With the growing number of lunar missions operating in environments with highly nonlinear dynamics, the optimization of space flight trajectories and operations under uncertainty has become a priority. This is especially valid for station-keeping on unstable libration-point orbits. This work presents an innovative stochastic optimization method for the target point approach. The method includes uncertainty propagation through differential-algebra-based Monte Carlo analyses directly into the optimization process. Applied to the quasi-halo orbit of the LUMIO CubeSat mission, the method is compared to traditional maneuver-based optimizations of the target point approach, demonstrating significantly improved fuel efficiency.
Stochastic Optimization for Target Point Approach on Quasi-Halo Orbits
Martinelli, A.;Giordano, C.;Topputo, F.
2026-01-01
Abstract
With the growing number of lunar missions operating in environments with highly nonlinear dynamics, the optimization of space flight trajectories and operations under uncertainty has become a priority. This is especially valid for station-keeping on unstable libration-point orbits. This work presents an innovative stochastic optimization method for the target point approach. The method includes uncertainty propagation through differential-algebra-based Monte Carlo analyses directly into the optimization process. Applied to the quasi-halo orbit of the LUMIO CubeSat mission, the method is compared to traditional maneuver-based optimizations of the target point approach, demonstrating significantly improved fuel efficiency.| File | Dimensione | Formato | |
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