Rigid body equations of motion for modeling and control of spacecraft formations. Part 1: Absolute equations of motion

Rigid body equations of motion for modeling and control of spacecraft formations. Part 1: Absolute equations of motion

In this paper, we present a tensorial (i.e., coordinate-free) derivation of the equations of motion of a formation consisting of N spacecraft each modeled as a rigid body. Specifically, using spatial velocities and spatial forces we demonstrate that the equations of motion for a single free rigid bo...

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Bibliographic Details
Published in:2004 American Control Conference Proceedings; Volume 4 of 6 Vol. 4; pp. 3646 - 3653 vol.4
Main Authors: Ploen, S.R., Hadaegh, F.Y., Scharf, D.P.
Format: Conference Proceeding Journal Article
Language:English
Published: Piscataway NJ IEEE 01-01-2004
Evanston IL American Automatic Control Council
Subjects:
Application software
Applied sciences
Computer science; control theory; systems
Control system synthesis
Control theory. Systems
Exact sciences and technology
Laboratories
Motion control
NASA
Nonlinear equations
Propulsion
Space missions
Space technology
Space vehicles
Tensile stress
Rigid bodies
Equation of motion
Control program
Spacecraft
Non linear control
Tracking task
Modeling
Symmetry group
Fix point
Fixed point theorem
Center of mass
Coriolis acceleration
Dynamic model
Formation
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Summary:In this paper, we present a tensorial (i.e., coordinate-free) derivation of the equations of motion of a formation consisting of N spacecraft each modeled as a rigid body. Specifically, using spatial velocities and spatial forces we demonstrate that the equations of motion for a single free rigid body (i.e., a single spacecraft) can be naturally expressed in four fundamental forms. The four forms of the dynamic equations include (1) motion about the system center-of-mass in terms of absolute rates-of-change, (2) motion about the system center-of-mass in terms of body rates of change, (3) motion about an arbitrary point fixed on the rigid body in terms of absolute rates-of-change, and (4) motion about an arbitrary point fixed on the rigid body in terms of body rates-of-change. We then introduce the spatial Coriolis dyadic and discuss how a proper choice of this non-unique tensor leads to dynamic models of formations satisfying the skew-symmetry property required by an important class of nonlinear tracking control laws. Next, we demonstrate that the equations of motion of the entire formation have the same structure as the equations of motion of an individual spacecraft. The results presented in this paper form the cornerstone of a coordinate-free modeling environment for developing dynamic models for various formation flying applications.
Bibliography:SourceType-Scholarly Journals-2
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ISBN:9780780383357
0780383354
ISSN:0743-1619
2378-5861
DOI:10.23919/ACC.2004.1384478