Saved in:
Bibliographic Details
Main Authors: Albee, Keenan, Sternberg, David C., Hansson, Alexander, Schwartz, David, Majumdar, Ritwik, Jia-Richards, Oliver
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.14524
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866915864816648192
author Albee, Keenan
Sternberg, David C.
Hansson, Alexander
Schwartz, David
Majumdar, Ritwik
Jia-Richards, Oliver
author_facet Albee, Keenan
Sternberg, David C.
Hansson, Alexander
Schwartz, David
Majumdar, Ritwik
Jia-Richards, Oliver
contents Small free-flying spacecraft can provide vital extravehicular activity (EVA) services like inspection and repair for future orbital outposts like the Lunar Gateway. Operating adjacent to delicate space station and microgravity targets, these spacecraft require formalization to describe the autonomy that a free-flyer inspection mission must provide. This work explores the transformation of general mission requirements for this class of free-flyer into a set of concrete decisions for the planning and control autonomy architectures that will power such missions. Flowing down from operator commands for inspection of important regions and mission time-criticality, a motion planning problem emerges that provides the basis for developing autonomy solutions. Unique constraints are considered such as velocity limitations, pointing, and keep-in/keep-out zones, with mission fallback techniques for providing hierarchical safety guarantees under model uncertainties and failure. Planning considerations such as cost function design and path vs. trajectory control are discussed. The typical inputs and outputs of the planning and control autonomy stack of such a mission are also provided. Notional system requirements such as solve times and propellant use are documented to inform planning and control design. The entire proposed autonomy framework for free-flyer inspection is realized in the SmallSatSim simulation environment, providing a reference example of free-flyer inspection autonomy. The proposed autonomy architecture serves as a blueprint for future implementations of small satellite autonomous inspection in proximity to mission-critical hardware, going beyond the existing literature in terms of both (1) providing realistic system requirements for an autonomous inspection mission and (2) translating these requirements into autonomy design decisions for inspection planning and control.
format Preprint
id arxiv_https___arxiv_org_abs_2603_14524
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Architecting Autonomy for Safe Microgravity Free-Flyer Inspection
Albee, Keenan
Sternberg, David C.
Hansson, Alexander
Schwartz, David
Majumdar, Ritwik
Jia-Richards, Oliver
Robotics
Small free-flying spacecraft can provide vital extravehicular activity (EVA) services like inspection and repair for future orbital outposts like the Lunar Gateway. Operating adjacent to delicate space station and microgravity targets, these spacecraft require formalization to describe the autonomy that a free-flyer inspection mission must provide. This work explores the transformation of general mission requirements for this class of free-flyer into a set of concrete decisions for the planning and control autonomy architectures that will power such missions. Flowing down from operator commands for inspection of important regions and mission time-criticality, a motion planning problem emerges that provides the basis for developing autonomy solutions. Unique constraints are considered such as velocity limitations, pointing, and keep-in/keep-out zones, with mission fallback techniques for providing hierarchical safety guarantees under model uncertainties and failure. Planning considerations such as cost function design and path vs. trajectory control are discussed. The typical inputs and outputs of the planning and control autonomy stack of such a mission are also provided. Notional system requirements such as solve times and propellant use are documented to inform planning and control design. The entire proposed autonomy framework for free-flyer inspection is realized in the SmallSatSim simulation environment, providing a reference example of free-flyer inspection autonomy. The proposed autonomy architecture serves as a blueprint for future implementations of small satellite autonomous inspection in proximity to mission-critical hardware, going beyond the existing literature in terms of both (1) providing realistic system requirements for an autonomous inspection mission and (2) translating these requirements into autonomy design decisions for inspection planning and control.
title Architecting Autonomy for Safe Microgravity Free-Flyer Inspection
topic Robotics
url https://arxiv.org/abs/2603.14524