Application of Quantum Machine Learning using the Quantum Kernel Algorithm on High Energy Physics Analysis at the LHC
Abstract
Quantum machine learning could possibly become a valuable alternative to classical machine learning for applications in High Energy Physics by offering computational speed-ups. In this study, we employ a support vector machine with a quantum kernel estimator (QSVM-Kernel method) to a recent LHC flagship physics analysis: (Higgs boson production in association with a top quark pair). In our quantum simulation study using up to 20 qubits and up to 50000 events, the QSVM-Kernel method performs as well as its classical counterparts in three different platforms from Google Tensorflow Quantum, IBM Quantum and Amazon Braket. Additionally, using 15 qubits and 100 events, the application of the QSVM-Kernel method on the IBM superconducting quantum hardware approaches the performance of a noiseless quantum simulator. Our study confirms that the QSVM-Kernel method can use the large dimensionality of the quantum Hilbert space to replace the classical feature space in realistic physics datasets.
Cite
@article{arxiv.2104.05059,
title = {Application of Quantum Machine Learning using the Quantum Kernel Algorithm on High Energy Physics Analysis at the LHC},
author = {Sau Lan Wu and Shaojun Sun and Wen Guan and Chen Zhou and Jay Chan and Chi Lung Cheng and Tuan Pham and Yan Qian and Alex Zeng Wang and Rui Zhang and Miron Livny and Jennifer Glick and Panagiotis Kl. Barkoutsos and Stefan Woerner and Ivano Tavernelli and Federico Carminati and Alberto Di Meglio and Andy C. Y. Li and Joseph Lykken and Panagiotis Spentzouris and Samuel Yen-Chi Chen and Shinjae Yoo and Tzu-Chieh Wei},
journal= {arXiv preprint arXiv:2104.05059},
year = {2021}
}