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Dynamical simulation via quantum machine learning with provable generalization

Joe Gibbs, Zoë Holmes, C. Matthias, Nicholas Ezzell, Hsin-Yuan Huang, Łukasz Cincio, Andrew Sornborger, Patrick J. Coles

2024Physical Review Research33 citationsDOIOpen Access PDF

Abstract

Much attention has been paid to dynamical simulation and quantum machine learning (QML) independently as applications for quantum advantage, while the possibility of using QML to enhance dynamical simulations has not been thoroughly investigated. Here we develop a framework for using QML methods to simulate quantum dynamics on near-term quantum hardware. We use generalization bounds, which bound the error a machine learning model makes on unseen data, to rigorously analyze the training data requirements of an algorithm within this framework. Our algorithm is thus resource efficient in terms of qubit and data requirements. Furthermore, our preliminary numerics for the XY model exhibit efficient scaling with problem size, and we simulate 20 times longer than Trotterization on IBMQ-Bogota. Published by the American Physical Society 2024

Topics & Concepts

GeneralizationComputer scienceQuantumQubitScalingQuantum computerGeneralization errorDynamical systems theoryAlgorithmArtificial intelligenceTheoretical computer scienceMathematicsArtificial neural networkPhysicsQuantum mechanicsGeometryMathematical analysisQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum and electron transport phenomena
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