Data-driven spectral analysis of the Koopman operator

Starting from measured data, we develop a method to compute the fine structure of the spectrum of the Koopman operator with rigorous convergence guarantees. The method is based on the observation that, in the measure-preserving ergodic setting, the moments of the spectral measure associated to a giv...

Full description

Saved in:
Bibliographic Details
Published inApplied and computational harmonic analysis Vol. 48; no. 2; pp. 599 - 629
Main Authors Korda, Milan, Putinar, Mihai, Mezić, Igor
Format Journal Article
LanguageEnglish
Published Elsevier Inc 01.03.2020
Subjects
Christoffel–Darboux kernel
Data-driven methods
Koopman operator
Moment problem
Spectral analysis
Toeplitz matrix
Koopman operator
Moment problem
Toeplitz matrix
Christoffel–Darboux kernel
Spectral analysis
Data-driven methods
Online AccessGet full text

Cover

More Information
Summary:Starting from measured data, we develop a method to compute the fine structure of the spectrum of the Koopman operator with rigorous convergence guarantees. The method is based on the observation that, in the measure-preserving ergodic setting, the moments of the spectral measure associated to a given observable are computable from a single trajectory of this observable. Having finitely many moments available, we use the classical Christoffel–Darboux kernel to separate the atomic and absolutely continuous parts of the spectrum, supported by convergence guarantees as the number of moments tends to infinity. In addition, we propose a technique to detect the singular continuous part of the spectrum as well as two methods to approximate the spectral measure with guaranteed convergence in the weak topology, irrespective of whether the singular continuous part is present or not. The proposed method is simple to implement and readily applicable to large-scale systems since the computational complexity is dominated by inverting an N×N Hermitian positive-definite Toeplitz matrix, where N is the number of moments, for which efficient and numerically stable algorithms exist; in particular, the complexity of the approach is independent of the dimension of the underlying state-space. We also show how to compute, from measured data, the spectral projection on a given segment of the unit circle, allowing us to obtain a finite approximation of the operator that explicitly takes into account the point and continuous parts of the spectrum. Finally, we describe a relationship between the proposed method and the so-called Hankel Dynamic Mode Decomposition, providing new insights into the behavior of the eigenvalues of the Hankel DMD operator. A number of numerical examples illustrate the approach, including a study of the spectrum of the lid-driven two-dimensional cavity flow.
ISSN:1063-5203
1096-603X
DOI:10.1016/j.acha.2018.08.002