Limit cycle oscillations in a mechanical system under fractional-order liénard type nonlinear feedback

•Nonlinear liénard type fractional feedback self-excitation is considered.•The control is general in nature and takes van der Pol and Rayleigh type feedback as its special cases.•Limit cycle of any desired frequency and amplitude can be generated for minimum control cost.•Dynamics of generation of l...

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Bibliographic Details
Published in:Communications in nonlinear science & numerical simulation 2024-01, Vol.128, p.107612, Article 107612
Main Authors: Kundu, Prasanjit Kumar, Chatterjee, Shyamal
Format: Article
Language:English
Subjects:
Fractional-order nonlinear feedback
Limit cycle
Liénard oscillator
Rayleigh oscillator
Van der pol oscillator
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Summary:•Nonlinear liénard type fractional feedback self-excitation is considered.•The control is general in nature and takes van der Pol and Rayleigh type feedback as its special cases.•Limit cycle of any desired frequency and amplitude can be generated for minimum control cost.•Dynamics of generation of limit cycle is explained with equivalent integer-order model of the proposed control.•Theoretical results are verified by simulations and experiments. Anti-control of self-excited oscillation in mechanical and micro-mechanical systems is an important research problem due to its potential applications. In this paper, a novel fractional-order Liénard type nonlinear feedback is proposed to generate a limit cycle of desired frequency and amplitude in a single-degree-of-freedom spring-mass-damper mechanical oscillator. The feedback comprises two different fractional-order terms which are associated with both linear and nonlinear parts of the feedback and thus making it more general, with the van der Pol and Rayleigh type feedback as special cases. The analytical relations for steady-state amplitude and frequency of oscillation with the system and controller parameters are obtained by performing the nonlinear analysis with the method of two-time scale. Bifurcations of amplitude and frequency of oscillation with the fractional orders are studied in details. For any desired frequency and amplitude of oscillation, the controller parameters are obtained for minimum control cost. The analytical results are verified by numerical simulations performed in MATLAB SIMULINK and experiment. An equivalent integer-order model of the proposed fractional-order feedback system is developed to decipher the dynamics behind the generation of the limit cycle at different desired frequencies and amplitudes.
ISSN:1007-5704
1878-7274
DOI:10.1016/j.cnsns.2023.107612