Computational method for phase space transport with applications to lobe dynamics and rate of escape

Naik, Shibabrat; Lekien, François; Ross, Shane D.

doi:10.1134/s1560354717030078

Cited by 6 publications

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“…The restricted three-body problem is a classic problem which has attracted a lot of attention for the study of escape [4][5][6][50][51][52][53][54][55][56][57][58][59][60][61][62][63]. Deeper understanding of the escape from a gravitational potential well due to multiple bodies can guide the design of trajectories for interplanetary space missions and also aid analysis of certain astronomical phenomena (e.g., galactic dynamics [64][65][66][67][68][69][70]).…”

Section: The Restricted Three-body Problem With Dissipationmentioning

confidence: 99%

Geometry of escape and transition dynamics in the presence of dissipative and gyroscopic forces in two degree of freedom systems

Zhong

Ross

2020

Communications in Nonlinear Science and Numerical Simulation

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Escape from a potential well can occur in different physical systems, such as capsize of ships, resonance transitions in celestial mechanics, and dynamic snap-through of arches and shells, as well as molecular reconfigurations in chemical reactions. The criteria and routes of escape in one-degree of freedom systems has been well studied theoretically with reasonable agreement with experiment. The trajectory can only transit from the hilltop of the one-dimensional potential energy surface. The situation becomes more complicated when the system has higher degrees of freedom since it has multiple routes to escape through an equilibrium of saddle-type, specifically, an index-1 saddle. This paper summarizes the geometry of escape across a saddle in some widely known physical systems with two degrees of freedom and establishes the criteria of escape providing both a methodology and results under the conceptual framework known as tube dynamics. These problems are classified into two categories based on whether the saddle projection and focus projection in the symplectic eigenspace are coupled or not when damping and/or gyroscopic effects are considered. For simplicity, only the linearized system around the saddle points is analyzed, but the results generalize to the nonlinear system. We define a transition region, T h , as the region of initial conditions of a given initial energy h which transit from one side of a saddle to the other. We find that in conservative systems, the boundary of the transition region, ∂T h , is a cylinder, while in dissipative systems, ∂T h is an ellipsoid.

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