A Million-Point Fast Trajectory Optimization Solver
Abstract
One might argue that solving a trajectory optimization problem over a million grid points is preposterous. How about solving such a problem at an incredibly fast computational time? On a small form-factor processor? Algorithmic details that make possible this trifecta of breakthroughs are presented in this paper. The computational mathematics that deliver these advancements are: (i) a Birkhoff-theoretic discretization of optimal control problems, (ii) matrix-free linear algebra leveraging Krylov-subspace methods, and (iii) a near-perfect Birkhoff preconditioner that helps achieve iteration speed with respect to the grid size,~. A key enabler of this high performance is the computation of Birkhoff matrix-vector products at time using fast Fourier transform techniques that eliminate traditional computational bottlenecks. A numerical demonstration of this unprecedented scale and speed is illustrated for a practical astrodynamics problem.
Cite
@article{arxiv.2509.01855,
title = {A Million-Point Fast Trajectory Optimization Solver},
author = {A. Javeed and D. P. Kouri and D. Ridzal and J. D. Steinman and I. M. Ross},
journal= {arXiv preprint arXiv:2509.01855},
year = {2025}
}
Comments
20 pages, 7 figures, AAS Paper 25-689