太阳帆航天器非对称共振晕轨道设计与分析

doi:10.7527/S1000-6893.2025.32576

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太阳帆航天器非对称共振晕轨道设计与分析

王大维¹,叶东¹,肖岩²,李海洋³

1. 哈尔滨工业大学
2. 哈尔滨工业大学卫星技术研究所
3. 深空探测实验室

收稿日期:2025-07-16 修回日期:2025-10-24 出版日期:2025-10-24 发布日期:2025-10-24
通讯作者: 叶东

Solar-sail spacecraft asymmetric resonant Halo orbits design and analysis

Received:2025-07-16 Revised:2025-10-24 Online:2025-10-24 Published:2025-10-24
Contact: Dong Ye

摘要/Abstract

摘要： 太阳帆作为一种利用太阳辐射压力产生持续小推力的航天推进系统，因其无需消耗推进剂的特点，在深空探测等长期航天任务中展现出独特优势。基于太阳-水星椭圆限制性三体问题这一动力学模型，提出三种递进式的太阳帆指向律，使太阳帆平面由最初正对太阳，过渡到在引力平面内偏离太阳方向，再到最终偏离引力平面。利用多段打靶法进行轨道延拓计算，获得了具有不同共振比的太阳帆共振晕轨道。在三种指向策略下，分别对太阳帆的面质比、锥角与方位角进行参数延拓。结果表明，前两种策略下得到的共振晕轨道在旋转坐标系中关于XZ平面呈对称结构，而第三种策略下获得的轨道则不关于任意平面或直线对称，表现出复杂的空间三维结构，同时保持良好的周期性。最后在高精度星历模型下对轨道稳定性进行分析，结果显示所构建的太阳帆共振晕轨道在无需轨道保持的情况下，可在约4–6个水星轨道周期内（约352–528天）维持轨道形状且不发散，具备一定的自然稳定性。

关键词: 椭圆限制性三体问题, 太阳帆航天器, 共振晕轨道, 太阳帆指向律, 星历模型

Abstract: The solar sail is a type of continuous low-thrust spacecraft that generates propulsion through solar radiation pres-sure. Due to its fuel-free operation, it is particularly suitable for long-duration deep space exploration missions. Based on the dynamical models of the Sun-Mercury elliptic restricted three-body problem, this study proposes three progressive solar sail steering laws. These steering strategies enable the normal vector of the solar sail plane to transition from pointing directly toward the Sun, to deviating within the gravitational plane, and finally to deviating out of the gravitational plane. By employing a multiple-shooting method combined with continuation techniques, families of resonant halo orbits with different resonance ratios are obtained for solar sail spacecraft. Under the three proposed steering laws, parameter continuation is performed with respect to the sail’s area-to-mass ratio, cone angle, and pitch angle, respectively. The first two steering laws yield resonant halo orbits that are symmetric about the XZ-plane of the rotating coordinate system. In contrast, the third steering law produces periodic orbits that are asymmetric with respect to any plane or line, exhibiting complex three-dimension structures with periodicity remained. Finally, the stability of the solar sail resonant halo orbits under different steering laws is analyzed within a high-precision ephemeris model. The results indicate that these orbits can maintain their overall shape without sig-nificant divergence for approximately 4 to 6 Mercury orbital periods (about 352 to 528 days) without station-keeping maneuvering.

Key words: Elliptic restricted three-body problem, Solar-sail spacecraft, Resonant Halo orbit, Solar sail steering law, Ephemeris model

中图分类号:

V412.4

王大维叶东肖岩李海洋. 太阳帆航天器非对称共振晕轨道设计与分析[J]. 航空学报, doi: 10.7527/S1000-6893.2025.32576.

