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Thruster failure recovery strategies for libration point missions

Thruster failure recovery strategies for libration point missions. Maksim Shirobokov Keldysh Institute of Applied Mathematics Moscow Institute of Physics and Technology Sergey Trofimov Keldysh Institute of Applied Mathematics Moscow Institute of Physics and Technology. Contents.

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Thruster failure recovery strategies for libration point missions

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  1. Thruster failure recovery strategiesfor libration point missions Maksim Shirobokov Keldysh Institute of Applied Mathematics Moscow Institute of Physics and Technology Sergey Trofimov Keldysh Institute of Applied Mathematics Moscow Institute of Physics and Technology

  2. Contents • Motivation • Problem statement • Theory background • Test case: Sun-Earth L2, planar periodic orbits • Conclusion

  3. Missions to libration points • Successfully accomplished missions: • ISEE-3, WIND, SOHO, ACE, Genesis • Promising near-future projects • Deep Space Climate Observatory (NASA) • LISA Pathfinder (ESA/NASA) • Spektr-RG (Roscosmos/ESA)

  4. Features related to periodic motion around collinear libration points High instability of motionrequirestheapplication of station-keeping techniques and their essential components: • Accuratetrajectorydetermination • Regular control-law updates In average, 2-12 m/s per year is required Thus, any possible thruster (or communication) failure1threatens a mission and can lead to a significant deviation of the spacecraft from the nominal periodic orbit 1The largest percentage of all fail occurrences relating to the control system falls on thruster failure, see Tafazoli [2009] “A Study of On-Orbit Spacecraft Failures”, Acta Astronautica

  5. Thsuter failure issue If a thruster fails, the control is allocated to a redundant set of thrusters: • attitude control thrusters • a backup orbital thruster Most of publications are related only to collision avoidance during rendezvous and docking. The problem of libration point mission recovery has not been deeply studied yet

  6. Problem statement Basic assumptions: • the main orbit control thruster failed and produces no thrust • the planned correction maneuver is not performed on time • with some delay, a redundant set of thrusters is used Transfer to the nominal periodic orbit may appear to be too expensive: • unstable environment leads to fast orbit decay • redundant thruster has usually less fuel than the main one Therefore, not enough fuel is left to perform station-keeping maneuvers during the planned mission lifetime

  7. Thruster failure recovery strategies Two strategies are considered: • periodic orbit targeting (POT) • stable manifold targeting (SMT) In both cases, the aim is the same—to find the “cheapest-to-get” periodic orbit for different values of correction maneuver delay (the time passed since the moment of unsuccessful correction maneuver)

  8. Circular restricted three-body problem The planar circular restricted three-body problem (CR3BP) is studied: • a spacecraft of negligible mass moves under the gravitational influence of two masses and • the spacecraft is supposed to move in the orbital plane of the primaries Note: the proposed recovery strategies can be applied to the spatial case (for example, for halo orbits)

  9. Reference frame Mass parameter Non-dimensional units: For the Sun-(Earth+Moon) system

  10. Equations of motion In rotating frame where is the so called effective potential; and are the partial derivatives of with respect to the position variables. The distances between the spacecraft and the primaries equal

  11. Libration points Equilibrium (libration) points can be found from the equations Collinear libration points Sun-(Earth+Moon) system

  12. Richardson’s third-order approximation of periodic orbits The third-order approximation of periodic orbits in normalized variables and expressed as follows: where some constants

  13. Periodic orbit targeting strategy Reference periodic orbit Backup periodic orbit

  14. Gain in delta-v for POT strategy

  15. Change in amplitude for POT strategy

  16. Stable manifold targeting strategy Reference periodic orbit Stable manifold

  17. Gain in delta-v for SMT strategy

  18. Change in amplitude for SMT strategy

  19. Conclusion • Two recovery strategies in case of possible thruster failure—periodic orbit targeting and stable manifold targeting—are proposed for collinear libration point missions • The proposed approach reduces delta-v spent by the redundant set of thrusters and increases the lifetime of the spacecraft

  20. Future work • Targeting to periodic orbits with larger amplitudes requires higher-order approximations of these orbits • Different positions of the unsuccessful correction maneuver may bring to different results

  21. Thank you!

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