In this paper we present, a comparison of trajectory optimization approaches for the minimum fuel rendezvous problem. Both indirect and direct methods are compared for a variety of test cases. The indirect approach is based on primer vector theory. The direct approaches are implemented numerically and include Sequential Quadratic Programming (SQP). Quasi- Newton and Nelder-Meade Simplex. Several cost function parameterizations are considered for the direct approach. We choose one direct approach that appears to be the most flexible. Both the direct and indirect methods are applied to a variety of test cases which are chosen to demonstrate the performance of each method in different flight regimes. The first test case is a simple circular-to...
Abstract: The four–impulse rendezvous of two spacecrafts moving initially on close near–ci...
Abstract: The work describes algorithms for minimization in the spaces of impulse componen...
In this thesis, two fundamental steps of the orbital rendezvous are studied: the relative navigation...
International audienceThe optimal fuel impulsive time-fixed rendezvous problem is reviewed. In a lin...
A method has been developed for determining optimal, i.e. minimum fuel, trajectories for the fixed-t...
The minimum-time, low-constant-thrust, same circular orbit rendezvous problem is studied using a rel...
The three-dimensional rendezvous between two spacecraft is considered: a target spacecraft on a circ...
International audienceThis paper focuses on the fixed-time minimum-fuel rendezvous between close ell...
In recent years, there has been a growing demand for the autonomous rendezvous and docking capabilit...
In this paper a new approach to constrained low-thrust trajectory optimization for rendezvous on ell...
One of the objectives of mission design is selecting an optimum orbital transfer which often transla...
This paper investigates methods for optimizing an impulsive multi-rendezvous trajectory aimed at per...
The spacecraft trajectory design process frequently includes the optimization of a quantity of impor...
International audienceThis paper focuses on the fixed-time minimum-fuel out-of-plane rendezvous betw...
International audienceThis paper focuses on the fixed-time minimum-fuel out-of-plane rendezvous betw...
Abstract: The four–impulse rendezvous of two spacecrafts moving initially on close near–ci...
Abstract: The work describes algorithms for minimization in the spaces of impulse componen...
In this thesis, two fundamental steps of the orbital rendezvous are studied: the relative navigation...
International audienceThe optimal fuel impulsive time-fixed rendezvous problem is reviewed. In a lin...
A method has been developed for determining optimal, i.e. minimum fuel, trajectories for the fixed-t...
The minimum-time, low-constant-thrust, same circular orbit rendezvous problem is studied using a rel...
The three-dimensional rendezvous between two spacecraft is considered: a target spacecraft on a circ...
International audienceThis paper focuses on the fixed-time minimum-fuel rendezvous between close ell...
In recent years, there has been a growing demand for the autonomous rendezvous and docking capabilit...
In this paper a new approach to constrained low-thrust trajectory optimization for rendezvous on ell...
One of the objectives of mission design is selecting an optimum orbital transfer which often transla...
This paper investigates methods for optimizing an impulsive multi-rendezvous trajectory aimed at per...
The spacecraft trajectory design process frequently includes the optimization of a quantity of impor...
International audienceThis paper focuses on the fixed-time minimum-fuel out-of-plane rendezvous betw...
International audienceThis paper focuses on the fixed-time minimum-fuel out-of-plane rendezvous betw...
Abstract: The four–impulse rendezvous of two spacecrafts moving initially on close near–ci...
Abstract: The work describes algorithms for minimization in the spaces of impulse componen...
In this thesis, two fundamental steps of the orbital rendezvous are studied: the relative navigation...