Optimal Low-Thrust Orbit Transfers Made Easy: A Direct Approach

TL;DR

This paper introduces a flexible, efficient direct method for optimizing low-thrust orbit transfers, effectively balancing fuel and time objectives without needing prior solution structure knowledge.

Contribution

It presents a novel dynamic model and Lyapunov-based initial guess scheme, enabling easier and faster solutions for complex low-thrust transfer problems.

Findings

Successfully solves minimum-time, minimum-fuel, and mixed objectives

Reduces computational demand compared to existing methods

Applicable to benchmark orbit transfer scenarios

Abstract

The optimization of low-thrust, multi-revolution orbit transfer trajectories is often regarded as a difficult problem in modern astrodynamics. In this paper, a flexible and computationally efficient approach is presented for the optimization of low-thrust orbit transfers under eclipse constraints. The proposed approach leverages a new dynamic model of the orbital motion and a Lyapunov-based initial guess generation scheme that is very easy to tune. A multi-objective, single-phase formulation of the optimal control problem is devised, which provides a convenient way to trade off fuel consumption and time of flight. A distinctive feature of such a formulation is that it requires no prior information about the structure of the optimal solution. Simulation results for two benchmark orbit transfer scenarios indicate that minimum-time, minimum-fuel and mixed time/fuel-optimal instances of the control problem can be readily solved via direct collocation, while incurring a significantly lower computational demand with respect to existing techniques.