Small-amplitude periodic orbit around sun-earth L1/L2 Controlled by solar radiation pressure

被引：0

作者：

机构：

[1] Tanaka, Keita

[2] Kawaguchi, Jun'ichiro

来源：

Tanaka, Keita (k-tanaka@jh.jp.nec.com) | 1600年 / Japan Society for Aeronautical and Space Sciences卷 / 59期

关键词：

The L1 and L2 points of the Sun-Earth system attract much attention for various space uses; such as observation and communication. Deploying the spacecraft just on L1/L2 is; however; not convenient; because L1 always overlaps with the Sun as seen from the Earth and L2 is hidden behind the shadow of the Earth. Adopting a small-amplitude periodic orbit around the L1/L2 points is one option to solve this problem. The orbit can be achieved by low continuous maneuvering. The required magnitude of acceleration is at a level that can be managed by solar radiation pressure. Utilizing solar radiation pressure has the possibility of saving maneuvering to keep the spacecraft near a L1/L2 orbit. Acceleration due to solar radiation pressure depends on the surface area of the spacecraft and thus the spacecraft should be equipped with a large flat surface. A spacecraft equipped with a solar sail is appropriate. This paper presents two station-keeping examples of solar sails in the vicinity of SE L1/L2 using acceleration resulting from solar radiation pressure. The orbit control laws are built into the linear system about the equilibrium; and we confirm that they are applicable in the non-linear system through numerical calculation. © 2016 The Japan Society for Aeronautical and Space Sciences;

D O I：

暂无

中图分类号：

学科分类号：

摘要：

Journal article (JA)

引用

共 50 条

[41] Ballistic design of transfer trajectories from artificial-satellite earth orbit to halo orbit in the neighborhood of the L2 point of the Sun-Earth system
I. S. Il’in
G. S. Zaslavsky
S. M. Lavrenov
V. V. Sazonov
V. A. Stepanyantz
A. G. Tuchin
D. A. Tuchin
V. S. Yaroshevsky
Cosmic Research, 2014, 52 : 437 - 449
[42] Ballistic Design of Transfer Trajectories from Artificial-Satellite Earth Orbit to Halo Orbit in the Neighborhood of the L2 Point of the Sun-Earth System
Il'in, I. S.
Zaslavsky, G. S.
Lavrenov, S. M.
Sazonov, V. V.
Stepanyantz, V. A.
Tuchin, A. G.
Tuchin, D. A.
Yaroshevsky, V. S.
COSMIC RESEARCH, 2014, 52 (06) : 437 - 449
[43] Optimal Escape from Sun-Earth and Earth-Moon L2 with Electric Propulsion
Mascolo, Luigi
Casalino, Lorenzo
AEROSPACE, 2022, 9 (04)
[44] Autonomous celestial navigation and analysis of precision for spacecraft on Halo orbit near L2 point of Sun-Earth system
Zhao, Shu-Ge
Zhang, Jing-Rui
Zhang, Yao
Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology, 2013, 33 (11): : 1119 - 1123
[45] ORBIT DETERMINATION OF SPACECRAFT IN EARTH-MOON L1 AND L2 LIBRATION POINT ORBITS
Woodard, Mark
Cosgrove, Daniel
Morinelli, Patrick
Marchese, Jeffrey
Owens, Brandon
Folta, David
ASTRODYNAMICS 2011, PTS I - IV, 2012, 142 : 1683 - +
[46] Transfer to Distant Retrograde Orbits via Rideshare to Sun-Earth L1 Point
Parsay, Khashayar
Folta, David C.
JOURNAL OF GUIDANCE CONTROL AND DYNAMICS, 2022, 45 (01) : 179 - 184
[47] Ridesharing Options from Geosynchronous Transfer Orbits to the Sun-Earth L1 Region
Romero, Juan Ojeda A.
Howell, Kathleen C.
JOURNAL OF SPACECRAFT AND ROCKETS, 2023, 60 (02) : 601 - 615
[48] The efficient computation of transfer trajectories between earth orbit and L1 halo orbit within the framework of the sun-earth restricted circular three body problem
Kechichian, Jean Albert
Advances in the Astronautical Sciences, 2000, 105 II : 1159 - 1180
[49] The efficient computation of transfer trajectories between earth orbit and L1 halo orbit within the framework of the sun-earth restricted circular three body problem
Kechichian, JA
SPACEFLIGHT MECHANICS 2000, VOL 105, PTS I AND II, 2000, 105 : 1159 - 1180
[50] Monitoring Earth's radiation fluxes from Lagrange points L1 and L2
Dzitoev, A. M.
Lapovok, Y. V.
Penkov, M. M.
Khankov, S. I.
JOURNAL OF OPTICAL TECHNOLOGY, 2018, 85 (09) : 573 - 578

← 1 2 3 4 5 →