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Authors
Advisor(s)
Abstract(s)
We study equilibria of a multibody system in the orbit plane within the framework of a model of n + 1 material
points connected by n light rods into an n-link chain. The junctions are spherical hinges. The center of mass of the system moves along a circular orbit. The equilibrium equations are reduced to a fairly simple form that enables their analysis.We find all the equilibria of an n-link chain in the orbit plane and prove that each rod can occupy one of the following three positions: it can be directed along the tangent to the orbit of the center of mass of the chain; it can be a member of a group of adjacent vertical rods, being the center of mass of this group situated on the tangent to the orbit; and, finally, an oblique orientation is possible if the rod joins either two vertical groups of rods or the end of a vertical group with the tangent to the orbit. It is shown that the number of equilibria does not exceed 2^(2n). We include the analysis of two examples (three- and four-link chains) and represent the schemes of all the realizable equilibria in these cases.
Description
Keywords
Multisatellite chain Formation flying Orbital dynamics
Citation
A. D. Guerman. Equilibria of multibody chain in orbit plane. Journal of Guidance, Control and Dynamics, v. 26, No. 6, 2003, 942-948
Publisher
AIAA