To meet the high contrast requirement of 1 x 10(-10) to image an Earth-like planet around a sun-like star, space telescopes equipped with coronagraphs require wavefront control systems. Deformable mirrors (DMs) are a key element of a wavefront control system, as they correct for imperfections, thermal distortions, and diffraction that would otherwise corrupt the wavefront and ruin the contrast. The goal of the CubeSat DM technology demonstration mission is to test the ability of a microelectromechanical system (MEMS) DM to perform wavefront control on-orbit on a nanosatellite platform. We consider two approaches for an MEMS DM technology demonstration payload that will fit within the mass, power, and volume constraints of a CubeSat: (1) a Michelson interferometer and (2) a Shack-Hartmann wavefront sensor. We clarify the constraints on the payload based on the resources required for supporting CubeSat subsystems drawn from subsystems that we have developed for a different CubeSat flight project. We discuss results from payload laboratory prototypes and their utility in defining mission requirements.
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机译:为了满足1 x 10(-10)的高对比度要求,以将类似太阳的恒星周围的地球行星成像,配备日冕仪的太空望远镜需要波前控制系统。可变形反射镜(DM)是波阵面控制系统的关键要素,因为它们可以校正不完整的缺陷,热变形和衍射,否则会破坏波阵面并破坏对比度。 CubeSat DM技术演示任务的目标是测试微机电系统(MEMS)DM在纳米卫星平台上执行在轨波前控制的能力。我们考虑两种适用于MEMS DM技术演示有效负载的方法,这些方法将适合CubeSat的质量,功率和体积约束:(1)迈克尔逊干涉仪和(2)Shack-Hartmann波前传感器。我们基于支持CubeSat子系统所需的资源来阐明对有效载荷的限制,这些资源来自我们为其他CubeSat飞行项目开发的子系统。我们讨论了有效载荷实验室原型的结果及其在定义任务需求中的效用。
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