A Tutorial on Horizon-Based Optical Navigation and Attitude Determination With Space Imaging Systems

A Tutorial on Horizon-Based Optical Navigation and Attitude Determination With Space Imaging Systems

Images of a nearby celestial body collected by a camera on an exploration spacecraft contain a wealth of actionable information. This work considers how the apparent location of the observed body's horizon in a digital image may be used to infer the relative position, attitude, or both. When th...

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Bibliographic Details
Published in:IEEE access Vol. 9; pp. 19819 - 19853
Main Author: Christian, John A.
Format: Journal Article
Language:English
Published: Piscataway IEEE 2021
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Adaptive optics
Algebraic geometry
Algorithms
Approximation
attitude determination
Cameras
computer vision
Digital imaging
Earth horizon sensors
Horizon
Hyperbolas
Iterative methods
Lenses
Navigation
Navigators
Optical imaging
optical navigation (OPNAV)
quadrics
space exploration
Space vehicles
Spacecraft
spacecraft navigation
Tutorials
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Description
Summary:Images of a nearby celestial body collected by a camera on an exploration spacecraft contain a wealth of actionable information. This work considers how the apparent location of the observed body's horizon in a digital image may be used to infer the relative position, attitude, or both. When the celestial body is a sphere, spheroid, or ellipsoid (as is the case for most large bodies in the Solar System), the projected horizon in an image is a conic-usually an ellipse at large distances and a hyperbola at small distances. This work develops non-iterative and analytically exact methods for every case (all combinations of unknown state parameters and quadric shapes), completely superseding older horizon-based methods that are iterative, approximate, or both. Some of the analytic methods presented in this work are new. Recognizing that these developments build on techniques that may be unfamiliar to many spacecraft navigators, this work is fashioned as a tutorial. Descriptive illustrations and numerical examples are provided to make concepts clear and to validate the proposed algorithms.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2021.3051914