arXiv : Hybrid Quantum Classical Graph Neural Networks for Particle Track Reconstruction

Tüysüz, Cenk; Demirköz, Bilge; Forster, Richard; Novotny, Kristiane; Vallecorsa, Sofia; Dobos, Daniel; Vlimant, Jean-Roch; Rieger, Carla; Potamianos, Karolos

doi:10.1007/s42484-021-00055-9

Article
Report number	arXiv:2109.12636
Title	Hybrid Quantum Classical Graph Neural Networks for Particle Track Reconstruction
Author(s)	Tüysüz, Cenk (Middle East Tech. U., Ankara) ; Rieger, Carla (ETH, Zurich (main)) ; Novotny, Kristiane (Lancaster U.) ; Demirköz, Bilge (Middle East Tech. U., Ankara) ; Dobos, Daniel (Lancaster U.) ; Potamianos, Karolos (Oxford U.) ; Vallecorsa, Sofia (CERN) ; Vlimant, Jean-Roch (Caltech) ; Forster, Richard (Lancaster U.)
Publication	2021-12-01
Imprint	2021-09-26
Number of pages	20
Note	20 pages, 18 figures
In:	Quant. Machine Intell. 3 (2021) 29
DOI	10.1007/s42484-021-00055-9
Subject category	cs.LG ; Computing and Computers ; quant-ph ; General Theoretical Physics
Accelerator/Facility, Experiment	CERN LHC
Abstract	The Large Hadron Collider (LHC) at the European Organisation for Nuclear Research (CERN) will be upgraded to further increase the instantaneous rate of particle collisions (luminosity) and become the High Luminosity LHC (HL-LHC). This increase in luminosity will significantly increase the number of particles interacting with the detector. The interaction of particles with a detector is referred to as "hit". The HL-LHC will yield many more detector hits, which will pose a combinatorial challenge by using reconstruction algorithms to determine particle trajectories from those hits. This work explores the possibility of converting a novel Graph Neural Network model, that can optimally take into account the sparse nature of the tracking detector data and their complex geometry, to a Hybrid Quantum-Classical Graph Neural Network that benefits from using Variational Quantum layers. We show that this hybrid model can perform similar to the classical approach. Also, we explore Parametrized Quantum Circuits (PQC) with different expressibility and entangling capacities, and compare their training performance in order to quantify the expected benefits. These results can be used to build a future road map to further develop circuit based Hybrid Quantum-Classical Graph Neural Networks.
Copyright/License	publication: © The Author(s) (License: CC BY 4.0) preprint: (License: CC BY 4.0)

$TrackML detector geometry projected to 2 dimensions ($r$, $z$). The region highlighted in orange indicates the detector layers used in this work. Drawing is adapted from \cite{trackml}.$