Abstract
Quantum computers have the potential to speed up certain computational tasks. A possibility this opens up within the field of machine learning is the use of quantum techniques that may be inefficient to simulate classically but could provide superior performance in some tasks. Machine learning algorithms are ubiquitous in particle physics and as advances are made in quantum machine learning technology there may be a similar adoption of these quantum techniques. In this work a quantum support vector machine (QSVM) is implemented for signal-background classification. We investigate the effect of different quantum encoding circuits, the process that transforms classical data into a quantum state, on the final classification performance. We show an encoding approach that achieves an average Area Under Receiver Operating Characteristic Curve (AUC) of 0.848 determined using quantum circuit simulations. For this same dataset the best classical method tested, a classical Support Vector Machine (SVM) using the Radial Basis Function (RBF) Kernel achieved an AUC of 0.793. Using a reduced version of the dataset we then ran the algorithm on the IBM Quantum ibmq_casablanca device achieving an average AUC of 0.703. As further improvements to the error rates and availability of quantum computers materialise, they could form a new approach for data analysis in high energy physics.
Highlights
There are a number of measurements in flavour physics that are statistically limited due to lack of precision in signalbackground classification
We have demonstrated on a small scale how quantum machine learning may be applied to signal-background classification for continuum suppression in the study of B mesons
Simulating the combinatorial encoding circuit on the signal-background classification problem we measured an average Area Under Receiver Operating Characteristic Curve (AUC) of 0.822, outperforming the classical Support Vector Machine (SVM) and XGBoost methods tested for this dataset
Summary
There are a number of measurements in flavour physics that are statistically limited due to lack of precision in signalbackground classification. A superior classification algorithm would allow improved measurements and may result in the discovery of physics beyond the standard model. To investigate a specific B meson decay mode, such as B → K+K− , we select only events that contain particle tracks identified as K+K− that could have originated from B mesons (which will include some falsely identified K+K− tracks from the qqpair). We refer to these particles as originating from the B candidate. We exclude particles associated with the B candidate and use the variables from the other B meson which are
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