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Representer Theorem for Learning Koopman Operators

Mohammad Khosravi

2023IEEE Transactions on Automatic Control17 citationsDOIOpen Access PDF

Abstract

In this work, we consider the problem of learning the Koopman operator for discrete-time autonomous systems. The learning problem is formulated as a generic constrained regularized empirical loss minimization in the infinite-dimensional space of linear operators. We show that a representer theorem holds for the introduced learning problem under certain but general conditions, which allows convex reformulation of the problem in a specific finite-dimensional space without any approximation and loss of precision. We discuss the inclusion of various forms of regularization and constraints in the learning problem, such as the operator norm, the Frobenius norm, the operator rank, the nuclear norm, and the stability. Subsequently, we derive the corresponding equivalent finite-dimensional problem. Furthermore, we demonstrate the connection between the proposed formulation and the extended dynamic mode decomposition. We present several numerical examples to illustrate the theoretical results and verify the performance of regularized learning of the Koopman operators.

Topics & Concepts

MathematicsRepresenter theoremOperator (biology)Operator theoryApplied mathematicsOperator normRegularization (linguistics)Norm (philosophy)Spectral theoremMathematical optimizationMatrix normConvex optimizationUnbounded operatorRegular polygonAlgebra over a fieldApproximation propertyComputer sciencePure mathematicsBanach spaceArtificial intelligenceEigenvalues and eigenvectorsTranscription factorKernel principal component analysisRepressorQuantum mechanicsGeneLawPhysicsGeometrySupport vector machineChemistryBiochemistryPolitical scienceKernel methodModel Reduction and Neural NetworksNumerical methods in inverse problems
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