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Sulaiman Alvi1,2, Christian W Bauer2, Benjamin Nachman2,3

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|February 28, 2023
PubMed
Summary
This summary is machine-generated.

Classical Machine Learning (CML) outperformed Quantum Machine Learning (QML) for anomaly detection in Large Hadron Collider (LHC) data. CML successfully identified anomalous events in simulated datasets, even with limited training data.

Keywords:
Multi-Higgs ModelsNew Light Particles

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Area of Science:

  • High Energy Physics
  • Quantum Computing
  • Machine Learning

Background:

  • Anomaly detection is crucial for discovering new physics at the Large Hadron Collider (LHC).
  • Semi-supervised learning approaches are suitable for analyzing complex datasets with limited labeled examples.
  • Quantum Machine Learning (QML) is a potential candidate for enhancing data analysis in high-energy physics.

Purpose of the Study:

  • To investigate the efficacy of Quantum Machine Learning (QML) for anomaly detection in a specific high-energy physics context.
  • To compare the performance of QML algorithms against Classical Machine Learning (CML) benchmarks in a semi-supervised setting.
  • To assess the potential for quantum advantage in classification tasks with small training datasets.

Main Methods:

  • A semi-supervised learning approach was applied to simulated four-lepton final state data from the LHC.
  • Standard QML algorithms were implemented and evaluated for anomaly detection.
  • CML algorithms were used as benchmarks for performance comparison.
  • Injected anomalous events were used to test the models' ability to identify deviations from background processes.

Main Results:

  • Classical Machine Learning (CML) benchmarks demonstrated superior performance compared to standard QML algorithms.
  • CML models were capable of automatically identifying anomalous events within background-only datasets.
  • The study explored a scenario (small training datasets) where quantum advantage is theoretically predicted.

Conclusions:

  • Current CML methods are effective and outperform QML for this specific anomaly detection task at the LHC.
  • The potential for quantum advantage in this regime requires further investigation with more advanced QML algorithms or different problem formulations.
  • The findings highlight the importance of robust CML benchmarks in evaluating emerging quantum computing applications.