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Anomaly detection in high-energy physics using a quantum autoencoder

Vishal S. Ngairangbam, Michael Spannowsky, Michihisa Takeuchi

2022Physical review. D/Physical review. D.108 citationsDOIOpen Access PDF

Abstract

The lack of evidence for new interactions and particles at the Large Hadron Collider (LHC) has motivated the high-energy physics community to explore model-agnostic data-analysis approaches to search for new physics. Autoencoders are unsupervised machine learning models based on artificial neural networks, capable of learning background distributions. We study quantum autoencoders based on variational quantum circuits for the problem of anomaly detection at the LHC. For a QCD $t\overline{t}$ background and resonant heavy-Higgs signals, we find that a simple quantum autoencoder outperforms classical autoencoders for the same inputs and trains very efficiently. Moreover, this performance is reproducible on present quantum devices. This shows that quantum autoencoders are good candidates for analysing high-energy physics data in future LHC runs.

Topics & Concepts

AutoencoderLarge Hadron ColliderPhysicsParticle physicsHiggs bosonQuantumAnomaly (physics)Anomaly detectionPhysics beyond the Standard ModelArtificial neural networkArtificial intelligenceComputer scienceQuantum mechanicsParticle physics theoretical and experimental studiesParticle Detector Development and PerformanceHigh-Energy Particle Collisions Research
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