Formulation and Analysis for Integrated Spacecraft Routing and Trajectory Design Problem
Abstract
This paper studies the integrated spacecraft routing and trajectory optimization problem for satellite servicing missions involving partial en-route propellant replenishment. Unlike terrestrial routing problems, spacecraft operate in a dynamic environment, and we need to optimize the spacecraft routing over a network with nonlinear and time-dependent trajectory costs. In this paper, we tackle this problem using two different formulations. The first formulation, referred to as the arc-based formulation, defines variables based on arcs and employs an iterative decoupling scheme that alternates between mixed-integer linear programming and sequential nonlinear trajectory optimization. The second formulation, referred to as the path-based formulation, defines variables based on paths/routes and leverages column generation and a labeling algorithm to accelerate the identification of promising routes. Through a geosynchronous satellite servicing case study and numerical experiments, we quantify the computational trade-offs between these two formulations in terms of the solution optimality, computational time, and robustness against non-converging or trivial solutions.
Cite
@article{arxiv.2604.18826,
title = {Formulation and Analysis for Integrated Spacecraft Routing and Trajectory Design Problem},
author = {Euihyeon Choi and Koki Ho},
journal= {arXiv preprint arXiv:2604.18826},
year = {2026}
}
Comments
30 pages