Floquet theory and stability analysis for Hamiltonian PDEs

Jared C. Bronski; Vera Mikyoung Hur; Robert Marangell

doi:10.1088/1361-6544/ad8698

Floquet theory and stability analysis for Hamiltonian PDEs

Jared C. Bronski, Vera Mikyoung Hur, Robert Marangell

Mathematics

Research output: Contribution to journal › Article › peer-review

Abstract

We analyze Floquet theory as it applies to the stability and instability of periodic traveling waves in Hamiltonian PDEs. Our investigation focuses on several examples of such PDEs, including the generalized KdV and BBM equations (third order), the nonlinear Schrödinger and Boussinesq equations (fourth order), and the Kawahara equation (fifth order). Our analysis reveals that the characteristic polynomial of the monodromy matrix inherits symmetry from the underlying PDE, enabling us to determine the essential spectrum along the imaginary axis and bifurcations of the spectrum away from the axis, employing the Floquet discriminant. We present numerical evidence to support our analytical findings.

Original language	English (US)
Article number	125010
Journal	Nonlinearity
Volume	37
Issue number	12
DOIs	https://doi.org/10.1088/1361-6544/ad8698
State	Published - Dec 2 2024

Keywords

34C25
35B10
35B35
Floquet theory
Hamiltonian systems
periodic traveling waves
spectrum
stability

ASJC Scopus subject areas

Statistical and Nonlinear Physics
Mathematical Physics
General Physics and Astronomy
Applied Mathematics

Online availability

10.1088/1361-6544/ad8698

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title = "Floquet theory and stability analysis for Hamiltonian PDEs",

abstract = "We analyze Floquet theory as it applies to the stability and instability of periodic traveling waves in Hamiltonian PDEs. Our investigation focuses on several examples of such PDEs, including the generalized KdV and BBM equations (third order), the nonlinear Schr{\"o}dinger and Boussinesq equations (fourth order), and the Kawahara equation (fifth order). Our analysis reveals that the characteristic polynomial of the monodromy matrix inherits symmetry from the underlying PDE, enabling us to determine the essential spectrum along the imaginary axis and bifurcations of the spectrum away from the axis, employing the Floquet discriminant. We present numerical evidence to support our analytical findings.",

keywords = "34C25, 35B10, 35B35, Floquet theory, Hamiltonian systems, periodic traveling waves, spectrum, stability",

author = "Bronski, {Jared C.} and {Mikyoung Hur}, Vera and Robert Marangell",

note = "RM would like to thank the Sydney Mathematical Research Institute for support during the writing of this paper and is partially supported by ARC Discovery Project DP210101102. VMH is supported by NSF DMS\u20132009981.",

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doi = "10.1088/1361-6544/ad8698",

language = "English (US)",

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AU - Bronski, Jared C.

AU - Mikyoung Hur, Vera

AU - Marangell, Robert

N1 - RM would like to thank the Sydney Mathematical Research Institute for support during the writing of this paper and is partially supported by ARC Discovery Project DP210101102. VMH is supported by NSF DMS\u20132009981.

PY - 2024/12/2

Y1 - 2024/12/2

N2 - We analyze Floquet theory as it applies to the stability and instability of periodic traveling waves in Hamiltonian PDEs. Our investigation focuses on several examples of such PDEs, including the generalized KdV and BBM equations (third order), the nonlinear Schrödinger and Boussinesq equations (fourth order), and the Kawahara equation (fifth order). Our analysis reveals that the characteristic polynomial of the monodromy matrix inherits symmetry from the underlying PDE, enabling us to determine the essential spectrum along the imaginary axis and bifurcations of the spectrum away from the axis, employing the Floquet discriminant. We present numerical evidence to support our analytical findings.

AB - We analyze Floquet theory as it applies to the stability and instability of periodic traveling waves in Hamiltonian PDEs. Our investigation focuses on several examples of such PDEs, including the generalized KdV and BBM equations (third order), the nonlinear Schrödinger and Boussinesq equations (fourth order), and the Kawahara equation (fifth order). Our analysis reveals that the characteristic polynomial of the monodromy matrix inherits symmetry from the underlying PDE, enabling us to determine the essential spectrum along the imaginary axis and bifurcations of the spectrum away from the axis, employing the Floquet discriminant. We present numerical evidence to support our analytical findings.

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KW - spectrum

KW - stability

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Floquet theory and stability analysis for Hamiltonian PDEs

Abstract

Keywords

ASJC Scopus subject areas

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