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Autores principales: Grauer, Hannah, Lupu, Elena-Sorina, Lee, Connor, Chung, Soon-Jo, Rowen, Darren, Bycroft, Benjamen, Leeds, Phaedrus, Brader, John
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2408.12084
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author Grauer, Hannah
Lupu, Elena-Sorina
Lee, Connor
Chung, Soon-Jo
Rowen, Darren
Bycroft, Benjamen
Leeds, Phaedrus
Brader, John
author_facet Grauer, Hannah
Lupu, Elena-Sorina
Lee, Connor
Chung, Soon-Jo
Rowen, Darren
Bycroft, Benjamen
Leeds, Phaedrus
Brader, John
contents Space debris and inactive satellites pose a threat to the safety and integrity of operational spacecraft and motivate the need for space situational awareness techniques. These uncooperative targets create a challenging tracking and detection problem due to a lack of prior knowledge of their features, trajectories, or even existence. Recent advancements in computer vision models can be used to improve upon existing methods for tracking such uncooperative targets to make them more robust and reliable to the wide-ranging nature of the target. This paper introduces an autonomous detection model designed to identify and monitor these objects using learning and computer vision. The autonomous detection method aims to identify and accurately track the uncooperative targets in varied circumstances, including different camera spectral sensitivities, lighting, and backgrounds. Our method adapts to the relative distance between the observing spacecraft and the target, and different detection strategies are adjusted based on distance. At larger distances, we utilize You Only Look Once (YOLOv8), a multitask Convolutional Neural Network (CNN), for zero-shot and domain-specific single-shot real time detection of the target. At shorter distances, we use knowledge distillation to combine visual foundation models with a lightweight fast segmentation CNN (Fast-SCNN) to segment the spacecraft components with low storage requirements and fast inference times, and to enable weight updates from earth and possible onboard training. Lastly, we test our method on a custom dataset simulating the unique conditions encountered in space, as well as a publicly-available dataset.
format Preprint
id arxiv_https___arxiv_org_abs_2408_12084
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Vision-Based Detection of Uncooperative Targets and Components on Small Satellites
Grauer, Hannah
Lupu, Elena-Sorina
Lee, Connor
Chung, Soon-Jo
Rowen, Darren
Bycroft, Benjamen
Leeds, Phaedrus
Brader, John
Computer Vision and Pattern Recognition
Space debris and inactive satellites pose a threat to the safety and integrity of operational spacecraft and motivate the need for space situational awareness techniques. These uncooperative targets create a challenging tracking and detection problem due to a lack of prior knowledge of their features, trajectories, or even existence. Recent advancements in computer vision models can be used to improve upon existing methods for tracking such uncooperative targets to make them more robust and reliable to the wide-ranging nature of the target. This paper introduces an autonomous detection model designed to identify and monitor these objects using learning and computer vision. The autonomous detection method aims to identify and accurately track the uncooperative targets in varied circumstances, including different camera spectral sensitivities, lighting, and backgrounds. Our method adapts to the relative distance between the observing spacecraft and the target, and different detection strategies are adjusted based on distance. At larger distances, we utilize You Only Look Once (YOLOv8), a multitask Convolutional Neural Network (CNN), for zero-shot and domain-specific single-shot real time detection of the target. At shorter distances, we use knowledge distillation to combine visual foundation models with a lightweight fast segmentation CNN (Fast-SCNN) to segment the spacecraft components with low storage requirements and fast inference times, and to enable weight updates from earth and possible onboard training. Lastly, we test our method on a custom dataset simulating the unique conditions encountered in space, as well as a publicly-available dataset.
title Vision-Based Detection of Uncooperative Targets and Components on Small Satellites
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2408.12084