We implement a fully factorization-free algorithm for nonconvex, free-final-time trajectory optimization. This algorithm is based on sequential convex programming and utilizes an inverse-free, exact discretization procedure to ensure dynamic feasibility of the converged trajectory and PIPG, a fast, first-order conic optimization algorithm as the subproblem solver. Although PIPG requires the tuning of a hyperparameter to achieve fastest convergence, we show that PIPG can be tuned to a nominal trajectory optimization problem and it is robust to variations in initial condition. We demonstrate this with a monte carlo simulation of the free-final-time rendezvous problem, using Clohessy-Wiltshire dynamics, an impulsive thrust model, and various state and control constraints including a spherical keepout zone.
@article{arxiv.2402.04561,
title = {Spacecraft Rendezvous Guidance via Factorization-Free Sequential Convex Programming using a First-Order Method},
author = {Govind M. Chari and Behçet Açıkmeşe},
journal= {arXiv preprint arXiv:2402.04561},
year = {2024}
}
Comments
AAS Rocky Mountain Guidance, Navigation and Control Conference, 2024