Transmitted and Storage-Dominated Resonance in Fractionally Damped Unidirectionally Coupled Duffing Oscillators

TL;DR

This study explores how fractional damping influences resonance transmission, energy storage, and response amplification in coupled Duffing oscillators, revealing mechanisms for tuning these phenomena via fractional memory effects.

Contribution

It demonstrates the impact of fractional damping on resonance regimes, energy redistribution, and response characteristics in unidirectionally coupled nonlinear oscillators, introducing new insights into fractional memory effects.

Findings

Distinction between transmitted and storage-dominated resonance regimes.

Fractional memory promotes temporary energy accumulation in the receiver.

Detuning receiver frequency enhances resonance and response localization.

Abstract

This paper investigates resonance transmission in two unidirectionally coupled Duffing oscillators with fractional damping, where the driver is harmonically forced and the receiver is connected through a linear coupling spring. Particular attention is paid to how fractional damping in the receiver modifies amplitude amplification, energy redistribution, and the structure of the coupled response. The numerical results reveal a clear distinction between transmitted resonance, associated with a coupling-power balance consistent with direct energy transfer through the coupling spring, and storage-dominated resonance, in which the receiver still exhibits a pronounced oscillatory response while the time-averaged coupling power becomes negative under the adopted convention. In this latter regime, fractional memory promotes temporary energy accumulation within the receiver--coupling subsystem, followed by partial release through the coupling spring without any feedback on the driver dynamics. We further show that detuning the receiver natural frequency enhances the interaction between the lower-frequency transmitted response and the higher-frequency coupled response, leading to a superposed resonance regime with increased receiver amplitude, stronger localization, and sharper response. The roles of the fractional order, coupling strength, and receiver natural frequency are systematically analyzed through frequency-response curves and parametric maps. Overall, the results show how fractional memory can be used to tune resonance transmission, energy localization, and amplified response in coupled nonlinear oscillators.