月球轨道编队超长波天文观测微卫星任务

月球背面能够有效屏蔽来自地球并同时遮挡来自太阳的射电信号干扰,拥有太阳系中近乎最安静的电磁环境,是开展空间超长波天文观测的最佳选择区域。在立足完成空间干涉实验的基本任务目标基础、并力争实现重大科学发现的研究思路基础上,研制并发射两颗微卫星,搭载"嫦娥4号"任务进入地月转移轨道,自主完成地月转移、近月制动,在有效燃料约束下形成环月大椭圆轨道编队,构建环月超长波天文干涉仪。说明了系统的工作模式,对数据处理与科学分析方法进行了论述,包括数据预处理、干涉成像与全天功率谱获取角度,进而从支持服务模块和科学载荷模型两个方面对微卫星方案进行了简要概述,凝练了项目任务解决的关键科学与技术问题。月球轨道编队超长波天文观测微卫星的实施将通过全球首个绕月近距编队飞行系统,构建全球首个星–星干涉射电天文观测系统,进而打开人类认识宇宙的新窗口。     

月球中继通信卫星系统发展综述与展望

中继通信是一些月球探测任务中必须解决的关键问题,特别是月球背面和两极地区的着陆和巡视探测任务以及载人登月任务。对国内外月球中继通信卫星的研究和发展情况进行了综述,在对月球中继通信任务需求分析的基础上,从中继通信体制选择、轨道选择等方面对月球中继通信任务的实现途径进行了分析,并对月球中继通信技术的未来发展进行了展望。     

地月L2点周期轨道的月球背面覆盖分析

地月L2点附近轨道具备独特的动力学和运动学特性,是月球背面探测任务的中继卫星首选布设位置。面向未来月球背面探测任务的中继通信需求,分析并研究了地月L2点周期轨道(halo轨道)对月球背面的覆盖。在圆型限制性三体问题模型下,研究并给出了halo轨道族延拓计算方法,基于延拓法设计了地月系大范围南北halo轨道族;给出了中继卫星的月球背面覆盖计算模型,定义了相应的时间覆盖因子;数值仿真了地月系南北halo轨道族的月球背面覆盖情况。研究结果表明:地月L2点周期轨道幅值和类型决定其对月面的覆盖性,幅值较小的轨道的月面整体覆盖性较好,幅值较大的轨道对月球南北极覆盖较好,南北族轨道分别有利于月球南北半球的覆盖。文章研究可为我国"嫦娥4号"月球背面探测任务的中继星轨道设计提供有益参考和借鉴。     

“嫦娥4号”月球背面软着陆任务设计

介绍了"嫦娥4号"月球背面软着陆任务设计方案。着陆区初步选定为月球背面南极–艾特肯(South PoleAitken,SPA)盆地内的冯·卡门(Von Kármán)撞击坑内。采用中继星实现着陆器和巡视器的对地通信,并选择环绕地月拉格朗日L2点的halo轨道作为其使命轨道。采用CZ-4C火箭和CZ-3B火箭,分别完成中继星和着陆器–巡视器组合体的发射。两器一星上共配置了6台国内研制科学载荷和3台国际合作科学载荷,开展以低频射电天文观测、巡视区形貌、矿物组份及浅层结构为主的科学探测。此外,还搭载了2颗月球轨道编队飞行微卫星、月面微型生态圈和大孔径激光角反射镜,分别开展超长波天文干涉测量试验、月面生态系统试验和超过地月距离的激光测距试验。通过创新设计顶层任务,充分继承成熟技术和产品,增加中继通信功能模块,开放资源引入高性能载荷和搭载项目,将实现一次低成本、短周期、大开放、高效益的月球探测任务。     

“嫦娥4号”中继星任务分析与系统设计

作为"嫦娥4号"任务的重要组成部分,中继星将为着陆器和巡视器提供中继通信支持。不同于其它月球探测器,中继星首次选择了绕地月L2平动点运行的晕(Halo)轨道以保证对月球背面的着陆器和巡视器提供连续的中继通信服务,面临诸多技术挑战。在对中继星任务特点进行分析的基础上,梳理了研制中的技术难题,包括使命轨道的选择、使命轨道的到达和长期维持、中继通信体制选择等,并提出了解决方案。中继星的总体设计方案概述也在文中给出。     

