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Analytical and numerical study of chaos in spatial attitude dynamics of a satellite in an elliptic orbit
Chegini, M ; Sharif University of Technology | 2018
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- Type of Document: Article
- DOI: 10.1177/0954406218762019
- Publisher: SAGE Publications Ltd , 2018
- Abstract:
- In this paper, chaos in spatial attitude dynamics of a triaxial rigid satellite in an elliptic orbit is investigated analytically and numerically. The goal in the analytical part is to prove the existence of chaos and then to find a relation for the width of chaotic layers (i.e. the initial values needed to have a chaotic attitude motion) based on the parameters of the system. The numerical part is aimed at validating the analytical method using the Poincaré maps and the maximum value of the Lyapunov exponents. The rotational–translational Hamiltonian of the system is first derived. This Hamiltonian has six degrees of freedom. Choosing a proper set of coordinates and given the fact that the total angular momentum is constant, the Hamiltonian is then reduced to a four-degree-of-freedom system. Assuming the effect of attitude on the orbital dynamics to be negligible, and assuming a nearly symmetric and fast-spinning satellite, the system is approximated by a second-order differential equation with a time quasi-periodic perturbation. Next, the Melnikov–Wiggins’s method is used to prove the existence of a chaotic behavior followed by the determination of an analytical relation for the width of chaotic layers. Although in the analytical method some restrictive assumptions are enforced, the results show that the analytical relation gives a good estimate for the width of chaotic layers even if these assumptions are not entirely satisfied. The results also show that this method is useful for finding the effects of all the parameters (the orbit and the satellite) and the initial values on the existence of a regular behavior. © 2018, IMechE 2018
- Keywords:
- Lyapunov exponents ; Melnikov–Wiggins method ; Poincare Map ; Spatial attitude dynamics ; Triaxial rigid satellite ; Width of chaotic layers ; Degrees of freedom (mechanics) ; Differential equations ; Dynamics ; Lyapunov functions ; Lyapunov methods ; Numerical methods ; Orbits ; Satellites ; Attitude dynamics ; Chaotic layer ; Elliptic orbit ; Four degree of freedom ; Lyapunov exponent ; Quasi-periodic perturbation ; Second-order differential equation ; Six degrees of freedom ; Hamiltonians
- Source: Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science ; 2018 ; 09544062 (ISSN)
- URL: https://journals.sagepub.com/doi/10.1177/0954406218762019