Families of periodic orbits in Hill’s problem with solar radiation pressure: application to Hayabusa 2
详细信息 查看全文
- 作者:Marco Giancotti ; Stefano Campagnola…
- 关键词:Hayabusa 2 ; Hill’s Problem ; Solar radiation pressure ; Periodic orbits ; Stability ; Numerical continuation
- 刊名:Celestial Mechanics and Dynamical Astronomy
- 出版年:2014
- 出版时间:November 2014
- 年:2014
- 卷:120
- 期:3
- 页码:269-286
- 全文大小:2,225 KB
- 参考文献:1. Bookless, J., McInnes, C.: Dynamics and control of displaced periodic orbits using solar-sail propulsion. J. Guid. Control Dyn. 29(3), 527-37 (2006) CrossRef
2. Bray, T., Goudas, C.: Doubly symmetric orbits about the collinear lagrangian points. Astron. J. 72(2), 202-13 (1967) CrossRef
3. Broschart, S.B., Scheeres, D.J., Villac, B.F.: New families of multi-revolution terminator orbits near small bodies. In: AAS 09-402, vol. 135 (2010)
4. Broschart, S.B., Lantoine, G., Grebow, D.J.: Characteristics of quasi-terminator orbits near primitive bodies. In: AAS 13-335 (2013)
5. Broucke, R.A.: Stability of periodic orbits in the elliptic, restricted three-body problem. AIAA J. 7(6), 1003-009 (1969) CrossRef
6. Doedel, E., Keller, H.B., Kernevez, J.P.: Numerical analysis and control of bifurcation problems (I) bifurcation in finite dimensions. Int. J. Bifurc. Chaos 1(3), 493-20 (1991) CrossRef
7. Doedel, E., Paffenroth, R., Keller, H.B., Dichmann, D.J., Galan-Vioque, J., Vanderbauwhede, A.: Computation of periodic solutions of conservative systems with application to the 3-body problem. Int. J. Bifurc. Chaos 13(6), 1-9 (2003) CrossRef
8. Giancotti, M., Funase, R.: Solar sail equilibrium positions and transfer trajectories close to a trojan asteroid. In: 63rd International Astronautical Congress (2012)
9. Hénon, M.: Numerical exploration of the restricted problem. V. Hill’s Case: periodic orbits and their stability. Astron. Astrophys. 1, 223-38 (1969)
10. Hénon, M.: Vertical stability of periodic orbits in the restricted problem. II. Hill’s case. Astron. Astrophys. 30, 317-21 (1974)
11. Hénon, M.: New families of periodic orbits in Hill’s problem of three bodies. Celest. Mech. Dyn. Astron. 85, 223-46 (2003) CrossRef
12. Ichtiaroglou, S.: Elliptic Hill’s problem–the continuation of periodic orbits. Astron. Astrophys. 92, 139-41 (1980)
13. Ichtiaroglou, S., Voyatzis, G.: On the effect of the eccentricity of a planetary orbit on the stability of satellite orbits. J. Astrophys. Astron. 11, 11-2 (1990) CrossRef
14. Katherine, Y., Villac, B.F.: Periodic orbits families in the hill’s three-body problem with solar radiation pressure. In: Advances in the Astronautical Sciences Series, vol 136, San Diego, Colifornia (2010)
15. Keller, H.B.: Numerical solution of bifurcation and nonlinear eigenvalue problems. In: Rabinowitz, P. (ed.) Applications of Bifurcation Theory. Academic Press, New York (1977)
16. Lantoine, G., Broschart, S.B., Grebow, D.J.: Design of quasi-terminator orbits near primitive bodies. In: AAS 13-15 (2013)
17. Lara, M., Scheeres, D.J.: Stability bounds for three-dimensional motion close to asteroids. J. Astron. Sci. 50(4), 389-09 (2002)
18. Markellos, V.V., Roy, A.E., Velgakis, M.J., Kanavos, S.S.: A photogravitational hill problem and radiation effects on hill stability of orbits. Astrophys. Space Sci. 271, 293-01 (2000) CrossRef
19. Matukuma, T.: On the Periodic Orbits in Hill -s case. Proc. Imp. Acad. 6(1), 131-32 (1930)