中国月球探测任务轨道确定技术及发展综述

月球探测器的轨道确定是完成月球探测任务的基础,在我国月球探测任务的引领下,在我国深空测控体系发展的同时,轨道确定技术也得到了快速的进步。从时空参考框架和动力学模型两个方面介绍了我国月球探测任务轨道确定技术的发展过程,基于时空参考框架的优化及动力学模型的改进,我国月球探测器的轨道确定能力及精度也不断提升,这对于当前及后续的月球探测任务都有很好的借鉴意义。     

Materials trade study for lunar/gateway missions.

The National Aeronautics and Space Administration (NASA) administrator has identified protection from radiation hazards as one of the two biggest problems of the agency with respect to human deep space missions. The intensity and strength of cosmic radiation in deep space makes this a 'must solve' problem for space missions. The Moon and two Earth-Moon Lagrange points near Moon are being proposed as hubs for deep space missions. The focus of this study is to identify approaches to protecting astronauts and habitats from adverse effects from space radiation both for single missions and multiple missions for career astronauts to these destinations. As the great cost of added radiation shielding is a potential limiting factor in deep space missions, reduction of mass, without compromising safety, is of paramount importance. The choice of material and selection of the crew profile play major roles in design and mission operations. Material trade studies in shield design over multi-segmented missions involving multiple work and living areas in the transport and duty phase of space mission's to two Earth-Moon co-linear Lagrange points (L1) between Earth and the Moon and (L2) on back side of the moon as seen from Earth, and to the Moon have been studied. It is found that, for single missions, current state-of-the-art knowledge of material provides adequate shielding. On the other hand, the choice of shield material is absolutely critical for career astronauts and revolutionary materials need to be developed for these missions. This study also provides a guide to the effectiveness of multifunctional materials in preparation for more detailed geometry studies in progress.     

地月平动点中继应用轨道维持

地月平动点中继应用轨道对于月球背面探测具有十分重要的应用价值,由于地月平动点的不稳定性,必须进行轨道维持。文章研究了真实力模型下月球平动点中继应用轨道的维持。首先,基于限制性三体问题下平动点轨道的运动特性,研究了平动点轨道维持的数学模型与维持策略,提出了平动点轨道维持的连续环绕控制方法,并给出了轨道维持的Halo和Lissajous两种控制方式;其次,充分考虑各天体和光压摄动下,采用数值手段研究了不同幅值的地月平动点周期中继应用轨道的维持间隔与速度增量等。研究结果表明:Lissajous控制方式适用于月球平动点中继应用轨道的维持,在给定测控精度条件下,维持间隔约7.4d,速度增量优于20m/s/a。该方法已经成功应用于我国"嫦娥2号"日地平动点任务和"嫦娥5T1"地月平动点任务并获得了良好的控制效果,还可直接应用于我国未来"嫦娥4号"等月球背面探测任务。     

嫦娥四号着陆器月面工作遮挡应对方案研究

嫦娥四号着陆于月球背面南极 艾特肯盆地内,着陆区周围复杂地形导致测控和通信遮挡风险。针对这一问题,开展了着陆区的测控、光照遮挡分析,提出利用轨道控制策略的精细化设计来提高着陆点精度、优化月面工作程序和增加自主控制功能的设计方法,全方面降低嫦娥四号着陆器在月球背面着陆区的生存风险。该方法已通过嫦娥四号着陆器在轨验证,可以为其他深空探测任务提供参考和借鉴。     

China's Future Missions for Deep Space Exploration and Exoplanet Space Survey by 2030

