Star-Identification System Based on Polygon Recognition

IF 0.1 4区 工程技术 Q4 ENGINEERING, AEROSPACE Aerospace America Pub Date : 2023-08-24 DOI:10.3390/aerospace10090748
Gustavo E. Ramos-Alcaraz, Miguel A. Alonso-Arévalo, J. M. Nuñez-Alfonso
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Abstract

Accurate attitude determination is crucial for satellites and spacecraft. Among attitude determination devices, star sensors are the most accurate. Solving the lost-in-space problem is the most critical function of the star sensor. Our research introduces a novel star-identification system that utilizes a polygon-recognition algorithm to assign a unique complex number to polygons created by stars. This system aims to solve the lost-in-space problem. Our system includes a full solution with a lens, image sensor, processing unit, and algorithm implementation. To test the system’s performance, we analyzed 100 night sky images that resembled what a real star sensor in orbit would experience. We used a k-d tree algorithm to accelerate the search in the star catalog of complex numbers. We implemented various verification methods, including internal polygon verification and a voting mechanism, to ensure the system’s reliability. We obtained the star database used as a reference from the Gaia DR2 catalog, which we filtered, to eliminate irrelevant stars, and which we arranged by apparent magnitude. Despite manually introducing up to three false stars, the system successfully identified at least one star in 97% of the analyzed images.
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基于多边形识别的恒星识别系统
准确的姿态确定对卫星和航天器至关重要。在姿态确定装置中,星敏感器精度最高。解决空间丢失问题是星敏感器最关键的功能。我们的研究介绍了一种新的恒星识别系统,该系统利用多边形识别算法为恒星产生的多边形分配唯一的复数。该系统旨在解决空间丢失问题。我们的系统包括一个完整的解决方案,包括镜头、图像传感器、处理单元和算法实现。为了测试该系统的性能,我们分析了100张夜空图像,这些图像与轨道上真正的恒星传感器所经历的图像相似。我们使用k-d树算法来加速在复数星表中的搜索。我们实现了多种验证方法,包括内部多边形验证和投票机制,以确保系统的可靠性。我们从盖亚DR2星表中获得了作为参考的恒星数据库,我们对其进行了过滤,以消除不相关的恒星,并按视星等排列。尽管人工引入了多达三颗假星,但该系统在97%的分析图像中成功识别了至少一颗星。
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来源期刊
Aerospace America
Aerospace America 工程技术-工程:宇航
自引率
0.00%
发文量
9
审稿时长
4-8 weeks
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