参考文献

[1]ZHAO P, WU C C, LI Y M.Design and applica-tion of solar sailing: A review on key technolo-gies[J].Chinese Journal of Aeronautics, 2023, 36(5):125-144
[2]GARWIN R L.Solar sailing-A practical method of pro-pulsion within the solar system[J].Jet Propulsion, 1958, 90(123):188-190
[3]TSUDA Y, MORI O, FUNASE R, et al.Achievement of IKAROS - Japanese deep space solar sail demonstra-tion mission[J].ACTA ASTRONAUTICA, 2013, 82(2):183-188
[4]JOHNSON L, WHORTON M, HEATON A, et al.NanoSail-D: A solar sail demonstration mis-sion[J].ACTA ASTRONAUTICA, 2011, 68(5-6):571-575
[5]LOCKETT T R, CASTILLO-ROGEZ J, JOHNSON L, et al.Near-Earth Asteroid Scout Flight Mission[J].IEEE Aerospace and Electronic Systems Magazine, 2020, 35(3):20-29
[6]RIDENOURE R W, MUNAKATA R, WONG S D, et al.Testing The LightSail Program: Advancing Solar Sailing Technology Using a CubeSat Platform[J].Journal of Small Satellite, 2016, 5(3):531-550
[7]SPENCER D A, BETTS B, BELLARDO J M, et al.The LightSail 2 solar sailing technology demonstra-tion[J].Advances in Space Research, 2021, 67(9):2878-2889
[8]TAKAO Y, MORI O, MATSUMOTO J, et al.Sample return system of OKEANOS—The solar power sail for Jupiter Trojan exploration[J].Acta Astronautica, 2023, 213(000):121-137
[9]HEILIGERS J, HIDDINK S, NOOMEN R, et al.Solar sail Lyapunov and Halo orbits in the Earth–Moon three-body problem[J].Acta Astronautica, 2015, 116:25-35
[10]张晨, 张皓.基于月球借力的低能入轨策略[J].航空学报, 2023, 44(2):326507-
[11]张晨.基于数值延拓的日月综合借力入轨策略[J].北京航空航天大学学报, 2024, 50(4):1176-1186
[12]HOU X Y, LIU L.On motions around the collinear li-bration points in the elliptic restricted three-body prob-lem[J]., (4):3552-3560.[J].Monthly Notices of the Royal Astronomical Society, 2011, 415(4):3552-3560
[13]PENG H, XU S.Stability of two groups of multi-revolution elliptic halo orbits in the elliptic restricted three-body problem[J].Celestial Mechanics and Dynamical As-tronomy: An international journal of space dynamics, 2015, 123(3):279-303
[14]PENG H, BAI X, XU S.Continuation of periodic orbits in the Sun-Mercury elliptic restricted three-body prob-lem[J].Communications in Nonlinear Science & Numeri-cal Simulation, 2017, 47(6):1-15
[15]MCINNES C R.Solar sailing: Orbital mechanics and mission applications[J].Advances in Space Research, 2003, 31(8):1971-1980
[16]JOHN BOOKLESS, COLIN MCINNES.Control of Lagrange point orbits using solar sail propulsion[J].Acta Astronautica, 2008, 62(2):159-176
[17]HEILIGERS J, HIDDINK S, NOOMEN R, et al.Solar sail Lyapunov and Halo orbits in the Earth–Moon three-body problem[J].Acta Astronautica, 2015, 116(NOV.-DEC.):25-35
[18]HEILIGERS J, MACDONALD M, PARKER J S.Ex-tension of Earth-Moon libration point orbits with solar sail propulsion[J].Astrophysics & Space Science, 2016, 361(7):241-
[19]安诗宇，刘明，李化义，等.地月三体系统新型太阳帆周期轨道设计与分析[J].航空学报, 2025, 46(4):230828-
[20]CHUJO T, TAKAO Y.Synodic Resonant Halo Orbits of Solar Sails in Restricted Four-Body Prob-lem[J].Journal of spacecraft and rockets, 2022, 59(6):19-
[21]GONG S, LI J.Solar sail periodic orbits in the elliptic restricted three-body problem[J].Celestial Mechanics and Dynamical Astronomy, 2015, 121(2):121-137
[22]HUANG J, BIGGS, J, CUI N.Families of halo orbits in the elliptic restricted three-body problem for a solar sail with reflectivity control devices[J].ADVANCES IN SPACE RESEARCH, 2020, 65(3):1070-1082
[23]LOSADA F, HEILIGERS J.New solar-sail orbits for polar observation of the earth and moon[J].JOURNAL OF GUIDANCE CONTROL AND DYNAMICS, 2021, 44(12):2155-2171
[24]RIOS R L, SCHEERES D J.Generalized Model for So-lar Sails[J].Journal of Spacecraft & Rockets, 2015, 42(1):182-185
[25]E M SPREEN, Trajectory Design and Targeting For Ap-plications to the Exploration Program in Cislunar Space[D].PURDUE UNIVERSITY, 2021.
[26]CHARLES H.Ancillary data services of NASA's Navi-gation and Ancillary Information Facility[J].Planetary and Space Science, 1996, 44(1):65-70

E-mail：hkxb@buaa.edu.cn

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太阳帆航天器非对称共振晕轨道设计与分析

Solar-sail spacecraft asymmetric resonant Halo orbits design and analysis

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