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Structural risk minimization for quantum linear classifiers

Casper Gyurik, van Dyon Vreumingen, Vedran Dunjko

2023Quantum33 citationsDOIOpen Access PDF

Abstract

Quantum machine learning (QML) models based on parameterized quantum circuits are often highlighted as candidates for quantum computing's near-term “killer application''. However, the understanding of the empirical and generalization performance of these models is still in its infancy. In this paper we study how to balance between training accuracy and generalization performance (also called structural risk minimization) for two prominent QML models introduced by Havlíček et al. \cite{havlivcek:qsvm}, and Schuld and Killoran \cite{schuld:qsvm}. Firstly, using relationships to well understood classical models, we prove that two model parameters – i.e., the dimension of the sum of the images and the Frobenius norm of the observables used by the model – closely control the models' complexity and therefore its generalization performance. Secondly, using ideas inspired by process tomography, we prove that these model parameters also closely control the models' ability to capture correlations in sets of training examples. In summary, our results give rise to new options for structural risk minimization for QML models.

Topics & Concepts

Parameterized complexityGeneralizationStructural risk minimizationObservableMinificationQuantumComputer scienceVC dimensionDimension (graph theory)Empirical risk minimizationApplied mathematicsArtificial intelligenceAlgorithmMathematicsMathematical optimizationPure mathematicsQuantum mechanicsPhysicsMathematical analysisQuantum Computing Algorithms and ArchitectureAdvancements in Semiconductor Devices and Circuit DesignMachine Learning and Algorithms
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