Quantum convolutional neural networks for high energy physics data analysis
Samuel Yen-Chi Chen, Tzu-Chieh Wei, C. Zhang, Haiwang Yu, Shinjae Yoo
Abstract
This paper presents a quantum convolutional neural network (QCNN) for the classification of high energy physics events. The proposed model is tested using a simulated dataset from the Deep Underground Neutrino Experiment. The proposed quantum architecture demonstrates an advantage of learning faster than the classical convolutional neural networks (CNNs) under a similar number of parameters. In addition to the faster convergence, the QCNN achieves a greater test accuracy compared to CNNs. Based on our results from numerical simulations, it is a promising direction to apply QCNN and other quantum machine learning models to high energy physics and other scientific fields.
Topics & Concepts
Convolutional neural networkQuantumConvergence (economics)Artificial neural networkDeep learningComputer scienceArtificial intelligenceEnergy (signal processing)Quantum machine learningTest dataMachine learningPhysicsQuantum computerQuantum mechanicsEconomic growthProgramming languageEconomicsParticle physics theoretical and experimental studiesComputational Physics and Python ApplicationsParticle Detector Development and Performance