Long-term dynamic modeling of tethered spacecraft using nodal position finite element method and symplectic integration

Long-term dynamic modeling of tethered spacecraft using nodal position finite element method and symplectic integration

Dynamic modeling of tethered spacecraft with the consideration of elasticity of tether is prone to the numerical instability and error accumulation over long-term numerical integration. This paper addresses the challenges by proposing a globally stable numerical approach with the nodal position fini...

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Bibliographic Details
Published in:Celestial mechanics and dynamical astronomy Vol. 123; no. 4; pp. 363 - 386
Main Authors: Li, G. Q., Zhu, Z. H.
Format: Journal Article
Language:English
Published: Dordrecht Springer Netherlands 01-12-2015
Springer Nature B.V
Subjects:
Aerospace Technology and Astronautics
Astrophysics and Astroparticles
Classical Mechanics
Dynamical Systems and Ergodic Theory
Dynamics
Energy conservation
Finite element analysis
Finite element method
Geophysics/Geodesy
Mathematical analysis
Mathematical models
Numerical integration
Orbits
Original Article
Physics
Physics and Astronomy
Runge-Kutta method
Spacecraft
Tethers
Nodal position finite element method
Symplectic integration
Elastic tether
Tethered spacecraft
Dynamics
Satellite deorbit
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Summary:Dynamic modeling of tethered spacecraft with the consideration of elasticity of tether is prone to the numerical instability and error accumulation over long-term numerical integration. This paper addresses the challenges by proposing a globally stable numerical approach with the nodal position finite element method (NPFEM) and the implicit, symplectic, 2-stage and 4th order Gaussian–Legendre Runge–Kutta time integration. The NPFEM eliminates the numerical error accumulation by using the position instead of displacement of tether as the state variable, while the symplectic integration enforces the energy and momentum conservation of the discretized finite element model to ensure the global stability of numerical solution. The effectiveness and robustness of the proposed approach is assessed by an elastic pendulum problem, whose dynamic response resembles that of tethered spacecraft, in comparison with the commonly used time integrators such as the classical 4th order Runge–Kutta schemes and other families of non-symplectic Runge–Kutta schemes. Numerical results show that the proposed approach is accurate and the energy of the corresponding numerical model is conservative over the long-term numerical integration. Finally, the proposed approach is applied to the dynamic modeling of deorbiting process of tethered spacecraft over a long period.
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ISSN:0923-2958
1572-9478
DOI:10.1007/s10569-015-9640-5