Europlanet Science Congress 2020
Virtual meeting
21 September – 9 October 2020
Europlanet Science Congress 2020
Virtual meeting
21 September – 9 October 2020
EPSC Abstracts
Vol.14, EPSC2020-835, 2020, updated on 08 Oct 2020
https://doi.org/10.5194/epsc2020-835
Europlanet Science Congress 2020
© Author(s) 2020. This work is distributed under
the Creative Commons Attribution 4.0 License.

Terminator Orbits around the Triple Asteroid 2001-SN263: A search for stable motion applicable to the mission ASTER

Kai Wickhusen1, Friedrich Damme2, Antonio G. V. de Brum3, Alexander Stark1, Jean-Baptiste Vincent1, Hauke Hussmann1, and Jürgen Oberst1,2
Kai Wickhusen et al.
  • 1German Aerospace Center (DLR), Berlin, Germany (kai.wickhusen@dlr.de)
  • 2Technical University of Berlin, Germany
  • 3Federal University of ABC, SBC, Sao Paulo, Brazil

Abstract

In this study we investigate the possibility of using terminator orbits that are stable over a period of three months to explore the triple near-earth asteroid (NEA) system 2001 SN263 with an orbiting spacecraft.  We study  in particular  the case of  the  mission ASTER  that is  under  study as  the  first Brazilian  deep  space mission [1].

Introduction

The interest in the first identified Near Earth Asteroid (NEA) triple system 2001 SN263 increased greatly when the Brazilian space agency announced ASTER, a rendezvous mission to explore this unique target [2].

The analysis of the observational data of 2001 SN263 [3] suggested that the primary is approximately a spheroid with an equivalent diameter of about 2.6 km (2.8×2.7×2.5 km) and smaller companions, about 700 m and 430 m in diameter orbiting at distances of 16.6 and 3.8 km, respectively. 

For the spacecraft to move safely within the system, it is critical to identify and characterize regions of stability and instability (i.e., where collision or escape are imminent).  Furthermore,  observational and operational strategies to explore all three asteroids critically depend  on  availability  of  stable  spacecraft  orbits  (i.e.,  orbits  that  do  not  requiring  expensive  correction maneuvers). In this study we search for stable orbits within the triple asteroid system. The orbits are considered stable when the spacecraft does not escape or collide with the system for 3 months.

Data and methods

We modelled the gravitational field of each body in two steps.  First, we integrate the gravitational acceleration contributed by the mass of the object, represented by a polyhedron shape model (and assuming a homogeneous interior). In  a  second  step,  we  replace  this  reference  field  with  its  spherical  harmonics  approximation.

The spacecraft trajectories around the triple asteroid are calculated with a numerical integrator which solves the equation of motion, taking into account all relevant forces:

with GM being  the  standard  gravitational  parameter  of  the  primary  body  and  being the spacecraft’s position and acceleration, respectively. The main acceleration acting on the spacecraft is caused by the system’s primary body, represented by a point mass, in the first term of the equation.  Higher-order terms, which include the non-spherical gravity field of the main body, are included in the second term. The secondary and tertiary body are represented by the third term of the equation.  Additionally, the large Solar System bodies, such as Sun and Jupiter are also included as perturbing forces in  this  third  addend.   The  last  term  takes  into  account  the  solar  radiation  pressure  acting  on  the spacecraft. The spacecraft is modelled based on the mass and dimensions as specified for ASTER mission [4].

Results and Conclusion

The results show that stable terminator orbits within the triple asteroid system can be found, for which the orbital plane is perpendicular to the incoming solar radiation.

These stable orbits are found between the semi-major axes of the secondary and tertiary body, i.e., at a distance between 4 km and 13 km from the primary’s centre.

Figure 1: Example of stability regions of the Aster S/C model in the triple asteroid system. The stability depends on initial orientation of the orbital plane which is represented by the longitude of ascending node and the inclination. Initial elements: semi-major axis=8km, eccentricity=0, remaining elements=0°. The colour coding shows the difference between largest and shortest distance to the primary body over 3 months.

The most stable region is located at semi-major axes between 7 and 12 km. In the best cases, the distance variation of the S/C absolute distance from primary’s centre (r.max-r.min) varies less than 1 km over a time frame of 3 months.

Figure 1 shows these stability regions at an exemplary initial distance of 8 km. 

References

[1] Macau, E. E. N., Winter, O. C., Velho, H. F. C., Sukhanov, A. A., Brum, A. G. V., Ferreira, J. L., Hetem, A., & Sandonato, G.  M.  (2011).   The  ASTER  mission:   exploring  for  the  first  time  a  triple  system  asteroid.  InProceedings of the 62nd International Astronautical Congress.  Cape Town, SA. 

[2] Sukhanov, A. A., Velho, H. F. C., Macau, E. E. N., & Winter, O. C. (2010). The Aster project:  Flight to a near-Earth asteroid. Cosmic Research,48, 443–450. doi:10.1134/S0010952510050114.

[3] Becker, T. M., Howell, E. S., Nolan, M. C., et al. (2015). Physical modeling of triple near-Earth Asteroid (153591) 2001 SN263 from radar and optical light curve observations. Icarus, 248, 499, doi: 10.1016/j.icarus.2014.10.048

[4] Goretov, V., Lipatov, A., Linkin V. (2018) Description of the spacecraft on the EJP for near-earth and planetary research.

Acknowledgements

F.D. and J.O have been supported by a grant from the German Science Foundation (DFG-OB 124/19-1)

A.G.V. de Brum was supported by the São Paulo Research Foundation – FAPESP
(grant#2018/22672-4).

How to cite: Wickhusen, K., Damme, F., de Brum, A. G. V., Stark, A., Vincent, J.-B., Hussmann, H., and Oberst, J.: Terminator Orbits around the Triple Asteroid 2001-SN263: A search for stable motion applicable to the mission ASTER, Europlanet Science Congress 2020, online, 21 September–9 Oct 2020, EPSC2020-835, https://doi.org/10.5194/epsc2020-835, 2020