English

Towards Robust Spacecraft Trajectory Optimization via Transformers

Optimization and Control 2025-01-28 v2 Artificial Intelligence Robotics

Abstract

Future multi-spacecraft missions require robust autonomous trajectory optimization capabilities to ensure safe and efficient rendezvous operations. This capability hinges on solving non-convex optimal control problems in real-time, although traditional iterative methods such as sequential convex programming impose significant computational challenges. To mitigate this burden, the Autonomous Rendezvous Transformer (ART) introduced a generative model trained to provide near-optimal initial guesses. This approach provides convergence to better local optima (e.g., fuel optimality), improves feasibility rates, and results in faster convergence speed of optimization algorithms through warm-starting. This work extends the capabilities of ART to address robust chance-constrained optimal control problems. Specifically, ART is applied to challenging rendezvous scenarios in Low Earth Orbit (LEO), ensuring fault-tolerant behavior under uncertainty. Through extensive experimentation, the proposed warm-starting strategy is shown to consistently produce high-quality reference trajectories, achieving up to 30\% cost improvement and 50\% reduction in infeasible cases compared to conventional methods, demonstrating robust performance across multiple state representations. Additionally, a post hoc evaluation framework is proposed to assess the quality of generated trajectories and mitigate runtime failures, marking an initial step toward the reliable deployment of AI-driven solutions in safety-critical autonomous systems such as spacecraft.

Keywords

Cite

@article{arxiv.2410.05585,
  title  = {Towards Robust Spacecraft Trajectory Optimization via Transformers},
  author = {Yuji Takubo and Tommaso Guffanti and Daniele Gammelli and Marco Pavone and Simone D'Amico},
  journal= {arXiv preprint arXiv:2410.05585},
  year   = {2025}
}

Comments

Submitted to the IEEE Aerospace Conference 2025. 13 pages, 10 figures

R2 v1 2026-06-28T19:12:17.905Z