Enhanced Method for Forced Strongly Nonlinear Two-Degree-of-Freedom Nonlinear Systems Using an Integro-Differential Equation Approach

Andrew Lewis

doi:10.1007/s11071-025-11290-1

Enhanced Method for Forced Strongly Nonlinear Two-Degree-of-Freedom Nonlinear Systems Using an Integro-Differential Equation Approach

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Abstract

In this paper, a method based on an integro-differential equation approach for investigating the response of a strongly nonlinear two-degree-of-freedom system subject to sinusoidal forcing is presented and applied to a set of equations based on an aeroelastic model of an all-moving control surface with a nonlinearity in its root support in supersonic flow. The method is shown to be able to accurately determine primary and subharmonic resonances together with symmetry-breaking and period-doubling responses. Additionally, their stability has been investigated using a Harmonic Balance-based implementation of Floquet theory which is a modification of a method previously used for autonomous systems. This method was validated by comparison with time domain derived Floquet multipliers, and comparisons between the two sets of values showed very close agreement. The study also highlighted several areas for further investigation.

Original language	English
Number of pages	25
Journal	Nonlinear Dynamics
Early online date	8 Jun 2025
DOIs	https://doi.org/10.1007/s11071-025-11290-1
Publication status	E-pub ahead of print - 8 Jun 2025

Keywords

forced nonlinear systems
primary resonance
subharmonic resonance
symmetry-breaking
period-doubling
Floquet Multipliers
Primary resonance
Forced nonlinear systems
Subharmonic resonance
Symmetry-breaking
Period-doubling
Floquet multipliers

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title = "Enhanced Method for Forced Strongly Nonlinear Two-Degree-of-Freedom Nonlinear Systems Using an Integro-Differential Equation Approach",

abstract = "In this paper, a method based on an integro-differential equation approach for investigating the response of a strongly nonlinear two-degree-of-freedom system subject to sinusoidal forcing is presented and applied to a set of equations based on an aeroelastic model of an all-moving control surface with a nonlinearity in its root support in supersonic flow. The method is shown to be able to accurately determine primary and subharmonic resonances together with symmetry-breaking and period-doubling responses. Additionally, their stability has been investigated using a Harmonic Balance-based implementation of Floquet theory which is a modification of a method previously used for autonomous systems. This method was validated by comparison with time domain derived Floquet multipliers, and comparisons between the two sets of values showed very close agreement. The study also highlighted several areas for further investigation.",

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author = "Andrew Lewis",

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N2 - In this paper, a method based on an integro-differential equation approach for investigating the response of a strongly nonlinear two-degree-of-freedom system subject to sinusoidal forcing is presented and applied to a set of equations based on an aeroelastic model of an all-moving control surface with a nonlinearity in its root support in supersonic flow. The method is shown to be able to accurately determine primary and subharmonic resonances together with symmetry-breaking and period-doubling responses. Additionally, their stability has been investigated using a Harmonic Balance-based implementation of Floquet theory which is a modification of a method previously used for autonomous systems. This method was validated by comparison with time domain derived Floquet multipliers, and comparisons between the two sets of values showed very close agreement. The study also highlighted several areas for further investigation.

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KW - forced nonlinear systems

KW - primary resonance

KW - subharmonic resonance

KW - symmetry-breaking

KW - period-doubling

KW - Floquet Multipliers

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KW - Forced nonlinear systems

KW - Subharmonic resonance

KW - Symmetry-breaking

KW - Period-doubling

KW - Floquet multipliers

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ER -

Enhanced Method for Forced Strongly Nonlinear Two-Degree-of-Freedom Nonlinear Systems Using an Integro-Differential Equation Approach

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