Saved in:
Bibliographic Details
Main Authors: Zhang, Zhong, Acciarini, Giacomo, Izzo, Dario, Baoyin, Hexi, Topputo, Francesco
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.26790
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866911722588078080
author Zhang, Zhong
Acciarini, Giacomo
Izzo, Dario
Baoyin, Hexi
Topputo, Francesco
author_facet Zhang, Zhong
Acciarini, Giacomo
Izzo, Dario
Baoyin, Hexi
Topputo, Francesco
contents Low-thrust trajectory design relies heavily on repeated evaluations of fuel consumption and transfer feasibility, which require expensive optimal control solutions. In this work, we show these quantities can be accurately approximated by machine learning surrogates, enabling fast and scalable evaluation across a wide range of scenarios. By increasing both dataset size and model capacity, we observe that low-thrust trajectory optimization follows a scaling law, with performance improving linearly with the logarithm of training data and network parameters, and no evidence of saturation within the explored regime. Guided by this observation, we construct a large-scale dataset using the proposed homotopy-ray strategy tailored to mission design requirements. A key is the introduction of a self-similar transformation, which allows generalization across semi-major axes, inclinations, and central bodies avoiding retraining. As a result, the same neural approximator can be applied to diverse orbital environments and mission classes. The proposed models accurately predict optimal fuel consumption and minimum transfer time for single- and multi-revolution transfers. Their performance and generalization are demonstrated on a public dataset, a multi-asteroid flyby problem from the Global Trajectory Optimization Competition, and an asteroid rendezvous mission design. The models and datasets are released as open-source to support the space community.
format Preprint
id arxiv_https___arxiv_org_abs_2605_26790
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Pretrained Approximators for Low-Thrust Trajectory Cost and Reachability
Zhang, Zhong
Acciarini, Giacomo
Izzo, Dario
Baoyin, Hexi
Topputo, Francesco
Machine Learning
Space Physics
Low-thrust trajectory design relies heavily on repeated evaluations of fuel consumption and transfer feasibility, which require expensive optimal control solutions. In this work, we show these quantities can be accurately approximated by machine learning surrogates, enabling fast and scalable evaluation across a wide range of scenarios. By increasing both dataset size and model capacity, we observe that low-thrust trajectory optimization follows a scaling law, with performance improving linearly with the logarithm of training data and network parameters, and no evidence of saturation within the explored regime. Guided by this observation, we construct a large-scale dataset using the proposed homotopy-ray strategy tailored to mission design requirements. A key is the introduction of a self-similar transformation, which allows generalization across semi-major axes, inclinations, and central bodies avoiding retraining. As a result, the same neural approximator can be applied to diverse orbital environments and mission classes. The proposed models accurately predict optimal fuel consumption and minimum transfer time for single- and multi-revolution transfers. Their performance and generalization are demonstrated on a public dataset, a multi-asteroid flyby problem from the Global Trajectory Optimization Competition, and an asteroid rendezvous mission design. The models and datasets are released as open-source to support the space community.
title Pretrained Approximators for Low-Thrust Trajectory Cost and Reachability
topic Machine Learning
Space Physics
url https://arxiv.org/abs/2605.26790