Low-Energy Round-Trip Trajectories to Near-Earth Objects using Low Thrust

TL;DR

This paper introduces a hybrid methodology combining CR3BP and 2BP models to efficiently generate low-energy round-trip trajectories to NEOs using low-thrust propulsion, enabling rapid mission design.

Contribution

It presents a modular, hybrid approach for systematic low-energy trajectory design to NEOs, improving over traditional methods by enabling large-scale exploration without heavy optimization.

Findings

Generated a large ensemble of low-energy round-trip trajectories

Achieved broad temporal flexibility and low propellant use

Compared favorably with existing 2BP solutions in energy and impulses

Abstract

Near-Earth Objects (NEOs) are attractive exploration targets due to their accessibility, scientific value, and resources. Although trajectory design has revealed efficient pathways to these bodies, systematic strategies for Earth-NEO transfers, especially with low thrust, remain limited. This work presents a streamlined methodology that blends the Sun-Earth circular restricted three-body problem (CR3BP) with the heliocentric two-body problem (2BP) to design low-energy round-trip trajectories. The current planar implementation enables efficient large-scale exploration of near-Earth space. Three-body manifold trajectories and transit orbits provide natural pathways for Earth departure and return through the L1 and L2 libration points, while the 2BP framework identifies spacecraft-NEO encounters through intersections of their elliptical orbits. This hybrid structure supports generating large collections of round-trip trajectories without heavy optimization, enabling rapid preliminary mission design across broad NEO populations. Rendezvous and takeoff maneuvers are first modeled as impulsive, then translated into low-thrust arcs to improve propellant efficiency. Round-trip transfers are assembled by combining compatible outbound and inbound branches under simple mission constraints. This modular approach is well suited for complex mission architectures that conventional patched-conics methods cannot systematically uncover. Applied to a representative NEO population, the method yields a large ensemble of round-trip trajectories with low launch and return energies, broad temporal flexibility, and competitive rendezvous and departure impulses compared to existing 2BP solutions.