On the algebra of Koopman eigenfunctions and on some of their infinities
Zahra Monfared, Saksham Malhotra, Sekiya Hajime, Ioannis Kevrekidis, Felix Dietrich
TLDR
Leveraging Koopman eigenfunctions' multiplicative group property, this paper accelerates eigenspace computation and handles singularities for global system representation.
Key contributions
- Exploits Koopman eigenfunctions' multiplicative group property for reversible systems.
- Accelerates numerical computation of Koopman eigenspaces by constructing polynomial combinations.
- Handles localized and extended eigenfunction singularities through matching and continuation techniques.
- Supports learning consistent global representations from locally sampled or sparse measurement data.
Why it matters
This paper significantly advances Koopman operator analysis by leveraging algebraic properties for faster eigenspace computation. It also addresses the critical challenge of eigenfunction singularities, enabling consistent global representations from local or sparse data. This is vital for understanding complex multistable systems and improving data-driven dynamical system modeling.
Original Abstract
For continuous-time dynamical systems with reversible trajectories, the nowhere-vanishing eigenfunctions of the Koopman operator of the system form a multiplicative group. Here, we exploit this property to accelerate the systematic numerical computation of the eigenspaces of the operator. Given a small set of (so-called ``principal'') eigenfunctions that are approximated conventionally, we can obtain a much larger set by constructing polynomials of the principal eigenfunctions. This enriches the set, and thus allows us to more accurately represent application-specific observables. Often, eigenfunctions exhibit localized singularities (e.g. in simple, one-dimensional problems with multiple steady states) or extended ones (e.g. in simple, two-dimensional problems possessing a limit cycle, or a separatrix); we discuss eigenfunction matching/continuation across such singularities. By handling eigenfunction singularities and enabling their continuation, our approach supports learning consistent global representations from locally sampled data. This is particularly relevant for multistable systems and applications with sparse or fragmented measurements.
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