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Planar High-Thrust and Low-Thrust Orbital Transfers from Earth to Europa

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Abstract

We review analytical formulae for low-thrust orbital transfers from a circular initial orbit to a circular target orbit and to escape, using constant thrust applied in the same direction as the velocity vector, or in the opposite direction. The formulae give approximations for the maneuver time, final mass fraction, and evolution of the semimajor axis. For comparison, the associated results for high-thrust Hohmann and Oberth transfers are summarized. A simple computer program employing the aforementioned relationships is a useful tool for analysis of planar planetary and interplanetary space missions. This implementation yields fast and reasonably accurate approximations to trajectory performance boundaries. Consequently, the approach can provide trajectory analysis for each spacecraft configuration during the conceptual space mission design phase. As an example, a mission from Low-Earth Orbit (LEO) to Jupiter’s moon Europa is analyzed.

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Authors and Affiliations

  1. Analytical Mechanics Associates, Inc., 303 Butler Farm Road, Suite 104 A, VA, 23666, Hampton, USA

    Hans Seywald

  2. Mail Stop 328, NASA Langley Research Center, VA, 23681-2199, Hampton, USA

    Carlos M. Roithmayr, Daniel D. Mazanek, Frederic H. Stillwagen & Patrick A. Troutman

  3. Center for Astrodynamics and Space Technology, Dept. of Astronomy, Yonsei University, 120-749, Seoul, Republic of Korea

    Sang-Young Park (Associate Professor)

Authors
  1. Hans Seywald
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  2. Carlos M. Roithmayr
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  3. Daniel D. Mazanek
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  4. Frederic H. Stillwagen
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  5. Patrick A. Troutman
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  6. Sang-Young Park
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Correspondence to Sang-Young Park.

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Seywald, H., Roithmayr, C.M., Mazanek, D.D. et al. Planar High-Thrust and Low-Thrust Orbital Transfers from Earth to Europa. J of Astronaut Sci 52, 421–439 (2004). https://doi.org/10.1007/BF03546410

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  • DOI: https://doi.org/10.1007/BF03546410

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