Passive Stabilization Systems for CubeSat Nanosatellites: General Principles and Features

2019 26th Saint Petersburg International Conference on Integrated Navigation Systems (ICINS) Pub Date : 2019-05-01 DOI:10.23919/ICINS.2019.8769434

I. Belokonov, I. Timbai, D. Davydov

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引用次数: 2

Abstract

This paper studies the dynamics of the angular motion of CubeSat nanosatellites with the passive stabilization systems of different types: aerodynamic, aerodynamic-gravitational, gravitational, gravitational-aerodynamic systems. The research was carried out in a probabilistic formulation. Using the obtained analytical distribution functions of the maximum angle of the nanosatellite longitudinal axis deviation from the required direction (orbital velocity vector, or local vertical), the formulas for selecting design parameters (geometrical dimensions, static stability margin, inertia moments) are derived. In the circular orbit at the required flight altitude, these parameters provide the deviation of the longitudinal axis from the required direction less than the allowable value with a given probability for a specified error of the initial angular velocity formed by the separation system. The nomograms for selecting the main design parameters of a CubeSat nanosatellite have been constructed.

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立方卫星纳米卫星无源稳定系统:一般原理和特点

本文研究了采用气动、气动-重力、重力、重力-气动等不同类型被动稳定系统的CubeSat纳米卫星角运动动力学。这项研究是用概率公式进行的。利用得到的纳米卫星纵轴偏离所需方向(轨道速度矢量或局部垂直方向)的最大角度解析分布函数，导出了设计参数(几何尺寸、静稳定裕度、惯性矩)的选择公式。在所需飞行高度的圆形轨道上，这些参数提供了在分离系统形成的初始角速度的指定误差下，纵轴与所需方向的偏差小于给定概率的允许值。建立了立方卫星纳米卫星主要设计参数选择图。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2019 26th Saint Petersburg International Conference on Integrated Navigation Systems (ICINS)

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