As NASA prepares to return humans to the moon and establish a long-term presence on the surface, technologies must be developed to access previously unvisited terrain regardless of the condition. Among these technologies is a guidance, navigation and control (GNC) system capable of safely and precisely delivering a spacecraft, whether manned or robotic, to a predetermined landing area. This thesis presents detailed research of both terrain-relative navigation using a terrain-scanning instrument and beacon-relative radiometric navigation using beacons in lunar orbit or on the surface of the moon. The models for these sensors are developed along with a baseline sensor suite that includes an altimeter, IMU, velocimeter, and star camera. Linear covariance analysis is used to rapidly perform the trade studies relevant to this problem and to provide the navigation performance data necessary to determine which navigation method is best suited to support a 100 m 3-sigma navigation requirement for landing anytime and anywhere on the moon.
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机译:随着NASA准备将人类送回月球并在水面建立长期存在,无论条件如何,都必须开发出可以访问以前未曾访问过的地形的技术。在这些技术中,有一种导航,导航和控制(GNC)系统,该系统能够安全准确地将载人或机器人的航天器运送到预定着陆区。本文介绍了使用地形扫描仪进行的相对地形导航和使用月球轨道或月球表面上的信标的信标相对辐射测量导航的详细研究。这些传感器的模型是与基线传感器套件一起开发的,该套件包括高度计,IMU,速度计和星形摄像机。线性协方差分析可用于快速进行与此问题相关的贸易研究,并提供必要的导航性能数据,以确定哪种导航方法最适合满足100 m 3-sigma导航要求,以便随时随地登陆月球。
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