages	12
Volume	251
DOIs	https://doi.org/10.1051/epjconf/202125103037
Publication status	Published - 23 Aug 2021
Event	CHEP 2021 - 25th International Conference on Computing in High Energy and Nuclear Physics - Duration: 17 May 2021 → 21 May 2021 https://www.epj-conferences.org/chep2021

Publication series

Name	EPJ Web of Conferences
Publisher	EDP Sciences
Volume	251
ISSN (Electronic)	2100-014X

Conference

Conference	CHEP 2021 - 25th International Conference on Computing in High Energy and Nuclear Physics
Abbreviated title	CHEP 2021
Period	17/05/21 → 21/05/21
Internet address	https://www.epj-conferences.org/chep2021

Bibliographical note

Publisher Copyright:
© The Authors, published by EDP Sciences, 2021

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10.1051/epjconf/202125103037Licence: CC BY

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Creaner, O., Blyth, S., Eriksen, S., Gerhardt, L., Monzani, M. E., & Riffard, Q. (2021). GPU simulation with Opticks: The future of optical simulations for LZ. In C. Boukacem-Zeghmouri, V. Buzek, H. Gautschi, J. Iqbal, M. P. Léonard, P. Limão-Vieira, M. S. Madjarska, T. Maré, N. Mason, B. Pradhan, M. B. Silva, J. Sun, M.-J. Zhang, & Z. Zhang (Eds.), EPJ Web of Conferences (Vol. 251). Article 03037 (EPJ Web of Conferences; Vol. 251). EDP Sciences. https://doi.org/10.1051/epjconf/202125103037

Creaner, Oisín ; Blyth, Simon ; Eriksen, Sam et al. / GPU simulation with Opticks : The future of optical simulations for LZ. EPJ Web of Conferences. editor / Chérifa Boukacem-Zeghmouri ; Vladimir Buzek ; Heidi Gautschi ; Jamshed Iqbal ; Michel Paul Léonard ; Paulo Limão-Vieira ; Maria S. Madjarska ; Thierry Maré ; Nigel Mason ; Biswajeet Pradhan ; Maria Beatriz Silva ; Jun Sun ; Ming-Jun Zhang ; Zhien Zhang. Vol. 251 EDP Sciences, 2021. (EPJ Web of Conferences).

@inproceedings{dc36b54fa7fd4a4b8e7400c2f4fce6c7,

title = "GPU simulation with Opticks: The future of optical simulations for LZ",

abstract = "The LZ collaboration aims to directly detect dark matter by using a liquid xenon Time Projection Chamber (TPC). In order to probe the dark matter signal, observed signals are compared with simulations that model the detector response. The most computationally expensive aspect of these simulations is the propagation of photons in the detector{\textquoteright}s sensitive volume. For this reason, we propose to offload photon propagation modelling to the Graphics Processing Unit (GPU), by integrating Opticks into the LZ simulations workflow. Opticks is a system which maps Geant4 geometry and photon generation steps to NVIDIA{\textquoteright}s OptiX GPU raytracing framework. This paradigm shift could simultaneously achieve a massive speed-up and an increase in accuracy for LZ simulations. By using the technique of containerization through Shifter, we will produce a portable system to harness the NERSC supercomputing facilities, including the forthcoming Perlmutter supercomputer, and enable the GPU processing to handle different detector configurations. Prior experience with using Opticks to simulate JUNO indicates the potential for speed-up factors over 1000× for LZ, and by extension other experiments requiring photon propagation simulations.",

author = "Ois{\'i}n Creaner and Simon Blyth and Sam Eriksen and Lisa Gerhardt and Monzani, \{Maria Elena\} and Quentin Riffard",

note = "Publisher Copyright: {\textcopyright} The Authors, published by EDP Sciences, 2021; CHEP 2021 - 25th International Conference on Computing in High Energy and Nuclear Physics, CHEP 2021 ; Conference date: 17-05-2021 Through 21-05-2021",

year = "2021",

month = aug,

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doi = "10.1051/epjconf/202125103037",

language = "English",

volume = "251",

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publisher = "EDP Sciences",

editor = "Ch{\'e}rifa Boukacem-Zeghmouri and Vladimir Buzek and Heidi Gautschi and Jamshed Iqbal and L{\'e}onard, \{Michel Paul\} and Paulo Lim{\~a}o-Vieira and Madjarska, \{Maria S.\} and Thierry Mar{\'e} and Nigel Mason and Biswajeet Pradhan and Silva, \{Maria Beatriz\} and Jun Sun and Ming-Jun Zhang and Zhien Zhang",

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Creaner, O, Blyth, S, Eriksen, S, Gerhardt, L, Monzani, ME & Riffard, Q 2021, GPU simulation with Opticks: The future of optical simulations for LZ. in C Boukacem-Zeghmouri, V Buzek, H Gautschi, J Iqbal, MP Léonard, P Limão-Vieira, MS Madjarska, T Maré, N Mason, B Pradhan, MB Silva, J Sun, M-J Zhang & Z Zhang (eds), EPJ Web of Conferences. vol. 251, 03037, EPJ Web of Conferences, vol. 251, EDP Sciences, CHEP 2021 - 25th International Conference on Computing in High Energy and Nuclear Physics, 17/05/21. https://doi.org/10.1051/epjconf/202125103037