20. Miele, A.: Revisit of the theorem of image Trajectories in the Earth-Moon space. J. Optim. Theory Appl. 147(3), 483-90 (2010) CrossRef
21. Morrow, E., Scheeres, D.J., Lubin, D.: Solar sail orbit operations at asteroids. J. Spacecr. Rockets 38(2), 279-86 (2001) CrossRef
22. Muller, T., Durech, J., Hasegawa, S., Abe, M., Kawakami, K., Kasuga, T., et al.: Thermo-physical properties of 162173 (1999 JU3), a potential flyby and rendezvous target for interplanetary missions. Astron. Astrophys. (2010)
23. Munoz-Almaraz, F., Freire, E., Galán, J., Doedel, E., Vanderbauwhede, A.: Continuation of periodic orbits in conservative and hamiltonian systems. Phys. D Nonlinear Phenom. 181(1-), 1-8 (2003) CrossRef
24. Papadakis, K.E.: Families of periodic orbits in the photo gravitational three-body problem. Astrophys. Space Sci. 245, 157-64 (1996) CrossRef
25. Russell, R.P.: Global search for planar and three-dimensional periodic orbits near Europa. In: AAS/AIAA Astrodynamics Specialist Conference, Lake Tahoe, California (2005)
26. Scheeres, D.J.: Satellite Dynamics about small bodies: averaged solar radiation pressure effects. J. Astron. Sci. 47, 25-6 (1999)
27. Scheeres, D.J.: Orbital Motion in Strongly Perturbed Environments. Springer, London (2012) CrossRef
28. Scheeres, D.J., Marzari, F.: Spacecraft dynamics in the vicinity of a comet. J. Astronaut. Sci. 50(1), 63-3 (2002)
29. Szebehely, V.: Theory of Orbits: The Restricted Problem of Three Bodies. Academic Press, New York (1967)
30. Tsuda, Y., Yoshikawa, M., Abe, M., Minamino, H., Nakazawa, S.: System design of the Hayabusa 2—asteroid sample return mission to 1999 JU3. Acta Astronaut. 91, 356-62 (2013) CrossRef
31. Voyatzis, G., Gkolias, I., Varvoglis, H.: The dynamics of the elliptic Hill problem: periodic orbits and stability regions. Celest. Mech. Dyn. Astron. 113, 125-39 (2012) CrossRef
32. Yárnoz, D., Cuartielles, J., McInnes, C.R.: Applications of solar radiation pressure dominated highly non-Keplerian trajectories around minor bodies. In: 64th International Astronautical Congress, Beijing, China (2013) - 作者单位:Marco Giancotti (1)
Stefano Campagnola (2)
Yuichi Tsuda (2)
Jun’ichiro Kawaguchi (2)
1. School of Aerospace Engineering, Sapienza University of Rome, Rome, Italy
2. Institute of Space and Astronautical Science, JAXA, Sagamihara, Japan - ISSN:1572-9478
文摘
This work studies periodic solutions applicable, as an extended phase, to the JAXA asteroid rendezvous mission Hayabusa?2 when it is close to target asteroid 1999 JU3. The motion of a spacecraft close to a small asteroid can be approximated with the equations of Hill’s problem modified to account for the strong solar radiation pressure. The identification of families of periodic solutions in such systems is just starting and the field is largely unexplored. We find several periodic orbits using a grid search, then apply numerical continuation and bifurcation theory to a subset of these to explore the changes in the orbit families when the orbital energy is varied. This analysis gives information on their stability and bifurcations. We then compare the various families on the basis of the restrictions and requirements of the specific mission considered, such as the pointing of the solar panels and instruments. We also use information about their resilience against parameter errors and their ground tracks to identify one particularly promising type of solution.