English

Autonomous Angles-Only Multi-Target Tracking for Spacecraft Swarms

Signal Processing 2021-10-04 v2 Image and Video Processing

Abstract

This paper presents a new algorithm for autonomous multitarget tracking of resident space objects using optical angles-only measurements from a spaceborne observer. To enable autonomous angles-only navigation of spacecraft swarms, an observer must be able to identify and track multiple known or unknown target space objects in view, without reliance on a-priori relative orbit knowledge. Extremely high assignment precision is necessary with low measurement frequencies and limited computational resources. The new "Spacecraft Angles-only MUltitarget tracking System" (SAMUS) algorithm has been developed to meet these objectives and constraints. It combines domain-specific modeling of target kinematics with multi-hypothesis techniques to autonomously track multiple unknown targets using only sequential camera images. A measurement transform ensures that target motion in the observer reference frame follows consistent parametric models; curve fitting is used to predict track behavior; and kinematically-derived track gating and scoring criteria are applied to improve the efficiency and accuracy of the multi-hypothesis approach. Monte-Carlo testing with high-fidelity simulations demonstrates close to 100% measurement assignment precision and strong recall across a range of multi-spacecraft formations, in both near-circular and eccentric orbits. Tracking is maintained in the presence of eclipse periods, significant measurement noise, and partially known swarm maneuvers. A comparison to other tracking algorithms reveals strong advantages in precision, robustness and computation time, crucial for spaceborne angles-only navigation.

Keywords

Cite

@article{arxiv.2002.08881,
  title  = {Autonomous Angles-Only Multi-Target Tracking for Spacecraft Swarms},
  author = {Justin Kruger and Simone D'Amico},
  journal= {arXiv preprint arXiv:2002.08881},
  year   = {2021}
}

Comments

19 pages, 15 figures, submitted to Acta Astronautica

R2 v1 2026-06-23T13:48:25.589Z