GPU simulation with Opticks: The future of optical simulations for LZ. / Creaner, Oisín; Blyth, Simon; Eriksen, Sam et al.
EPJ Web of Conferences. ed. / Chérifa Boukacem-Zeghmouri; Vladimir Buzek; Heidi Gautschi; Jamshed Iqbal; Michel Paul Léonard; Paulo Limão-Vieira; Maria S. Madjarska; Thierry Maré; Nigel Mason; Biswajeet Pradhan; Maria Beatriz Silva; Jun Sun; Ming-Jun Zhang; Zhien Zhang. Vol. 251 EDP Sciences, 2021. 03037 (EPJ Web of Conferences; Vol. 251).

Research output: Chapter in Book/Report/Conference proceeding › Conference Contribution (Conference Proceeding)

TY - GEN

T1 - GPU simulation with Opticks

T2 - CHEP 2021 - 25th International Conference on Computing in High Energy and Nuclear Physics

AU - Creaner, Oisín

AU - Blyth, Simon

AU - Eriksen, Sam

AU - Gerhardt, Lisa

AU - Monzani, Maria Elena

AU - Riffard, Quentin

N1 - Publisher Copyright: © The Authors, published by EDP Sciences, 2021

PY - 2021/8/23

Y1 - 2021/8/23

N2 - The LZ collaboration aims to directly detect dark matter by using a liquid xenon Time Projection Chamber (TPC). In order to probe the dark matter signal, observed signals are compared with simulations that model the detector response. The most computationally expensive aspect of these simulations is the propagation of photons in the detector’s sensitive volume. For this reason, we propose to offload photon propagation modelling to the Graphics Processing Unit (GPU), by integrating Opticks into the LZ simulations workflow. Opticks is a system which maps Geant4 geometry and photon generation steps to NVIDIA’s OptiX GPU raytracing framework. This paradigm shift could simultaneously achieve a massive speed-up and an increase in accuracy for LZ simulations. By using the technique of containerization through Shifter, we will produce a portable system to harness the NERSC supercomputing facilities, including the forthcoming Perlmutter supercomputer, and enable the GPU processing to handle different detector configurations. Prior experience with using Opticks to simulate JUNO indicates the potential for speed-up factors over 1000× for LZ, and by extension other experiments requiring photon propagation simulations.

AB - The LZ collaboration aims to directly detect dark matter by using a liquid xenon Time Projection Chamber (TPC). In order to probe the dark matter signal, observed signals are compared with simulations that model the detector response. The most computationally expensive aspect of these simulations is the propagation of photons in the detector’s sensitive volume. For this reason, we propose to offload photon propagation modelling to the Graphics Processing Unit (GPU), by integrating Opticks into the LZ simulations workflow. Opticks is a system which maps Geant4 geometry and photon generation steps to NVIDIA’s OptiX GPU raytracing framework. This paradigm shift could simultaneously achieve a massive speed-up and an increase in accuracy for LZ simulations. By using the technique of containerization through Shifter, we will produce a portable system to harness the NERSC supercomputing facilities, including the forthcoming Perlmutter supercomputer, and enable the GPU processing to handle different detector configurations. Prior experience with using Opticks to simulate JUNO indicates the potential for speed-up factors over 1000× for LZ, and by extension other experiments requiring photon propagation simulations.

U2 - 10.1051/epjconf/202125103037

DO - 10.1051/epjconf/202125103037

M3 - Conference Contribution (Conference Proceeding)

VL - 251

T3 - EPJ Web of Conferences

BT - EPJ Web of Conferences

A2 - Boukacem-Zeghmouri, Chérifa

A2 - Buzek, Vladimir

A2 - Gautschi, Heidi

A2 - Iqbal, Jamshed

A2 - Léonard, Michel Paul

A2 - Limão-Vieira, Paulo

A2 - Madjarska, Maria S.

A2 - Maré, Thierry

A2 - Mason, Nigel

A2 - Pradhan, Biswajeet

A2 - Silva, Maria Beatriz

A2 - Sun, Jun

A2 - Zhang, Ming-Jun

A2 - Zhang, Zhien

PB - EDP Sciences

Y2 - 17 May 2021 through 21 May 2021

ER -

Creaner O, Blyth S, Eriksen S, Gerhardt L, Monzani ME, Riffard Q. GPU simulation with Opticks: The future of optical simulations for LZ. In Boukacem-Zeghmouri C, Buzek V, Gautschi H, Iqbal J, Léonard MP, Limão-Vieira P, Madjarska MS, Maré T, Mason N, Pradhan B, Silva MB, Sun J, Zhang MJ, Zhang Z, editors, EPJ Web of Conferences. Vol. 251. EDP Sciences. 2021. 03037. (EPJ Web of Conferences). doi: 10.1051/epjconf/202125103037

GPU simulation with Opticks: The future of optical simulations for LZ

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