Sunlight reflected off of resident space objects can be used as an optical signal for astrometric orbit determination and for deducing geometric information about the object. With the increasing population of small satellites and debris in low Earth orbit, photometry is a powerful tool in operational support of space missions, whether for anomaly resolution or object identification. To accurately determine size, shape, spin rate, status of deployables, or attitude information of an unresolved resident space object, multi-hertz sample rate photometry is required to capture the relatively rapid changes in brightness that these objects can exhibit. OSCOM, which stands for Optical tracking and Spectral characterization of CubeSats for Operational Missions, is a low cost and portable telescope system capable of time-resolved small satellite photometry, and is field deployable on short notice for simultaneous observation from multiple sites. We present the electro-optical design principles behind OSCOM and light curves of the 1.5 U DICE-2 CubeSat and simultaneous observations of the main body of the ASTRO-H satellite after its fragmentation event.
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机译:从常驻空间物体反射回来的阳光可用作光信号,用于确定天体轨道和推导有关物体的几何信息。随着低地球轨道上小型卫星和碎片的增加,无论是用于异常解析还是物体识别,光度法都是为航天任务提供业务支持的有力工具。为了准确确定未解决的居住空间物体的大小,形状,自旋速率,可部署状态或姿态信息,需要使用多赫兹采样率光度法来捕获这些物体可能表现出的相对较快的亮度变化。 OSCOM代表用于执行任务的CubeSats的光学跟踪和光谱表征,是一种低成本,便携式的望远镜系统,具有时间分辨的小型卫星测光功能,可在短时间内现场部署,以便从多个站点同时观察。我们介绍了OSCOM背后的电光设计原理和1.5 U DICE-2 CubeSat的光曲线,以及在碎片事件发生后对ASTRO-H卫星主体的同时观测。
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