Time-Varying Shadows of Quasi-Periodic Motion Across Sections of the Flow Within Nearly Time-Periodic Three-Body Dynamics

Quasi-periodic behavior underlying gravitational three-body dynamics may supply naturally bounded reference trajectories to control spacecraft motion. To insert or maintain a spacecraft into bounded motion that resembles quasi-periodic behavior, guidance algorithms may require target position and ve...

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Bibliographic Details
Published in:The Journal of the astronautical sciences 2021-12, Vol.68 (4), p.855-890
Main Authors: Guzzetti, Davide, Baoyin, Hexi
Format: Article
Language:English
Subjects:
Accuracy
Aerospace Technology and Astronautics
Algorithms
Dynamic structural analysis
Dynamics
Earth-Moon system
Engineering
Indicators
Inspection
Mathematical Applications in the Physical Sciences
Motion stability
Original Article
Perturbation
Poincare maps
Position indicators
Shadows
Space Exploration and Astronautics
Space Sciences (including Extraterrestrial Physics
Spacecraft guidance
Spacecraft motion
Target recognition
Toruses
Trajectory control
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Description
Summary:Quasi-periodic behavior underlying gravitational three-body dynamics may supply naturally bounded reference trajectories to control spacecraft motion. To insert or maintain a spacecraft into bounded motion that resembles quasi-periodic behavior, guidance algorithms may require target position and velocity values, potentially at a fixed epoch. Within lower fidelity models that are autonomous, Poincaré maps are a particularly effective tool to identify target conditions for nearly quasi-periodic motion; however, challenges remain in transitioning the application of Poincaré maps to higher fidelity models that are nearly time-periodic. In fact, Poincaré maps are often visualized in lower dimensional spaces for inspection; such visualizations do not often supply a static and comprehensive description for the underlying dynamical structures, when dynamics are nearly time-periodic. In this work, we explore a framework to facilitate the interpretation of Poincaré map patterns associated with epoch-dependent solutions and states that are projected to lower dimensional position and velocity spaces. The introduction of chaos indicators may reveal regions of the projection that produce bounded motion as a function of the given epoch and/or initial state perturbation. Within precisely time-periodic systems, these regions may be the image, or shadow, of underlying torus manifolds. In the Poisson sense, shadows of quasi-periodic motion may be considered regions of stability within the lower dimensional space. Within the projection space, chaos indicators may capture time variations of a reference shadow or reveal special perturbation patterns. The framework is presented in two case studies: the first study demonstrates application within binary asteroid dynamics that are precisely time-periodic; the second study demonstrates application within nearly time-periodic dynamics (i.e., an ephemeris representation of the Earth-Moon system), when solutions resemble quasi-periodic motion only over finite time intervals.
ISSN:0021-9142
2195-0571
DOI:10.1007/s40295-021-00284-x