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Main Authors: Hobbs, Kerianne L., Phillips, Sean, Simon, Michelle, Lyons, Joseph B., Culbertson, Jared, Clouse, Hamilton Scott, Hamilton, Nathaniel, Dunlap, Kyle, Lippay, Zachary S., Aurand, Joshua, Bell, Zachary I., Hammack, Taleri, Ayres, Dorothy, Lim, Rizza
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.05984
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author Hobbs, Kerianne L.
Phillips, Sean
Simon, Michelle
Lyons, Joseph B.
Culbertson, Jared
Clouse, Hamilton Scott
Hamilton, Nathaniel
Dunlap, Kyle
Lippay, Zachary S.
Aurand, Joshua
Bell, Zachary I.
Hammack, Taleri
Ayres, Dorothy
Lim, Rizza
author_facet Hobbs, Kerianne L.
Phillips, Sean
Simon, Michelle
Lyons, Joseph B.
Culbertson, Jared
Clouse, Hamilton Scott
Hamilton, Nathaniel
Dunlap, Kyle
Lippay, Zachary S.
Aurand, Joshua
Bell, Zachary I.
Hammack, Taleri
Ayres, Dorothy
Lim, Rizza
contents The Safe Trusted Autonomy for Responsible Space (STARS) program aims to advance autonomy technologies for space by leveraging machine learning technologies while mitigating barriers to trust, such as uncertainty, opaqueness, brittleness, and inflexibility. This paper presents the achievements and lessons learned from the STARS program in integrating reinforcement learning-based multi-satellite control, run time assurance approaches, and flexible human-autonomy teaming interfaces, into a new integrated testing environment for collaborative autonomous satellite systems. The primary results describe analysis of the reinforcement learning multi-satellite control and run time assurance algorithms. These algorithms are integrated into a prototype human-autonomy interface using best practices from human-autonomy trust literature, however detailed analysis of the effectiveness is left to future work. References are provided with additional detailed results of individual experiments.
format Preprint
id arxiv_https___arxiv_org_abs_2501_05984
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The Safe Trusted Autonomy for Responsible Space Program
Hobbs, Kerianne L.
Phillips, Sean
Simon, Michelle
Lyons, Joseph B.
Culbertson, Jared
Clouse, Hamilton Scott
Hamilton, Nathaniel
Dunlap, Kyle
Lippay, Zachary S.
Aurand, Joshua
Bell, Zachary I.
Hammack, Taleri
Ayres, Dorothy
Lim, Rizza
Systems and Control
The Safe Trusted Autonomy for Responsible Space (STARS) program aims to advance autonomy technologies for space by leveraging machine learning technologies while mitigating barriers to trust, such as uncertainty, opaqueness, brittleness, and inflexibility. This paper presents the achievements and lessons learned from the STARS program in integrating reinforcement learning-based multi-satellite control, run time assurance approaches, and flexible human-autonomy teaming interfaces, into a new integrated testing environment for collaborative autonomous satellite systems. The primary results describe analysis of the reinforcement learning multi-satellite control and run time assurance algorithms. These algorithms are integrated into a prototype human-autonomy interface using best practices from human-autonomy trust literature, however detailed analysis of the effectiveness is left to future work. References are provided with additional detailed results of individual experiments.
title The Safe Trusted Autonomy for Responsible Space Program
topic Systems and Control
url https://arxiv.org/abs/2501.05984