Study on the dynamics, relative equilibria, and stability for liquid-filled spacecraft with flexible appendage
DOI10.1007/s00707-022-03269-5zbMath1506.70009OpenAlexW4289638048MaRDI QIDQ2083772
Publication date: 11 October 2022
Published in: Acta Mechanica (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1007/s00707-022-03269-5
block diagonalizationenergy-momentum methodprinciple of symmetric criticalitystability conditiongeometrically exact rodLagrangian geometric mechanicslarge-amplitude lateral sloshing
Jets and cavities, cavitation, free-streamline theory, water-entry problems, airfoil and hydrofoil theory, sloshing (76B10) Stability problems in rigid body dynamics (70E50) Lagrange's equations (70H03)
Cites Work
- Unnamed Item
- Unnamed Item
- Unnamed Item
- Heteroclinic bifurcations in attitude maneuver of coupled slosh-spacecraft with flexible appendage
- Hamiltonian structures and stability for rigid bodies with flexible attachments
- Study on the global chaotic dynamics and control of liquid-filled spacecraft with flexible appendage
- Lagrangian block diagonalization
- Reduction of symplectic manifolds with symmetry
- Gyroscopic control and stabilization
- Optimal control of attitude for coupled-rigid-body spacecraft via Chebyshev-Gauss pseudospectral method
- Nonholonomic mechanics and control. With the collaboration of J. Baillieul, P. Crouch, and J. Marsden. With scientific input from P. S. Krishnaprasad, R. M. Murray, and D. Zenkov.
- Stability of relative equilibria. I: The reduced energy-momentum method
- Stability of relative equilibria. II: Application to nonlinear elasticity
- Almost complete and equable heteroclinic networks
- Analytical method for the attitude stability of partially liquid filled spacecraft with flexible appendage
- Nonlinear stability of fluid and plasma equilibria
- Lie-Poisson structures, dual-spin spacecraft and asymptotic stability
- The dynamics of coupled planar rigid bodies. Part I: reduction, equilibria and stability
- A variational principle for fluid sloshing with vorticity, dynamically coupled to vessel motion
- Liquid Sloshing Dynamics
- Geometric Mechanics
This page was built for publication: Study on the dynamics, relative equilibria, and stability for liquid-filled spacecraft with flexible appendage
