一种针对金星探测器的姿态指向设计

doi:10.3969/j.issn.1674-1579.2017.05.003

空间控制技术与应用 ›› 2017, Vol. 43 ›› Issue (5): 14-21.doi: 10.3969/j.issn.1674-1579.2017.05.003

一种针对金星探测器的姿态指向设计

马越辰，徐明

（北京航空航天大学，北京 100191）

收稿日期:2017-03-07 出版日期:2017-10-20 发布日期:2018-01-03
作者简介:作者简介：马越辰（1994—），男，硕士研究生，研究方向为轨道设计和空间探测;徐明(1981—),男，副教授，研究方向为航天器轨道动力学与控制、航天任务分析与设计.
基金资助:

*国家自然科学基金资助项目（11772024）.

An Attitude Pointing Design Applied to Venus Spacecraft

MA Yue-Chen, XU Ming

(Beihang University, Beijing 100191, China)

Received:2017-03-07 Online:2017-10-20 Published:2018-01-03

摘要/Abstract

摘要： 摘要：金星探测需要超长距离低码率传输，因而金星探测器需要保持其数传天线指向地球.相对于地球轨道飞行器来说，金星探测器距离太阳更近，需要固定散热面来维持探测器内的温度.提供一种基于在金星探测器偏置安装天线的姿态指向设计，能够保证从金星向地球传输数据并且维持散热面远离太阳.而此设计旨在减少数传天线的数量至一根同时将两个固定平面作为散热面.还提供两种详细方案来控制姿态机动来保证在数传天线始终指向地球的同时在特定节点切换散热面.

关键词: 关键词：金星探测, 偏置安装天线, 固定散热面

Abstract: Abstract：Venus detection requires ultralongdistance transmission at lowbitrate, so Venus spacecraft need to keep digital antennas pointing to the earth. Compared with the earth spacecraft, Venus spacecraft are closer to the sun. So the fixed radiator is needed to maintain the temperature inside the spacecraft. Based on the antenna irregularly placed on the spacecraft, a design is provided to ensure that the data is transferred from Venus to the earth and that the heat dissipation surface is maintained away from the sun. Unlike other Venus spacecraft such as Venus Express and AKATSUKI equipped with two or more antennas to transmit data, this design is aimed to reduce the number of digital antennas to only one, meanwhile the two fixed plane is designed as a cooling surface. Two detailed strategies are also provided to drive the attitude maneuver to ensure that the digital antenna always points to the earth while switching the cooling surface in a particular node.

Key words: Keywords：Venus exploration, placing the antenna irregularly, fixed radiator

中图分类号:

V476.4

马越辰, 徐明. 一种针对金星探测器的姿态指向设计[J]. 空间控制技术与应用, 2017, 43(5): 14-21.

MA Yue-Chen, XU Ming. An Attitude Pointing Design Applied to Venus Spacecraft[J]. , 2017, 43(5): 14-21.

参考文献

参考文献［1］BIENSTOCK B J. Pioneer Venus and Galileo entry probe heritage［C］//Proceedings of the International Workshop Planetary Probe Atmospheric Entry and Descent Trajectory Analysis and Science. Lisbon: Portugal, 2003. ［2］张伟, 方宝东, 成玫, 等. 空间飞行器分离式构型设计［J］. 上海航天, 2013,30(1):17. ZHANG W, FANG B C, CHENG M, et al. Design of space vehicle separated configuration［J］. Shanghai Aerospace, 2013,30(1):17. ［3］BRADY W F W, Pioneer Venus probe targeting manoeuvre design［C］//AAS/AIAA Astrodynamics Conference. Washington D.C.: AIAA, 1979. ［4］LORENZ R D. Attitude and angular rates of planetary probes during atmospheric descent: Implications for imaging［J］. Planetary & Space Science, 2010,58(5):838846. ［5］JOHNSON W T K. Magellan imaging radar mission to Venus［J］. Proceedings of the IEEE, 1991,79(6):777790. ［6］ACCOMAZZO A, SCHMITZ P, TANCO I. From Earth to Venusreaching our sister planet［J］. Esa Bulletin.bulletin Ase.european Space Agency, 2006,127(127):3844. ［7］WINTON A J, SCHNORHK A, MCCARTHY C, et al. Venus express spacecraft［J］. Esa Bul letin.bulletin Ase.european Space Agency, 2005,124(124):1622. ［8］ISHII N, YAMAKAWA H, SAWAI S, et al. Current status of the PLANETC Venus orbiter design［J］. Advances in Space Research, 2004,34(8):16681672. ［9］NAKAMURA M, IMAMURA T, UENO M, et al. PlanetC: Venus climate orbiter mission of Japan［J］. Planetary & Space Science, 2007,55(12):18311842. ［10］江山. 日本测试金星探测器发动机［J］. 太空探索, 2011(10):1515. JIANG S. Japantest Venus probe engine［J］. Space Exploration, 2011(10):1515. ［11］徐煜华. “拂晓”号起死回生［J］. 科学世界, 2016(5):5663. XU Y H. “Dawn” was born back to life［J］. The Scientific World, 2016(5):5663.

一种针对金星探测器的姿态指向设计

An Attitude Pointing Design Applied to Venus Spacecraft

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 0

Metrics

本文评价

推荐阅读 0