Four future missions for deep space exploration and future space-based exoplanet surveys on habitable planets by 2030 are scheduled to be launched. Two Mars exploration missions are designed to investigate geological structure, the material on Martian surface, and retrieve returned samples. The asteroids and main belt comet exploration is expected to explore two objects within 10 years. The small-body mission will aim to land on the asteroid and get samples return to Earth. The basic physical characteristics of the two objects will be obtained through the mission. The exploration of Jupiter system will characterize the environment of Jupiter and the four largest Moons and understand the atmosphere of Jupiter. In addition, we further introduce two space-based exoplanet survey by 2030, Miyin Program and Closeby Habitable Exoplanet Survey (CHES Mission). Miyin program aims to detect habitable exoplanets using interferometry, while CHES mission expects to discover habitable exoplanets orbiting FGK stars within 10 pc through astrometry. The above-mentioned missions are positively to achieve breakthroughs in the field of planetary science.      

China's Lunar and Deep Space Exploration Program for the Next Decade (2020-2030)

China has carried out four unmanned missions to the Moon since it launched Chang'E-1, the first lunar orbiter in 2007. With the implementation of the Chang'E-5 mission this year, the three phases of the lunar exploration program, namely orbiting, landing and returning, have been completed. In the plan of follow-up unmanned lunar exploration missions, it is planned to establish an experimental lunar research station at the lunar south pole by 2030 through the implementation of several missions, laying a foundation for the establishment of practical lunar research station in the future. China successfully launched its first Mars probe on 23 July 2020, followed in future by an asteroid mission, second Mars mission, and a mission to explore Jupiter and its moons.      

载人月球极地探测定点返回轨道设计

针对载人月球极地探测任务,对定点返回轨道优化设计问题进行了研究。根据月球极地轨道的特性,介绍了三种返回轨道机动方案。结合三脉冲变轨方案,采用了从初步计算到精确计算的串行求解策略,对定点返回轨道进行优化设计。初步计算阶段,建立了基于近月点伪参数的三段二体拼接模型,将三脉冲机动段与月球逃逸段解耦,求解轨道初值;精确计算阶段,提出了两段拼接方法,分别进行逆向和正向高精度数值积分。经过仿真测试,验证了该策略求解的有效性和准确性。最后,通过大量的仿真计算,分析了定点返回轨道的特性。研究结论对未来载人月球极地探测定点返回轨道方案的设计具有重要的参考价值。     

“龙江2号”月球轨道微卫星定轨分析

微纳卫星深空探测任务中,通常所分配的测控资源有限,因此有必要对有限测控资源条件下微纳卫星的定轨精度进行分析。以微纳卫星深空探测为背景,采用"龙江2号"微卫星的轨道测量数据对其定轨精度进行了分析。"龙江2号"微卫星只有USB轨道测量数据,且环月段测控资源相对紧张,每天有两站跟踪,共约3～4 h的轨道测量数据。首先介绍了"龙江2号"微卫星飞行任务及其飞行过程中影响测定轨的因素;其次给出了定轨的动力学模型,对微卫星地月转移段的定轨精度进行了分析;最后通过分析摄动力、动量轮卸载以及数据弧段长度的影响,给出了微卫星环月阶段所使用的定轨策略,并通过重叠弧段比较的模式,给出了微卫星环月段的定轨精度。研究结论可以为后续微纳卫星深空探测任务提供有益参考。     

日地L1点探测任务设计与结果分析

日地L1点是太阳观测任务的理想观测点,对于中国后续太阳观测任务具有重要意义,因此在嫦娥五号的拓展任务阶段设计并实施了中国首次日地L1点探测任务,通过在轨飞行验证了日地L1点转移轨道、环绕轨道设计的正确性,对日地L1点的测控链路环境、太阳辐照环境、三体动力学环境、空间辐射环境等飞行环境进行了探测和验证。轨道飞行和各项环境探测的结果与设计模型的预示结果之间比对一致性较好,通过在轨飞行数据验证了设计模型的正确性。各项试验获得了预期的技术成果,进一步丰富了嫦娥五号任务的成果产出,对中国后续深空探测任务和产品的设计具有重要借鉴意义。     

"嫦娥一号"卫星轨控标定方法研究与实现

在航天测控任务中,对轨控效果进行标定并合理利用可以实现更为精准的轨道控制.提出了一种综合利用控前控后精密轨道、轨控过程遥测姿态数据、遥测加速度计测量数据对沉底发动机、轨控发动机、加速度计刻度系数进行标定的方法;介绍了该方法在中国首次月球探测任务中的应用情况;最后分析了标定结果对定轨及定姿精度的敏感程度,从而在理论上进一步说明在后续深空探测中利用精密轨道进行轨控标定的可行性和重要性.     

