Effect of a parametric damping on nonlinear dynamics of a symmetric heavy gyroscope

Chaotic dynamics, coexistence of attractors and nonlinear resonances are some of the most complex phenomena that affect the operation and performance of complex systems in general, and rotating machines in particular. This work deals with the analysis of the route to chaos and the coexistence of the...

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Bibliographic Details
Published in:Indian journal of physics 2024, Vol.98 (10), p.3623-3633
Main Authors: Nourou, Y., Miwadinou, C. H., Agossou, D. Y., Monwanou, A. V.
Format: Article
Language:English
Subjects:
Algorithms
Amplitudes
Astrophysics and Astroparticles
Bifurcations
Complex systems
Damping
Dynamical systems
Excitation
Gyroscopes
Liapunov exponents
Nonlinear dynamics
Nonlinear systems
Original Paper
Parameters
Physics
Physics and Astronomy
Resonance
Resonant frequencies
Rotating machinery
Rotating machines
Runge-Kutta method
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Summary:Chaotic dynamics, coexistence of attractors and nonlinear resonances are some of the most complex phenomena that affect the operation and performance of complex systems in general, and rotating machines in particular. This work deals with the analysis of the route to chaos and the coexistence of the attractors of a parametrically damped gyroscope. After having modeled the dynamics of the gyroscope under the influence of the control force, using numerical simulations, the types of resonances are sought, and then the amplitudes and the frequencies of the oscillations are determined. Subsequently, the study and the control of chaotic dynamics and the coexistence of gyroscope attractors are carried out using bifurcation diagrams, Lyapunov exponents and phase portraits using red fourth-order Runge–Kutta algorithm. It is shown that a high value of the parameter α considerably reduces the amplitude and the resonant frequency of the gyroscope and therefore can eliminate the resonance of the gyroscope when Ω = ω , Ω = 2 ω and Ω = 3 ω , while a large value of the parameter β or of the amplitude f of periodic excitation accentuates the resonance of the gyroscope in these cases. Similarly, an increase in the amplitude h of the parametric damping increases the resonance amplitude. Finally, the chaotic behavior and the coexistence of the attractors of the gyroscope studied depend on the values of each of the parameters α , β , f , h and the frequencies of the parametric excitation and the damping parametric force.
ISSN:0973-1458
0974-9845
DOI:10.1007/s12648-024-03095-6