Related papers: Quantum Machine Learning and its Supremacy in High Energy Physics

Quantum Machine Learning and its Supremacy in High Energy Physics

URL: http://arxiv.org/abs/2011.11478v1
Date: Tue, 17 Nov 2020 17:12:17 GMT
Title: Quantum Machine Learning and its Supremacy in High Energy Physics
Authors: Kapil K. Sharma
Abstract summary: This article reveals the future prospects of quantum algorithms in high energy physics (HEP) The key technique to solve these problems is pattern recognition, which is an important application of machine learning.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: This article reveals the future prospects of quantum algorithms in high energy physics (HEP). Particle identification, knowing their properties and characteristics is a challenging problem in experimental HEP. The key technique to solve these problems is pattern recognition, which is an important application of machine learning and unconditionally used for HEP problems. To execute pattern recognition task for track and vertex reconstruction, the particle physics community vastly use statistical machine learning methods. These methods vary from detector to detector geometry and magnetic field used in the experiment. Here in the present introductory article, we deliver the future possibilities for the lucid application of quantum computation and quantum machine learning in HEP, rather than focusing on deep mathematical structures of techniques arise in this domain.

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