Electrostatic space radiation shielding

For the success of NASA’s new vision for space exploration to Moon, Mars and beyond, exposures from the hazards of severe space radiation in deep space long duration missions is ‘a must solve’ problem. The payload penalty demands a very stringent requirement on the design of the spacecrafts for human deep space missions. The exploration beyond low Earth orbit (LEO) to enable routine access of space will require protection from the hazards of the accumulated exposures of space radiation, Galactic Cosmic Rays (GCR) and Solar Particle Events (SPE), and minimizing the production of secondary radiation is a great advantage. There is a need to look to new horizons for newer technologies. The present investigation revisits electrostatic active radiation shielding and explores the feasibility of using the electrostatic shielding in concert with the state-of-the-art materials shielding and protection technologies. The full space radiation environment has been used, for the first time, to explore the feasibility of electrostatic shielding. The goal is to repel enough positive charge ions so that they miss the spacecraft without attracting thermal electrons. Conclusions are drawn for the future directions of space radiation protection.     

Adaptive response studies may help choose astronauts for long-term space travel.

Long-term manned exploratory missions are planned for the future. Exposure to high-energy neutrons, protons and high charge and energy particles during a deep space mission, needs protection against the detrimental effects of space radiation. It has been suggested that exposure to unpredictable extremely large solar particle events would kill the astronauts without massive shielding. To reduce this risk to astronauts and to minimize the need for shielding, astronauts with highest significant adaptive responses should be chosen. It has been demonstrated that some humans living in very high natural radiation areas have acquired high adaptive responses to external radiation. Therefore, we suggest that for a deep space mission the adaptive response of all potential crew members be measured and only those with high adaptive response be chosen. We also proclaim that chronic exposure to elevated levels of radiation can considerably decrease radiation susceptibility and better protect astronauts against the unpredictable exposure to sudden and dramatic increase in flux due to solar flares and coronal mass ejections.     

Design and analysis of a direct transfer trajectory from a near rectilinear halo orbit to a low lunar orbit

A near rectilinear halo orbit (NRHO) is regarded as a potential orbit for a future deep space station that can effectively support sustainable crewed lunar exploration missions. In this paper, the L₂ southern NRHOs are selected as the research object, and a direct transfer trajectory from an NRHO to a low lunar orbit (LLO) is designed and analyzed. First, based on the circular restricted three-body problem, the characteristics of NRHOs are discussed including geometric behaviour, stability and synodic resonance. Second, optimal direct transfer trajectories are obtained by combining a local gradient optimization with a numerical continuation strategy. A reachable domain calculation model is established. Finally, simulations are carried out to verify the feasibility of the trajectory design method. The relationship between the velocity change and the reachable domain is further analysed through simulation calculations.     

中国月球及深空空间环境探测

深空探测承载着人类航天技术发展、探索宇宙奥秘和寻找地外生命及人类宜居地的重任,成为各航天大国关注的热点。我国月球与深空探测虽然起步晚,但起点高,正在追赶并将实现领先。简要回顾了我国月球及深空空间环境探测的载荷情况、数据结果、理论和应用研究成果,简述了当前在研的自主火星空间环境探测目标以及规划中的未来深空探测任务,并根据当前国际发展态势,及我国在研、规划中的月球及深空探测任务情况,分析了我国月球及深空空间环境探测的关键科学问题、载荷技术发展趋势、理论与模拟的研究需求,最后对深空环境探测进行了展望。